DIGIMAT LEARNING MANAGEMENT PLATFORM

Mechanical Engineering (12,514 Video Lectures)

Link NPTEL Course Name NPTEL Lecture Title
Link Convective Heat and Mass Transfer Lecture 1 - Introduction
Link Convective Heat and Mass Transfer Lecture 2 - Flow Classifications
Link Convective Heat and Mass Transfer Lecture 3 - Laws of Convection
Link Convective Heat and Mass Transfer Lecture 4 - Scalar Transport Equations
Link Convective Heat and Mass Transfer Lecture 5 - Laminar Boundary Layers
Link Convective Heat and Mass Transfer Lecture 6 - Similarity Method
Link Convective Heat and Mass Transfer Lecture 7 - Similaity Solns Velocity BL
Link Convective Heat and Mass Transfer Lecture 8 - Similaity Solns Temperature BL - I
Link Convective Heat and Mass Transfer Lecture 9 - Similaity Solns Temperature BL - II
Link Convective Heat and Mass Transfer Lecture 10 - Integral BL Equations
Link Convective Heat and Mass Transfer Lecture 11 - Integral Solns Laminar Velocity BL
Link Convective Heat and Mass Transfer Lecture 12 - Integral Solns Laminar Temperature BL
Link Convective Heat and Mass Transfer Lecture 13 - Superposition Theory
Link Convective Heat and Mass Transfer Lecture 14 - Laminar Internal Flows
Link Convective Heat and Mass Transfer Lecture 15 - Fully-Developed Laminar Flows - 1
Link Convective Heat and Mass Transfer Lecture 16 - Fully-Developed Laminar Flows - 2
Link Convective Heat and Mass Transfer Lecture 17 - Fully-Developed Laminar Flows Heat Transfer - 1
Link Convective Heat and Mass Transfer Lecture 18 - Fully-Developed Laminar Flows Heat Transfer - 2
Link Convective Heat and Mass Transfer Lecture 19 - Laminar Internal Developing Flows Heat Transfer
Link Convective Heat and Mass Transfer Lecture 20 - Superposition Technique
Link Convective Heat and Mass Transfer Lecture 21 - Nature of Turbulent Flows
Link Convective Heat and Mass Transfer Lecture 22 - Sustaining Mechanism of Turbulence - 1
Link Convective Heat and Mass Transfer Lecture 23 - Sustaining Mechanism of Turbulence - 1
Link Convective Heat and Mass Transfer Lecture 24 - Sustaining Mechanism of Turbulence - 2
Link Convective Heat and Mass Transfer Lecture 25 - Near-Wall Turbulent Flows - 1
Link Convective Heat and Mass Transfer Lecture 26 - Near-Wall Turbulent Flows - 2
Link Convective Heat and Mass Transfer Lecture 27 - Turbulence Models - 1
Link Convective Heat and Mass Transfer Lecture 28 - Turbulence Models - 2
Link Convective Heat and Mass Transfer Lecture 29 - Turbulence Models - 3
Link Convective Heat and Mass Transfer Lecture 30 - Prediction of Turbulent Flows
Link Convective Heat and Mass Transfer Lecture 31 - Prediction of Turbulent Heat Transfer
Link Convective Heat and Mass Transfer Lecture 32 - Convective Mass Transfer
Link Convective Heat and Mass Transfer Lecture 33 - Stefan Flow Model
Link Convective Heat and Mass Transfer Lecture 34 - Couette Flow Model
Link Convective Heat and Mass Transfer Lecture 35 - Reynolds Flow Model
Link Convective Heat and Mass Transfer Lecture 36 - Boundary Layer Flow Model
Link Convective Heat and Mass Transfer Lecture 37 - Evaluation of g and Nw
Link Convective Heat and Mass Transfer Lecture 38 - Diffusion Mass Transfer Problems
Link Convective Heat and Mass Transfer Lecture 39 - Convective MT Couette Flow
Link Convective Heat and Mass Transfer Lecture 40 - Convective MT Reynolds Flow Model - 1
Link Convective Heat and Mass Transfer Lecture 41 - Convective MT Reynolds Flow Model - 2
Link Convective Heat and Mass Transfer Lecture 42 - Natural Convection
Link Convective Heat and Mass Transfer Lecture 43 - Diffusion Jet Flames
Link Cryogenic Engineering Lecture 1 - Introduction to Cryogenic Engineering
Link Cryogenic Engineering Lecture 2 - Properties of Cryogenic Fluids - I
Link Cryogenic Engineering Lecture 3 - Properties of Cryogenic Fluids - II
Link Cryogenic Engineering Lecture 4 - Properties of Cryogenic
Link Cryogenic Engineering Lecture 5 - Material Properties at Low Temperature - I
Link Cryogenic Engineering Lecture 6 - Material Properties at Low Temperature - II
Link Cryogenic Engineering Lecture 7 - Material Properties at Low Temperature - III
Link Cryogenic Engineering Lecture 8 - Gas Liquefaction and Refrigeration Systems - I
Link Cryogenic Engineering Lecture 9 - Gas Liquefaction and Refrigeration Systems - II
Link Cryogenic Engineering Lecture 10 - Gas Liquefaction and Refrigeration Systems - III
Link Cryogenic Engineering Lecture 11 - Gas Liquefaction and Refrigeration Systems - IV
Link Cryogenic Engineering Lecture 12 - Gas Liquefaction and Refrigeration Systems - V
Link Cryogenic Engineering Lecture 13 - Gas Liquefaction and Refrigeration Systems - VI
Link Cryogenic Engineering Lecture 14 - Gas Liquefaction and Refrigeration Systems - VII
Link Cryogenic Engineering Lecture 15 - Gas Liquefaction and Refrigeration Systems - VIII
Link Cryogenic Engineering Lecture 16 - Gas Liquefaction and Refrigeration Systems - IX
Link Cryogenic Engineering Lecture 17 - Gas Liquefaction and Refrigeration Systems - X
Link Cryogenic Engineering Lecture 18 - Gas Separation - I
Link Cryogenic Engineering Lecture 19 - Gas Separation - II
Link Cryogenic Engineering Lecture 20 - Gas Separation - III
Link Cryogenic Engineering Lecture 21 - Gas Separation - IV
Link Cryogenic Engineering Lecture 22 - Gas Separation - V
Link Cryogenic Engineering Lecture 23 - Gas Separation - VI
Link Cryogenic Engineering Lecture 24 - Gas Separation - VII
Link Cryogenic Engineering Lecture 25 - Gas Separation - VIII
Link Cryogenic Engineering Lecture 26 - Cryocoolers
Link Cryogenic Engineering Lecture 27 - Cryocoolers Ideal Stirling Cycle - I
Link Cryogenic Engineering Lecture 28 - Cryocoolers Ideal Stirling Cycle - II
Link Cryogenic Engineering Lecture 29 - Cryocoolers Ideal Stirling Cycle - III
Link Cryogenic Engineering Lecture 30 - Cryocoolers Ideal Stirling Cycle - IV
Link Cryogenic Engineering Lecture 31 - Cryocoolers Ideal Stirling Cycle - V
Link Cryogenic Engineering Lecture 32 - Cryocoolers
Link Cryogenic Engineering Lecture 33 - Cryogenic Insulation - I
Link Cryogenic Engineering Lecture 34 - Cryogenic Insulation - II
Link Cryogenic Engineering Lecture 35 - Cryogenic Insulation - III
Link Cryogenic Engineering Lecture 36 - Vacuum Technology - I
Link Cryogenic Engineering Lecture 37 - Vacuum Technology - II
Link Cryogenic Engineering Lecture 38 - Vaccum Technology - III
Link Cryogenic Engineering Lecture 39 - Instrumentation in Cryogenics - I
Link Cryogenic Engineering Lecture 40 - Instrumentation in Cryogenics - II
Link Cryogenic Engineering Lecture 41 - Instrumentation in Cryogenics - III
Link Cryogenic Engineering Lecture 42 - Safety in Cryogenics
Link Advanced Strength of Materials Lecture 1 - Stress and Strain Tensor
Link Advanced Strength of Materials Lecture 2 - Stress and Strain Tensor (Continued) and Cauchy Formula for Traction
Link Advanced Strength of Materials Lecture 3 - Examples on Calculation of Strains and Tractions, Principal Stresses and Directions
Link Advanced Strength of Materials Lecture 4 - Example on Calculation of Principal Stresses and Directions, Orthogonality of Principal Directions, Principal Stresses are all Real
Link Advanced Strength of Materials Lecture 5 - Maximum Shear Stress and Octahedral Shear Stress, Deviatoric and Hydrostatic Stresses
Link Advanced Strength of Materials Lecture 6 - Transformation of Stresses and Mohr Circle in 3-D
Link Advanced Strength of Materials Lecture 7 - Mohr Circle (Continued)
Link Advanced Strength of Materials Lecture 8 - Deformation, Rotation and Strain Tensors, Principal Strains,Deviatoric and Hydrostatic Strains
Link Advanced Strength of Materials Lecture 9 - Strain Transformations, Strains in Polar Coordinates, Equilibrium Equations in 2-D
Link Advanced Strength of Materials Lecture 10 - Equilibrium Equations in 2-D Polar Coordinates Plane Stress and Plane Strain Conditions
Link Advanced Strength of Materials Lecture 11 - Stress-Strain Relations for Isotropic, Orthotropic and Anisotropic Materials Stress-Strain-Temperature Relations
Link Advanced Strength of Materials Lecture 12 - Relation between Elastic Constants and Strain Energy Densities Recap of Lectures 1 to 11
Link Advanced Strength of Materials Lecture 13 - Stress Distribution in Thick Cylinder
Link Advanced Strength of Materials Lecture 14 - Stresses due to Shrink Fitting
Link Advanced Strength of Materials Lecture 15 - Stresses in Rotating Disc
Link Advanced Strength of Materials Lecture 16 - Examples on Shrink Fitting and Rotating Disc
Link Advanced Strength of Materials Lecture 17 - Torsion of Non-Circular Shaft
Link Advanced Strength of Materials Lecture 18 - Torsion of Non-Circular Shaft (Continued)
Link Advanced Strength of Materials Lecture 19 - Membrane Analogy for Torsion
Link Advanced Strength of Materials Lecture 20 - Torsion of Thin Box Sections
Link Advanced Strength of Materials Lecture 21 - Torsion of Box and Open Sections
Link Advanced Strength of Materials Lecture 22 - Bending of Curved Bars
Link Advanced Strength of Materials Lecture 23 - Bending of Curved Bars (Continued)
Link Advanced Strength of Materials Lecture 24 - Theories of Failure
Link Advanced Strength of Materials Lecture 25 - Theories of Failure (Continued)
Link Advanced Strength of Materials Lecture 26 - Theories of Failure (Continued) and Their Applications, Griffith Theory of Brittle Fracture
Link Advanced Strength of Materials Lecture 27 - Application of Griffith Theory, Irwin-Orowan Modification of Griffith Theory, Assessment of Effect of Dynamic Loading
Link Advanced Strength of Materials Lecture 28 - Theorems of Elasticity
Link Advanced Strength of Materials Lecture 29 - Theorems of Elasticity (Continued)
Link Advanced Strength of Materials Lecture 30 - Thermal Stress Distribution in Rectangular Sheet due to Symmetric and Asymmetric Temperature Fields
Link Advanced Strength of Materials Lecture 31 - Thermal Stress Distribution in Cylinders
Link Advanced Strength of Materials Lecture 32 - Unsymmetrical Bending
Link Advanced Strength of Materials Lecture 33 - Shear Centre
Link Advanced Strength of Materials Lecture 34 - Plate Bending
Link Advanced Strength of Materials Lecture 35 - Plate Bending (Continued)
Link Advanced Strength of Materials Lecture 36 - Examples on Plate Bending
Link Advanced Strength of Materials Lecture 37 - Approximate Solutions for Bending of Rectangular and Circular Plates
Link Advanced Strength of Materials Lecture 38 - Thin Shells of Revolution
Link Advanced Strength of Materials Lecture 39 - Beam on Elastic Foundation
Link Advanced Strength of Materials Lecture 40 - Application of Beam on Elastic Foundation Analysis to Pressure Vessels for Calculation of Discontinuity Stresses
Link Heat and Mass Transfer Lecture 1 - Introduction to Heat and Mass Transfer
Link Heat and Mass Transfer Lecture 2 - Introduction
Link Heat and Mass Transfer Lecture 3 - Introduction
Link Heat and Mass Transfer Lecture 4 - Heat Conduction - 1
Link Heat and Mass Transfer Lecture 5 - Heat Conduction - 2
Link Heat and Mass Transfer Lecture 6 - Heat Conduction - 3
Link Heat and Mass Transfer Lecture 7 - Heat Conduction - 4
Link Heat and Mass Transfer Lecture 8 - Heat Conduction - 5
Link Heat and Mass Transfer Lecture 9 - Heat Conduction - 6
Link Heat and Mass Transfer Lecture 10 - Thermal Radiation - 1
Link Heat and Mass Transfer Lecture 11 - Thermal Radiation - 2
Link Heat and Mass Transfer Lecture 12 - Thermal Radiation - 3
Link Heat and Mass Transfer Lecture 13 - Thermal Radiation - 4
Link Heat and Mass Transfer Lecture 14 - Thermal Radiation - 5
Link Heat and Mass Transfer Lecture 15 - Thermal Radiation - 6
Link Heat and Mass Transfer Lecture 16 - Review Of Fluid Mechanics - 1
Link Heat and Mass Transfer Lecture 17 - Review Of Fluid Mechanics - 2
Link Heat and Mass Transfer Lecture 18 - Forced Convection - 1
Link Heat and Mass Transfer Lecture 19 - Forced Convection - 2
Link Heat and Mass Transfer Lecture 20 - Forced Convection - 3
Link Heat and Mass Transfer Lecture 21 - Forced Convection - 4
Link Heat and Mass Transfer Lecture 22 - Natural Convection - 1
Link Heat and Mass Transfer Lecture 23 - Natural Convection - 2
Link Heat and Mass Transfer Lecture 24 - Natural Convection - 3
Link Heat and Mass Transfer Lecture 25 - Heat Exchangers - 1
Link Heat and Mass Transfer Lecture 26 - Heat Exchangers - 2
Link Heat and Mass Transfer Lecture 27 - Heat Exchangers - 3
Link Heat and Mass Transfer Lecture 28 - Heat Exchangers - 4
Link Heat and Mass Transfer Lecture 29 - Boiling and Condensation - 1
Link Heat and Mass Transfer Lecture 30 - Boiling and Condensation - 2
Link Heat and Mass Transfer Lecture 31 - Boiling and Condensation - 3
Link Heat and Mass Transfer Lecture 32 - Boiling and Condensation - 4
Link Heat and Mass Transfer Lecture 33 - Introduction to Mass Transfer - 1
Link Heat and Mass Transfer Lecture 34 - Introduction to Mass Transfer - 2
Link Heat and Mass Transfer Lecture 35 - Introduction to Mass Transfer - 3
Link Robotics Lecture 1 - Introduction to Robotics
Link Robotics Lecture 2 - Technologies in Robots
Link Robotics Lecture 3 - Industrial Robots
Link Robotics Lecture 4 - Industrial Manipulators and its Kinematics
Link Robotics Lecture 5 - Parallel Manipulators
Link Robotics Lecture 6 - Grippers manipulators
Link Robotics Lecture 7 - Electric Actuators
Link Robotics Lecture 8 - Actuators - Electric, Hydraulic, Pneumatic
Link Robotics Lecture 9 - Internal State Sensors
Link Robotics Lecture 10 - Internal State Sensors
Link Robotics Lecture 11 - External State Sensors
Link Robotics Lecture 12 - Trajectory planning
Link Robotics Lecture 13 - Trajectory planning
Link Robotics Lecture 14 - Trajectory planning
Link Robotics Lecture 15 - Trajectory planning
Link Robotics Lecture 16 - Trajectory planning
Link Robotics Lecture 17 - Trajectory planning
Link Robotics Lecture 18 - Trajectory planning
Link Robotics Lecture 19 - Trajectory planning
Link Robotics Lecture 20 - Forward Position Control
Link Robotics Lecture 21 - Inverse Problem
Link Robotics Lecture 22 - Velocity Analysis
Link Robotics Lecture 23 - Velocity Analysis
Link Robotics Lecture 24 - Dynamic Analysis
Link Robotics Lecture 25 - Image Processing
Link Robotics Lecture 26 - Image Processing
Link Robotics Lecture 27 - Image Processing
Link Robotics Lecture 28 - Image Processing
Link Robotics Lecture 29 - Image Processing
Link Robotics Lecture 30 - Image Processing
Link Robotics Lecture 31 - Robot Dynamics and Control
Link Robotics Lecture 32 - Robot Dynamics and Control
Link Robotics Lecture 33 - Robot Dynamics and Control
Link Robotics Lecture 34 - Robot Dynamics and Control
Link Robotics Lecture 35 - Robot Dynamics and Control
Link Robotics Lecture 36 - Robot Dynamics and Control
Link Robotics Lecture 37 - Futuristic Topics in Robotics
Link Robotics Lecture 38 - Robot Dynamic and Control-Case Studies
Link Robotics Lecture 39 - Robot Dynamic and Control-Case Studies
Link Robotics Lecture 40 - Futuristic Topics in Robotics
Link NOC:Optimization from Fundamentals Lecture 1 - Introduction
Link NOC:Optimization from Fundamentals Lecture 2 - Isoperimetric problem
Link NOC:Optimization from Fundamentals Lecture 3 - Review of real analysis (sequences and convergence)
Link NOC:Optimization from Fundamentals Lecture 4 - Bolzano-Weierstrass theorem and completeness axiom
Link NOC:Optimization from Fundamentals Lecture 5 - Open sets, closed sets and compact sets
Link NOC:Optimization from Fundamentals Lecture 6 - Continuity and Weierstrass theorem
Link NOC:Optimization from Fundamentals Lecture 7 - Weierstrass theorem
Link NOC:Optimization from Fundamentals Lecture 8 - Different solution concepts
Link NOC:Optimization from Fundamentals Lecture 9 - Different types of constraints
Link NOC:Optimization from Fundamentals Lecture 10 - Taylor's theorem
Link NOC:Optimization from Fundamentals Lecture 11 - First order sufficient condition
Link NOC:Optimization from Fundamentals Lecture 12 - Second order necessary condition
Link NOC:Optimization from Fundamentals Lecture 13 - Least square regression
Link NOC:Optimization from Fundamentals Lecture 14 - Least square regression (Continued...)
Link NOC:Optimization from Fundamentals Lecture 15 - Implicit function theorem
Link NOC:Optimization from Fundamentals Lecture 16 - Optimization with equality constraints and introduction to Lagrange multipliers - I
Link NOC:Optimization from Fundamentals Lecture 17 - Optimization with equality constraints and introduction to Lagrange multipliers - II
Link NOC:Optimization from Fundamentals Lecture 18 - Least norm solution of underdetermined linear system
Link NOC:Optimization from Fundamentals Lecture 19 - Transformation of optimization problems - I
Link NOC:Optimization from Fundamentals Lecture 20 - Transformation of optimization problems - II
Link NOC:Optimization from Fundamentals Lecture 21 - Transformation of optimization problems - III
Link NOC:Optimization from Fundamentals Lecture 22 - Convex Analysis - I
Link NOC:Optimization from Fundamentals Lecture 23 - Convex Analysis - II
Link NOC:Optimization from Fundamentals Lecture 24 - Convex Analysis - III
Link NOC:Optimization from Fundamentals Lecture 25 - Polyhedrons
Link NOC:Optimization from Fundamentals Lecture 26 - Minkowski-Weyl Theorem
Link NOC:Optimization from Fundamentals Lecture 27 - Linear Programming Problems
Link NOC:Optimization from Fundamentals Lecture 28 - Extreme points and optimal solution of an LP
Link NOC:Optimization from Fundamentals Lecture 29 - Extreme points and optimal solution of an LP (Continued...)
Link NOC:Optimization from Fundamentals Lecture 30 - Extreme points and basic feasible solutions
Link NOC:Optimization from Fundamentals Lecture 31 - Equivalence of extreme point and BFS
Link NOC:Optimization from Fundamentals Lecture 32 - Equivalence of extreme point and BFS (Continued...)
Link NOC:Optimization from Fundamentals Lecture 33 - Examples of Linear Programming
Link NOC:Optimization from Fundamentals Lecture 34 - Weak and Strong duality
Link NOC:Optimization from Fundamentals Lecture 35 - Proof of strong duality
Link NOC:Optimization from Fundamentals Lecture 36 - Proof of strong duality (Continued...)
Link NOC:Optimization from Fundamentals Lecture 37 - Farkas' lemma
Link NOC:Optimization from Fundamentals Lecture 38 - Max-flow Min-cut problem
Link NOC:Optimization from Fundamentals Lecture 39 - Shortest path problem
Link NOC:Optimization from Fundamentals Lecture 40 - Complementary Slackness
Link NOC:Optimization from Fundamentals Lecture 41 - Proof of complementary slackness
Link NOC:Optimization from Fundamentals Lecture 42 - Tangent cones
Link NOC:Optimization from Fundamentals Lecture 43 - Tangent cones (Continued...)
Link NOC:Optimization from Fundamentals Lecture 44 - Constraint qualifications, Farkas' lemma and KKT
Link NOC:Optimization from Fundamentals Lecture 45 - KKT conditions
Link NOC:Optimization from Fundamentals Lecture 46 - Convex optimization and KKT conditions
Link NOC:Optimization from Fundamentals Lecture 47 - Slater condition and Lagrangian Dual
Link NOC:Optimization from Fundamentals Lecture 48 - Weak duality in convex optimization and Fenchel dual
Link NOC:Optimization from Fundamentals Lecture 49 - Geometry of the Lagrangian
Link NOC:Optimization from Fundamentals Lecture 50 - Strong duality in convex optimization - I
Link NOC:Optimization from Fundamentals Lecture 51 - Strong duality in convex optimization - II
Link NOC:Optimization from Fundamentals Lecture 52 - Strong duality in convex optimization - III
Link NOC:Optimization from Fundamentals Lecture 53 - Line search methods for unconstrained optimization
Link NOC:Optimization from Fundamentals Lecture 54 - Wolfe conditions
Link NOC:Optimization from Fundamentals Lecture 55 - Line search algorithm and convergence
Link NOC:Optimization from Fundamentals Lecture 56 - Steepest descent method and rate of convergence
Link NOC:Optimization from Fundamentals Lecture 57 - Newton's method
Link NOC:Optimization from Fundamentals Lecture 58 - Penalty methods
Link NOC:Optimization from Fundamentals Lecture 59 - L1 and L2 Penalty methods
Link NOC:Optimization from Fundamentals Lecture 60 - Augmented Lagrangian methods
Link NOC:Optimization from Fundamentals Lecture 61 - Cutting plane methods
Link NOC:Optimization from Fundamentals Lecture 62 - Interior point methods for linear programming
Link NOC:Optimization from Fundamentals Lecture 63 - Dynamic programming: Inventory control problem
Link NOC:Optimization from Fundamentals Lecture 64 - Policy and value function
Link NOC:Optimization from Fundamentals Lecture 65 - Principle of optimality in dynamic programming
Link NOC:Optimization from Fundamentals Lecture 66 - Principle of optimality applied to inventory control problem
Link NOC:Optimization from Fundamentals Lecture 67 - Optimal control for a system with linear state dynamics and quadratic cost
Link NOC:Design of Mechatronic Systems Lecture 1 - Introduction
Link NOC:Design of Mechatronic Systems Lecture 2 - Elements of Mechatronic Systems - Part I
Link NOC:Design of Mechatronic Systems Lecture 3 - Elements of Mechatronic Systems - Part II
Link NOC:Design of Mechatronic Systems Lecture 4 - Elements of Mechatronic Systems - Part III
Link NOC:Design of Mechatronic Systems Lecture 5 - CD-ROM - Part I
Link NOC:Design of Mechatronic Systems Lecture 6 - CD-ROM - Part II
Link NOC:Design of Mechatronic Systems Lecture 7 - CD-ROM - Part III
Link NOC:Design of Mechatronic Systems Lecture 8 - Scanner
Link NOC:Design of Mechatronic Systems Lecture 9 - Integrated Mechanical-Electronics Philosophy - Part I
Link NOC:Design of Mechatronic Systems Lecture 10 - Integrated Mechanical-Electronics Philosophy - Part II
Link NOC:Design of Mechatronic Systems Lecture 11 - Smart Sensors Concept
Link NOC:Design of Mechatronic Systems Lecture 12 - Compliant Mechanisms
Link NOC:Design of Mechatronic Systems Lecture 13 - Microprocessor Building Blocks I - Combinational Circuits
Link NOC:Design of Mechatronic Systems Lecture 14 - Microprocessor Building Blocks II - Sequential Circuits
Link NOC:Design of Mechatronic Systems Lecture 15 - Microprocessor Memory and Addressing
Link NOC:Design of Mechatronic Systems Lecture 16 - Timing and control unit: Primitive Microprocessor
Link NOC:Design of Mechatronic Systems Lecture 17 - Microcontroller Architecture - I
Link NOC:Design of Mechatronic Systems Lecture 18 - Microcontroller Architecture - II
Link NOC:Design of Mechatronic Systems Lecture 19 - Microcontroller Programming Philosophy
Link NOC:Design of Mechatronic Systems Lecture 20 - Hardware Interfaces
Link NOC:Design of Mechatronic Systems Lecture 21 - Interfacing Actuator using PWM in Tiva Microcontroller
Link NOC:Design of Mechatronic Systems Lecture 22 - Interfacing Encoder using QEI in Tiva Launchpad + ISR
Link NOC:Design of Mechatronic Systems Lecture 23 - Mathematical Modelling: Overview and Context
Link NOC:Design of Mechatronic Systems Lecture 24 - Modelling Friction in a System
Link NOC:Design of Mechatronic Systems Lecture 25 - Modelling DC Motor with loads
Link NOC:Design of Mechatronic Systems Lecture 26 - Lagrange formulation fundamentals
Link NOC:Design of Mechatronic Systems Lecture 27 - Lagrange formulation examples
Link NOC:Design of Mechatronic Systems Lecture 28 - Dynamics: 2-R Manipulator
Link NOC:Design of Mechatronic Systems Lecture 29 - Control formulation: Regulation and Tracking
Link NOC:Design of Mechatronic Systems Lecture 30 - Fundamentals of Simulation of dynamics using MATLAB
Link NOC:Design of Mechatronic Systems Lecture 31 - Selection of Sensors and Actuators - Part I
Link NOC:Design of Mechatronic Systems Lecture 32 - Selection of Sensors and Actuators - Part II
Link NOC:Design of Mechatronic Systems Lecture 33 - Concept of feedback
Link NOC:Design of Mechatronic Systems Lecture 34 - Closed loop control implementation in microcontroller
Link NOC:Design of Mechatronic Systems Lecture 35 - Mathematical representations of systems for control
Link NOC:Design of Mechatronic Systems Lecture 36 - Control design for linear systems
Link NOC:Design of Mechatronic Systems Lecture 37 - Application of control design for linear systems
Link NOC:Design of Mechatronic Systems Lecture 38 - Mathematical Preliminaries- Nonlinear Control
Link NOC:Design of Mechatronic Systems Lecture 39 - Fundamentals of Lyapunov theory
Link NOC:Design of Mechatronic Systems Lecture 40 - Application of Lyapunov stability analysis
Link NOC:Design of Mechatronic Systems Lecture 41 - Trajectory tracking controller: Robotic system
Link NOC:Design of Mechatronic Systems Lecture 42 - Fundamentals of sampling
Link NOC:Design of Mechatronic Systems Lecture 43 - Shannon sampling theorem and signal reconstruction
Link NOC:Design of Mechatronic Systems Lecture 44 - Signal processing
Link NOC:Design of Mechatronic Systems Lecture 45 - Digital system representation and filters for mechatronics
Link NOC:Design of Mechatronic Systems Lecture 46 - Case study: Development of 3D microprinting system
Link NOC:Design of Mechatronic Systems Lecture 47 - Case study: 3D microprinting via Bulk lithography
Link NOC:Design of Mechatronic Systems Lecture 48 - Case study: Hele-Shaw system for novel fabrication
Link NOC:Nonlinear Adaptive Control Lecture 1 - Basic Concepts and Nomenclature
Link NOC:Nonlinear Adaptive Control Lecture 2 - Preliminaries - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 3 - Preliminaries - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 4 - Preliminaries - Part 3
Link NOC:Nonlinear Adaptive Control Lecture 5 - Preliminaries - Part 4
Link NOC:Nonlinear Adaptive Control Lecture 6 - Preliminaries - Part 5
Link NOC:Nonlinear Adaptive Control Lecture 7 - Barbalat's Lemma - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 8 - Barbalat's Lemma - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 9 - Convergence of Signals using Barbalat's Lemma - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 10 - Convergence of Signals using Barbalat's Lemma - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 11 - Notions of Stability - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 12 - Notions of Stability - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 13 - Stability Analysis with Examples - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 14 - Stability Analysis with Examples - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 15 - Stability Analysis with Examples - Part 3
Link NOC:Nonlinear Adaptive Control Lecture 16 - Stability Analysis with Examples - Part 4
Link NOC:Nonlinear Adaptive Control Lecture 17 - Stability Analysis in Linear Systems
Link NOC:Nonlinear Adaptive Control Lecture 18 - Function Classes and Definiteness
Link NOC:Nonlinear Adaptive Control Lecture 19 - Positive Definite Functions
Link NOC:Nonlinear Adaptive Control Lecture 20 - Radially Unbounded Functions
Link NOC:Nonlinear Adaptive Control Lecture 21 - Decrescent Functions
Link NOC:Nonlinear Adaptive Control Lecture 22 - Lyapunov Stability Theorems - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 23 - Lyapunov Stability Theorems - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 24 - Lyapunov Stability Theorems - Part 3
Link NOC:Nonlinear Adaptive Control Lecture 25 - Exponential Stability and Converse Lyapunov Theorems
Link NOC:Nonlinear Adaptive Control Lecture 26 - Persistence of Excitation (PE): Introduction
Link NOC:Nonlinear Adaptive Control Lecture 27 - Connection of PE to Stability, Uniform Complete Observability (UCO)
Link NOC:Nonlinear Adaptive Control Lecture 28 - Exponential Stability of LTV systems, PE and Exponential Stability
Link NOC:Nonlinear Adaptive Control Lecture 29 - Parameter Identifier Convergence under PE Condition
Link NOC:Nonlinear Adaptive Control Lecture 30 - Analysis of Parameter Varying Systems using General Integral Lemma - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 31 - Analysis of Parameter Varying Systems using General Integral Lemma - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 32 - Adaptive Control Design: First Order Scalar Systems
Link NOC:Nonlinear Adaptive Control Lecture 33 - Barbalat's Lemma and Signal Chasing Anslysis
Link NOC:Nonlinear Adaptive Control Lecture 34 - Parameter Convergence in Adaptive Control Design
Link NOC:Nonlinear Adaptive Control Lecture 35 - Adaptive Control Design: Second-Order Systems
Link NOC:Nonlinear Adaptive Control Lecture 36 - Overcoming the Detectability Obstacle: Ortega Construction
Link NOC:Nonlinear Adaptive Control Lecture 37 - Backstepping in Adaptive Control: Introduction - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 38 - Backstepping in Adaptive Control: Introduction - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 39 - Backstepping in Adaptive Control: Parameters Unmatched with Control - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 40 - Backstepping in Adaptive Control: Parameters Unmatched with Control - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 41 - How to Deal with Unknown Gains in Control
Link NOC:Nonlinear Adaptive Control Lecture 42 - Setup of Model Reference Adaptive Control (MRAC) Problem
Link NOC:Nonlinear Adaptive Control Lecture 43 - Model Reference Adaptive control: For Known and Unknown Parameters
Link NOC:Nonlinear Adaptive Control Lecture 44 - Model Reference Adaptive control: Lyapunov Stability Analysis
Link NOC:Nonlinear Adaptive Control Lecture 45 - Generalization of Adaptive Integrator Backstepping Method - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 46 - Generalization of Adaptive Integrator Backstepping Method - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 47 - Extended Matching Design for Avoiding Overparameterization
Link NOC:Nonlinear Adaptive Control Lecture 48 - Adaptive Integrator Backstepping Method: An Example - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 49 - Adaptive Integrator Backstepping Method: An Example - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 50 - Extended Matching Design: An Example
Link NOC:Nonlinear Adaptive Control Lecture 51 - Control Lyapunov Function
Link NOC:Nonlinear Adaptive Control Lecture 52 - Tuning Function Adaptive Method
Link NOC:Nonlinear Adaptive Control Lecture 53 - Adaptive Backstepping via Control Lyapunov Function (CLF)
Link NOC:Nonlinear Adaptive Control Lecture 54 - Adaptive Backstepping via CLF: An Example
Link NOC:Nonlinear Adaptive Control Lecture 55 - Robustness in Adaptive Control - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 56 - Robustness in Adaptive Control - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 57 - Parameter Projection in Adaptive Control - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 58 - Parameter Projection in Adaptive Control - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 59 - Parameter Projection in Adaptive Control - Part 3
Link NOC:Nonlinear Adaptive Control Lecture 60 - Sigma- Modification and Epsilon-Modification in Adaptive Control
Link NOC:Nonlinear Adaptive Control Lecture 61 - Initial Excitation in Adaptive Control - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 62 - Initial Excitation in Adaptive Control - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 63 - Initial Excitation in Adaptive Control - Part 3
Link NOC:Nonlinear Adaptive Control Lecture 64 - Initial Excitation in Adaptive Control - Part 4
Link NOC:Nonlinear Adaptive Control Lecture 65 - Initial Excitation in Adaptive Control - Part 5
Link NOC:Nonlinear Adaptive Control Lecture 66 - Discussion on Historical Developments in Adaptive Control and Learning
Link NOC:Nonlinear Adaptive Control Lecture 67 - Real Time Neural Network Based Control of a Robotic Manipulator - Part 1
Link NOC:Nonlinear Adaptive Control Lecture 68 - Real Time Neural Network Based Control of a Robotic Manipulator - Part 2
Link NOC:Nonlinear Adaptive Control Lecture 69 - Real Time Neural Network Based Control of a Robotic Manipulator - Part 3
Link NOC:Nonlinear Adaptive Control Lecture 70 - Real Time Neural Network Based Control of a Robotic Manipulator - Part 4
Link NOC:Nonlinear Adaptive Control Lecture 71 - Real Time Neural Network Based Control of a Robotic Manipulator - Part 5
Link NOC:Nonlinear Control Design Lecture 1 - Course Introduction
Link NOC:Nonlinear Control Design Lecture 2 - Examples of Nonlinear systems
Link NOC:Nonlinear Control Design Lecture 3 - Existence and uniqueness of solutions
Link NOC:Nonlinear Control Design Lecture 4 - Preliminaries and notations
Link NOC:Nonlinear Control Design Lecture 5 - Preliminaries: Normed linear space
Link NOC:Nonlinear Control Design Lecture 6 - Preliminaries: Induced Matrix Norms and Signal Norms
Link NOC:Nonlinear Control Design Lecture 7 - Signal Norms and Cauchy-Schwarz Inequality
Link NOC:Nonlinear Control Design Lecture 8 - Stability - Part 1
Link NOC:Nonlinear Control Design Lecture 9 - Stability - Part 2
Link NOC:Nonlinear Control Design Lecture 10 - Stability - Part 3
Link NOC:Nonlinear Control Design Lecture 11 - Stability - Part 4
Link NOC:Nonlinear Control Design Lecture 12 - Stability - Part 5
Link NOC:Nonlinear Control Design Lecture 13 - Lyapunov stability Theorems - Part 1
Link NOC:Nonlinear Control Design Lecture 14 - Lyapunov stability Theorems - Part 2
Link NOC:Nonlinear Control Design Lecture 15 - Lyapunov stability Theorems - Part 3
Link NOC:Nonlinear Control Design Lecture 16 - Lyapunov stability Theorems - Part 4
Link NOC:Nonlinear Control Design Lecture 17 - Lyapunov stability Theorems - Part 5
Link NOC:Nonlinear Control Design Lecture 18 - Lyapunov stability Theorems - Part 6
Link NOC:Nonlinear Control Design Lecture 19 - Proofs of Lyapunov Stability Theorems - Part 1
Link NOC:Nonlinear Control Design Lecture 20 - Proofs of Lyapunov Stability Theorems - Part 2
Link NOC:Nonlinear Control Design Lecture 21 - Proofs of Lyapunov Stability Theorems - Part 3
Link NOC:Nonlinear Control Design Lecture 22 - Proofs of Lyapunov Stability Theorems - Part 4
Link NOC:Nonlinear Control Design Lecture 23 - La Salle's Invariance Principle - Part 1
Link NOC:Nonlinear Control Design Lecture 24 - La Salle's Invariance Principle - Part 2
Link NOC:Nonlinear Control Design Lecture 25 - La Salle's Invariance Principle - Part 3
Link NOC:Nonlinear Control Design Lecture 26 - La Salle's Invariance Principle - Part 4
Link NOC:Nonlinear Control Design Lecture 27 - La Salle's Invariance Principle - Part 5
Link NOC:Nonlinear Control Design Lecture 28 - La Salle's Invariance Principle - Part 6
Link NOC:Nonlinear Control Design Lecture 29 - Control Lyapunov functions - Part 1
Link NOC:Nonlinear Control Design Lecture 30 - Control Lyapunov functions - Part 2
Link NOC:Nonlinear Control Design Lecture 31 - Control Lyapunov functions - Part 3
Link NOC:Nonlinear Control Design Lecture 32 - Control Lyapunov functions - Part 4
Link NOC:Nonlinear Control Design Lecture 33 - Control Lyapunov functions - Part 5
Link NOC:Nonlinear Control Design Lecture 34 - Backstepping method for control design - Part 1
Link NOC:Nonlinear Control Design Lecture 35 - Backstepping method for control design - Part 2
Link NOC:Nonlinear Control Design Lecture 36 - Backstepping method for control design - Part 3
Link NOC:Nonlinear Control Design Lecture 37 - Backstepping method for control design - Part 4
Link NOC:Nonlinear Control Design Lecture 38 - Passivity based control - Part 1
Link NOC:Nonlinear Control Design Lecture 39 - Passivity based control - Part 2
Link NOC:Nonlinear Control Design Lecture 40 - Passivity based control - Part 3
Link NOC:Nonlinear Control Design Lecture 41 - Passivity in control systems - Part 1 (Prof. Antonio Loria)
Link NOC:Nonlinear Control Design Lecture 42 - Passivity in control systems - Part 2 (Prof. Antonio Loria)
Link NOC:Nonlinear Control Design Lecture 43 - Passivity in control systems - Part 3 (Prof. Antonio Loria)
Link NOC:Nonlinear Control Design Lecture 44 - Passivity in control systems - Part 4 (Prof. Antonio Loria)
Link NOC:Nonlinear Control Design Lecture 45 - Passivity based control - Part 4
Link NOC:Nonlinear Control Design Lecture 46 - Passivity based control - Part 5
Link NOC:Nonlinear Control Design Lecture 47 - Passivity based control - Part 6
Link NOC:Nonlinear Control Design Lecture 48 - Passivity based control - Part 7
Link NOC:Nonlinear Control Design Lecture 49 - Feedback Linearization - Part 1
Link NOC:Nonlinear Control Design Lecture 50 - Feedback Linearization - Part 2
Link NOC:Nonlinear Control Design Lecture 51 - Feedback Linearization - Part 3
Link NOC:Nonlinear Control Design Lecture 52 - Feedback Linearization - Part 4
Link NOC:Nonlinear Control Design Lecture 53 - Feedback Linearization - Part 5
Link NOC:Nonlinear Control Design Lecture 54 - Feedback Linearization - Part 6
Link NOC:Nonlinear Control Design Lecture 55 - Feedback Linearization - Part 6
Link NOC:Nonlinear Control Design Lecture 56 - Feedback Linearization - Part 7
Link NOC:Nonlinear Control Design Lecture 57 - Feedback Linearization - Part 8
Link NOC:Nonlinear Control Design Lecture 58 - Feedback Linearization - Part 9
Link NOC:Nonlinear Control Design Lecture 59 - Feedback Linearization - Part 10
Link NOC:Nonlinear Control Design Lecture 60 - Feedback Linearization - Part 11
Link NOC:Nonlinear Control Design Lecture 61 - Barbalat's Lemma
Link NOC:Nonlinear Control Design Lecture 62 - Application of Barbalat's Lemma
Link NOC:Nonlinear Control Design Lecture 63 - Adaptive control - Part 1
Link NOC:Nonlinear Control Design Lecture 64 - Adaptive control - Part 2
Link NOC:Nonlinear Control Design Lecture 65 - State constrained control - Part 1
Link NOC:Nonlinear Control Design Lecture 66 - State constrained control - Part 2
Link NOC:Nonlinear Control Design Lecture 67 - State constrained control - Part 3
Link NOC:Nonlinear Control Design Lecture 68 - Finite time stability - Part 1
Link NOC:Nonlinear Control Design Lecture 69 - Finite time stability - Part 2
Link NOC:Nonlinear Control Design Lecture 70 - Finite time stability - Part 3
Link NOC:Nonlinear Control Design Lecture 71 - Sliding mode control - Part 1
Link NOC:Nonlinear Control Design Lecture 72 - Sliding mode control - Part 2
Link NOC:Nonlinear Control Design Lecture 73 - Sliding mode control - Part 3
Link Tribology Lecture 1 - Introduction
Link Tribology Lecture 2 - Interdisciplinary Approach and Economic Benefits
Link Tribology Lecture 3 - Friction
Link Tribology Lecture 4 - Friction Estimation
Link Tribology Lecture 5 - Friction Instability
Link Tribology Lecture 6 - Wear
Link Tribology Lecture 7 - Adhesive Wear
Link Tribology Lecture 8 - Wear Mechanisms
Link Tribology Lecture 9 - Wear Mechanisms - 2
Link Tribology Lecture 10 - Wear Analysis
Link Tribology Lecture 11 - Lubrication and Lubricants
Link Tribology Lecture 12 - Boundary Lubrication
Link Tribology Lecture 13 - Lubrication Mechanisms
Link Tribology Lecture 14 - Hydrodynamic Lubrication
Link Tribology Lecture 15 - Lubricant Classifications
Link Tribology Lecture 16 - Solid and Semi Solid Lubricants
Link Tribology Lecture 17 - Liquid Lubricants
Link Tribology Lecture 18 - Lubricant Additives
Link Tribology Lecture 19 - Fluid Film Lubrication
Link Tribology Lecture 20 - Reynolds Equation
Link Tribology Lecture 21 - Solution of Reynolds Equation
Link Tribology Lecture 22 - Hybrid Solution Approach (to solve Reynolds Equation)
Link Tribology Lecture 23 - Finite Difference Method to Solve Reynolds Equation
Link Tribology Lecture 24 - Viscosity Variation
Link Tribology Lecture 25 - Estimating Elastic Deformation
Link Tribology Lecture 26 - Thermo Hydrodynamic Lubrication
Link Tribology Lecture 27 - Application of Tribology
Link Tribology Lecture 28 - Rolling Element Bearings
Link Tribology Lecture 29 - Rolling Element Bearings (Continued...)
Link Tribology Lecture 30 - Rolling Element Bearings (Continued...)
Link Tribology Lecture 31 - Selection of Rolling Element Bearings
Link Tribology Lecture 32 - Friction of Rolling Element Bearing
Link Tribology Lecture 33 - Bearing Clearance
Link Tribology Lecture 34 - Bearing Lubrication
Link Tribology Lecture 35 - Tribology of Gears
Link Tribology Lecture 36 - Friction and Lubrication of Gears
Link Tribology Lecture 37 - Friction and Lubrication of Gears (Continued...)
Link Tribology Lecture 38 - Surface Fatigue of Spur Gears
Link Tribology Lecture 39 - Journal Bearings
Link Tribology Lecture 40 - Hydrostatic Bearings
Link Tribology Lecture 41 - Hydrodynamic Journal Bearings
Link Tribology Lecture 42 - Design of Hydrodynamic Journal Bearings
Link Computer Aided Design and Manufacturing Lecture 1 - An Introduction to CAD
Link Computer Aided Design and Manufacturing Lecture 2 - Input Output Devices, Raster Graphics
Link Computer Aided Design and Manufacturing Lecture 3 - Raster Graphics - I
Link Computer Aided Design and Manufacturing Lecture 4 - Raster Graphics - II
Link Computer Aided Design and Manufacturing Lecture 5 - Polygon Filling
Link Computer Aided Design and Manufacturing Lecture 6 - Windowing and Clipping
Link Computer Aided Design and Manufacturing Lecture 7 - Clipping of Polygons
Link Computer Aided Design and Manufacturing Lecture 8 - 2D Transformations
Link Computer Aided Design and Manufacturing Lecture 9 - 3D Transformations and Projection
Link Computer Aided Design and Manufacturing Lecture 10 - Perspective Projections
Link Computer Aided Design and Manufacturing Lecture 11 - Projections and Hidden Surface Removal
Link Computer Aided Design and Manufacturing Lecture 12 - Hidden Surface Removal
Link Computer Aided Design and Manufacturing Lecture 13 - Hidden Surface Removal
Link Computer Aided Design and Manufacturing Lecture 14 - Hidden Surface Removal
Link Computer Aided Design and Manufacturing Lecture 15 - Finite Element Method : An Introduction
Link Computer Aided Design and Manufacturing Lecture 16 - Galerkin's Approach
Link Computer Aided Design and Manufacturing Lecture 17 - Galerkin's Method : 1D Finite Element Method
Link Computer Aided Design and Manufacturing Lecture 18 - 1D Finite Element Problems
Link Computer Aided Design and Manufacturing Lecture 19 - 1D Finite Element Problems
Link Computer Aided Design and Manufacturing Lecture 20 - FE Problems : Solving for Q
Link Computer Aided Design and Manufacturing Lecture 21 - 1D - FE Problems : Galerkin's Approach
Link Computer Aided Design and Manufacturing Lecture 22 - Penalty Approach and Multi Point Boundary
Link Computer Aided Design and Manufacturing Lecture 23 - Quadratic Shape Functions
Link Computer Aided Design and Manufacturing Lecture 24 - 2D - FE Problems
Link Computer Aided Design and Manufacturing Lecture 25 - 2D - FE Problems (Continued.)
Link Computer Aided Design and Manufacturing Lecture 26 - 3D - FE Problems
Link Computer Aided Design and Manufacturing Lecture 27 - 3D - Tetrahedral and 2D - Quadrilateral Element
Link Computer Aided Design and Manufacturing Lecture 28 - Mesh Preparation
Link Computer Aided Design and Manufacturing Lecture 29 - Modeling of Curves
Link Computer Aided Design and Manufacturing Lecture 30 - Modeling of Curves
Link Computer Aided Design and Manufacturing Lecture 31 - Modeling of Curves
Link Computer Aided Design and Manufacturing Lecture 32 - Modeling of B-Spline Curves
Link Computer Aided Design and Manufacturing Lecture 33 - Modeling of B-spline Curves
Link Computer Aided Design and Manufacturing Lecture 34 - Surface Modeling
Link Computer Aided Design and Manufacturing Lecture 35 - Surface Modeling
Link Computer Aided Design and Manufacturing Lecture 36 - Display of Curves and Surfaces
Link Computer Aided Design and Manufacturing Lecture 37 - Solid Modeling
Link Computer Aided Design and Manufacturing Lecture 38 - Solid Modeling
Link Computer Aided Design and Manufacturing Lecture 39 - Solid Modeling Using Octrees
Link Computer Aided Design and Manufacturing Lecture 40 (Missing)
Link Computer Aided Design and Manufacturing Lecture 41 - Computer Aided Design
Link Computer Aided Design and Manufacturing Lecture 42 - Computer Aided Manufacturing
Link Computer Aided Design and Manufacturing Lecture 43 - What is CAD/CAM
Link Computer Aided Design and Manufacturing Lecture 44 - An Overview of Geometric Modeling
Link Computer Aided Design and Manufacturing Lecture 45 - Parametric Cubic Curve
Link Computer Aided Design and Manufacturing Lecture 46 - Parametric Bezier Curve
Link Computer Aided Design and Manufacturing Lecture 47 - B-Spline Curve
Link Computer Aided Design and Manufacturing Lecture 48 - Parametric Surfaces - Part-1
Link Computer Aided Design and Manufacturing Lecture 49 - Parametric Surfaces - Part-2
Link Computer Aided Design and Manufacturing Lecture 50 - Solid Modeling
Link Computer Aided Design and Manufacturing Lecture 51 - Geometric & Product Data Exchange
Link Computer Aided Design and Manufacturing Lecture 52 - Reverse Engineering
Link Project and Production Management Lecture 1 - Project and Production Management - An Overview
Link Project and Production Management Lecture 2 - Project Management: An Overview
Link Project and Production Management Lecture 3 - Project Identification and Screening
Link Project and Production Management Lecture 4 - Project Appraisal - Part I
Link Project and Production Management Lecture 5 - Project Appraisal - Part II
Link Project and Production Management Lecture 6 - Project Selection
Link Project and Production Management Lecture 7 - Project Representation
Link Project and Production Management Lecture 8 - Consistency and Redundancy in Project Networks
Link Project and Production Management Lecture 9 - Basic scheduling with A-O-A Networks
Link Project and Production Management Lecture 10 - Basic Scheduling with A-O-N Networks
Link Project and Production Management Lecture 11 - Project Scheduling with Probabilistic Activity
Link Project and Production Management Lecture 12 - Linear Time-Cost Tradeoffs in Projects
Link Project and Production Management Lecture 13 - Project Crashing with Multiple Objectives
Link Project and Production Management Lecture 14 - Resource Profiles and Leveling
Link Project and Production Management Lecture 15 - Limited Resource Allocation
Link Project and Production Management Lecture 16 - Project Monitoring and Control with PERT/Cost
Link Project and Production Management Lecture 17 - Team Building and Leadership in Projects
Link Project and Production Management Lecture 18 - Organizational and Behavioral Issues
Link Project and Production Management Lecture 19 - Computers in Project Management
Link Project and Production Management Lecture 20 - Project Completion and Review
Link Project and Production Management Lecture 21 - Life Cycle of a Production System
Link Project and Production Management Lecture 22 - Role of Models in Production Management
Link Project and Production Management Lecture 23 - Financial Evaluation of capital Decisions
Link Project and Production Management Lecture 24 - Decision Trees and Risk Evaluation
Link Project and Production Management Lecture 25 - Introducing New Products & Services
Link Project and Production Management Lecture 26 - Economic Evaluation of New Products & Services
Link Project and Production Management Lecture 27 - Product Mix Decisions
Link Project and Production Management Lecture 28 - Product & Process Design
Link Project and Production Management Lecture 29 - Issues in Location of Facilities
Link Project and Production Management Lecture 30 - Mathematical Models for Facility Location
Link Project and Production Management Lecture 31 - Layout planning
Link Project and Production Management Lecture 32 - Computerised Layout Planning
Link Project and Production Management Lecture 33 - Product Layouts and Assembly Line Balancing
Link Project and Production Management Lecture 34 - Forecasting
Link Project and Production Management Lecture 35 - The Analysis of Time Series
Link Project and Production Management Lecture 36 - Aggregate Production Planning: Basic Concepts
Link Project and Production Management Lecture 37 - Modelling Approaches
Link Project and Production Management Lecture 38 - Basic Inventory Principles
Link Project and Production Management Lecture 39 - Inventory Modelling
Link Project and Production Management Lecture 40 - Material Requirements Planning
Link Project and Production Management Lecture 41 - Scheduling of Job Shops
Link NOC:RAC Product Design Lecture 1 - Introduction to Design
Link NOC:RAC Product Design Lecture 2 - Design Considerations
Link NOC:RAC Product Design Lecture 3 - Basic Concepts Psychrometry and Air-Conditioning
Link NOC:RAC Product Design Lecture 4 - Refrigerants
Link NOC:RAC Product Design Lecture 5 - Refrigerant Properties and Applications
Link NOC:RAC Product Design Lecture 6 - Refrigeration Cycle and Components
Link NOC:RAC Product Design Lecture 7 - Compressor Selection
Link NOC:RAC Product Design Lecture 8 - Expansion Devices
Link NOC:RAC Product Design Lecture 9 - Condensers and Evaporators
Link NOC:RAC Product Design Lecture 10 - Types of Heat Exchangers and Air Conditioning Systems
Link NOC:RAC Product Design Lecture 11 - Selection of Air Conditioning Systems for Hostels
Link NOC:RAC Product Design Lecture 12 - Case Study on a Railway Air Conditioning System
Link NOC:RAC Product Design Lecture 13 - Vibration and noise issues in railway AC systems
Link NOC:RAC Product Design Lecture 14 - New product launch process
Link NOC:RAC Product Design Lecture 15 - Case study on a telecom cooling system and Emerging technologies
Link NOC:Thermodynamics Lecture 1 - Thermodynamic Concepts: Applications of thermodynamics
Link NOC:Thermodynamics Lecture 2 - Thermodynamic Concepts: System definition,Heat, Work and Mass Flow
Link NOC:Thermodynamics Lecture 3 - Thermodynamic Concepts: Questions and Answers
Link NOC:Thermodynamics Lecture 4 - Thermodynamic Concepts: Properties,State and Equilibrium
Link NOC:Thermodynamics Lecture 5 - Thermodynamic Concepts: Process, Cycles and Applications
Link NOC:Thermodynamics Lecture 6 - Thermodynamic Concepts: Steady state, Reversible and Irreversible processes
Link NOC:Thermodynamics Lecture 7 - Thermodynamic Concepts: Causes of irreversibility
Link NOC:Thermodynamics Lecture 8 - Thermodynamic Concepts: Thermal reservoirs
Link NOC:Thermodynamics Lecture 9 - Thermodynamic Concepts: Pressure and temperature
Link NOC:Thermodynamics Lecture 10 - Thermodynamic Concepts: Revision and Summary
Link NOC:Thermodynamics Lecture 11 - Laws Of Thermodynamics: Mass flow rate, Conservation of mass, Flow work
Link NOC:Thermodynamics Lecture 12 - Laws Of Thermodynamics: Zeroth Law
Link NOC:Thermodynamics Lecture 13 - Laws Of Thermodynamics: First Laws Of Thermodynamics, 1st law for Control Mass, Internal Energy, enthalpy
Link NOC:Thermodynamics Lecture 14 - Laws Of Thermodynamics: 1st law for Control Volume
Link NOC:Thermodynamics Lecture 15 - Laws Of Thermodynamics: Revision, Cycles, Second Law statements, Clausius inequality
Link NOC:Thermodynamics Lecture 16 - Laws Of Thermodynamics: Introduction to carnot Cycle
Link NOC:Thermodynamics Lecture 17 - Laws Of Thermodynamics: Entropy,Entropy change for a system
Link NOC:Thermodynamics Lecture 18 - Laws Of Thermodynamics: Thermodynamics relations,Bernoulli's equation
Link NOC:Thermodynamics Lecture 19 - Laws Of Thermodynamics: Devices, Cycles
Link NOC:Thermodynamics Lecture 20 - Properties of a Pure Substance: Thermodynamic behaviour of a pure substance
Link NOC:Thermodynamics Lecture 21 - Properties of a Pure Substance: Saturated states, Subcooled liquid, Superheated vapour
Link NOC:Thermodynamics Lecture 22 - Properties of a Pure Substance: Vapour pressure curve, Reference state
Link NOC:Thermodynamics Lecture 23 - Properties of a Pure Substance: Saturated states
Link NOC:Thermodynamics Lecture 24 - Properties of a Pure Substance: p-h diagram
Link NOC:Thermodynamics Lecture 25 - Properties of a Pure Substance: T-s diagram, h-s diagram
Link NOC:Thermodynamics Lecture 26 - Properties of a Pure Substance: Critical state, Compressibility factor
Link NOC:Thermodynamics Lecture 27 - Properties of a Pure Substance: Ideal gas behaviour, Equations of state, Specific heat
Link NOC:Thermodynamics Lecture 28 - Properties of a Pure Substance: Ideal gas processes
Link NOC:Thermodynamics Lecture 29 - Properties of a Pure Substance: Gibbs energy, Helmholtz function, Property relations
Link NOC:Thermodynamics Lecture 30 - Properties of a Pure Substance: Process analysis, Summary
Link NOC:Thermodynamics Lecture 31 - Laws of Thermodynamics: Carnot Cycle Realization
Link NOC:Thermodynamics Lecture 32 - Applications, Problem Solving: Devices, Schematic/Flow Diagrams
Link NOC:Thermodynamics Lecture 33 - Applications, Problem Solving: Positive Displacement Devices
Link NOC:Thermodynamics Lecture 34 - Applications, Problem Solving: Heat Exchangers
Link NOC:Thermodynamics Lecture 35 - Applications, Problem Solving: Compressors, Fans and Blowers, Pumps
Link NOC:Thermodynamics Lecture 36 - Applications, Problem Solving: Turbines
Link NOC:Thermodynamics Lecture 37 - Applications, Problem Solving: Nozzle, Diffuser, Expansion Valve, Pipe/duct flow
Link NOC:Thermodynamics Lecture 38 - Applications, Problem Solving: De-Superheater, Deaerator, Separation
Link NOC:Thermodynamics Lecture 39 - Applications, Problem Solving: Unsteady processes, Filling, Evacuation
Link NOC:Thermodynamics Lecture 40 - Applications, Problem Solving: Realization of Carnot cycle, Practical cycles, Air-standard cycles
Link NOC:Thermodynamics Lecture 41 - Applications, Problem Solving: Materials, Compressible flow
Link NOC:Thermodynamics Lecture 42 - Applications, Problem Solving: Otto cycle, Diesel cycle
Link NOC:Thermodynamics Lecture 43 - Applications, Problem Solving: Closed system
Link NOC:Thermodynamics Lecture 44 - Applications, Problem Solving: Open System
Link NOC:Thermodynamics Lecture 45 - Properties of Ideal Gas Mixtures: Introduction to mixtures properties
Link NOC:Thermodynamics Lecture 46 - Properties of Ideal Gas Mixtures: Equation of state, Conservation equations
Link NOC:Thermodynamics Lecture 47 - Gas-Vapour Mixtures: Psychrometry, Moist air Properties,
Link NOC:Thermodynamics Lecture 48 - Gas-Vapour Mixtures: Properties, Conservation of Mass and Energy
Link NOC:Thermodynamics Lecture 49 - Gas-Vapour Mixtures: Psychrometric chart, Applications
Link NOC:Thermodynamics Lecture 50 - Thermodynamics of Reacting sytems: Introduction to reacting systems and combustion
Link NOC:Thermodynamics Lecture 51 - Thermodynamics of Reacting sytems: Flames, Stoichiometry
Link NOC:Thermodynamics Lecture 52 - Thermodynamics of Reacting sytems: Analysis of Closed and Open Systems, Enthalpy of Formation
Link NOC:Thermodynamics Lecture 53 - Phase and Chemical Equilibrium: Introduction. Chemical equilibrium. Gibbs function
Link NOC:Thermodynamics Lecture 54 - Phase and Chemical Equilibrium: Equilibrium constant. Phase equilibrium
Link NOC:Solid Mechanics Lecture 1 - Mathematical Concepts: Working with Vectors and Tensors
Link NOC:Solid Mechanics Lecture 2 - Traction Vector
Link NOC:Solid Mechanics Lecture 3 - Stress Tensor and its Matrix Representation
Link NOC:Solid Mechanics Lecture 4 - Transformation of Stress Matrix
Link NOC:Solid Mechanics Lecture 5 - Stress Equilibrium Equations : Balance of Linear and Angular Momentum
Link NOC:Solid Mechanics Lecture 6 - Balance of Angular Momentum (Continued...)
Link NOC:Solid Mechanics Lecture 7 - Principal Planes and Principal stress components
Link NOC:Solid Mechanics Lecture 8 - Maximizing the Shear Component of Traction
Link NOC:Solid Mechanics Lecture 9 - Mohr's Circle
Link NOC:Solid Mechanics Lecture 10 - Mohr's Circle (Continued...), Stress Invariants, Decomposition of the Stress Tensor
Link NOC:Solid Mechanics Lecture 11 - Concept of Strain Tensor
Link NOC:Solid Mechanics Lecture 12 - Longitudinal and Shear Strains
Link NOC:Solid Mechanics Lecture 13 - Local Volumetric Strain and Local Infinitesimal Rotation
Link NOC:Solid Mechanics Lecture 14 - Similarity in Properties of Stress and Strain Tensors
Link NOC:Solid Mechanics Lecture 15 - Stress-Strain Relation
Link NOC:Solid Mechanics Lecture 16 - Stress-Strain Relation for Isotropic Materials
Link NOC:Solid Mechanics Lecture 17 - Linear Momentum Balance in Cylinderical Coordinate System
Link NOC:Solid Mechanics Lecture 18 - Linear Momentum Balance in Cylinderical Coordinate System (Continued...)
Link NOC:Solid Mechanics Lecture 19 - Strain Matrix Cylinderical Coordinate System
Link NOC:Solid Mechanics Lecture 20 - Extension-Torsion-Inflation in a Hollow Cylinder
Link NOC:Solid Mechanics Lecture 21 - Extension-Torsion-Inflation in a Hollow Cylinder (Continued...)
Link NOC:Solid Mechanics Lecture 22 - Solving Problems Involving Torsion of Shafts
Link NOC:Solid Mechanics Lecture 23 - Pure Bending of Rectangular Beams
Link NOC:Solid Mechanics Lecture 24 - Bending of Beams (Continued...)
Link NOC:Solid Mechanics Lecture 25 - Bending of Unsymmetrical Beams
Link NOC:Solid Mechanics Lecture 26 - Concept of Shear Center
Link NOC:Solid Mechanics Lecture 27 - Theoy of Beams
Link NOC:Solid Mechanics Lecture 28 - Theoy of Beams (Continued...) and Beam Buckling
Link NOC:Solid Mechanics Lecture 29 - Energy Methods
Link NOC:Solid Mechanics Lecture 30 - Energy Methods (Continued...)
Link NOC:Solid Mechanics Lecture 31 - Theories of Failure
Link NOC:Solid Mechanics Lecture 32 - Theories of Failure (Continued...)
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 1 - Course Outline, Introduction
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 2 - Experimentation Processes and Applications Overview
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 3 - Developments in Uncertainty Analysis, Approach
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 4 - Errors, Their Causes and Classification
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 5 - Errors to Uncertainty via Statistics
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 6 - Sources of Errors, Uncertainty Definitions
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 7 - Experimentation - I
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 8 - Experimentation Stages / Phases I
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 9 - Experimentation Stages / Phases II
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 10 - Uncertainty Analysis Processes
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 11 - Instrument ans DAS
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 12 - Basic procedure - I
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 13 - Basic procedure - II
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 14 - Evaluating systematic uncertainties
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 15 - Worksheets for uncertainty in a measurement, Examples
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 16 - Examples of uncertainty in a measurement
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 17 - Methodologies, Multiple tests method
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 18 - Single test, Basics of taylor Series Method
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 19 - Sensitivity coefficient, Result uncertainty from TSM
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 20 - Result uncertainty TSM: Special cases
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 21 - Method selection, Worksheets for result uncertainty
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 22 - Examples for result uncertainty - 1
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 23 - Examples for result uncertainty - 2
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 24 - Regression Introduction
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 25 - Regression analysis - Linear, single variable
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 26 - Correlation, Related topics
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 27 - Reporting uncertainties
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 28 - Validation and verification aspects, Data archiving
Link NOC:Introduction to Uncertainty Analysis and Experimentation Lecture 29 - Course overview
Link NOC:Engineering Graphics and Design Lecture 1 - Introduction
Link NOC:Engineering Graphics and Design Lecture 2 - Examples of visualization - 1
Link NOC:Engineering Graphics and Design Lecture 3 - Examples of visualization - 2
Link NOC:Engineering Graphics and Design Lecture 4 - Visualization and drawing
Link NOC:Engineering Graphics and Design Lecture 5 - Sketch to engineering drawing
Link NOC:Engineering Graphics and Design Lecture 6 - Types of projections
Link NOC:Engineering Graphics and Design Lecture 7 - Multiview projections
Link NOC:Engineering Graphics and Design Lecture 8 - 1st and 3rd angle projections
Link NOC:Engineering Graphics and Design Lecture 9 - Sketching
Link NOC:Engineering Graphics and Design Lecture 10 - Visualization
Link NOC:Engineering Graphics and Design Lecture 11 - Drawing sheet
Link NOC:Engineering Graphics and Design Lecture 12 - Lines
Link NOC:Engineering Graphics and Design Lecture 13 - Dimensioning
Link NOC:Engineering Graphics and Design Lecture 14 - Projection of a point line and plane
Link NOC:Engineering Graphics and Design Lecture 15 - Projection of simple objects
Link NOC:Engineering Graphics and Design Lecture 16 - Example Projection of a solid
Link NOC:Engineering Graphics and Design Lecture 17 - Example Projection of an object
Link NOC:Engineering Graphics and Design Lecture 18 - Types of Solids
Link NOC:Engineering Graphics and Design Lecture 19 - Polygons Construction and Projections
Link NOC:Engineering Graphics and Design Lecture 20 - Rotation of Solids
Link NOC:Engineering Graphics and Design Lecture 21 - Example Rotation of Solids
Link NOC:Engineering Graphics and Design Lecture 22 - Section views
Link NOC:Engineering Graphics and Design Lecture 23 - Sectioning practices
Link NOC:Engineering Graphics and Design Lecture 24 - Auxiliary views
Link NOC:Engineering Graphics and Design Lecture 25 - Example Section View
Link NOC:Engineering Graphics and Design Lecture 26 - Example Auxiliary View
Link NOC:Engineering Graphics and Design Lecture 27 - Pictorial Drawings
Link NOC:Engineering Graphics and Design Lecture 28 - Construction of Isometric Drawings
Link NOC:Engineering Graphics and Design Lecture 29 - Example Isometric drawings
Link NOC:Engineering Graphics and Design Lecture 30 - Working Drawing
Link NOC:Engineering Graphics and Design Lecture 31 - Example Sectional View of Assembly
Link NOC:Engineering Graphics and Design Lecture 32 - Computer Aided Design
Link NOC:Engineering Graphics and Design Lecture 33 - Autodesk Inventor Environment
Link NOC:Engineering Graphics and Design Lecture 34 - Sketching for Solid Modelling
Link NOC:Engineering Graphics and Design Lecture 35 - Example 1 Extrude Hole Fillet Chamfer
Link NOC:Engineering Graphics and Design Lecture 36 - Example 2 Rib Mirror
Link NOC:Engineering Graphics and Design Lecture 37 - Example 3
Link NOC:Engineering Graphics and Design Lecture 38 - Revolve Loft Pattern
Link NOC:Engineering Graphics and Design Lecture 39 - Example 4
Link NOC:Engineering Graphics and Design Lecture 40 - Example 5
Link NOC:Engineering Graphics and Design Lecture 41 - Spline Sweep Shell
Link NOC:Engineering Graphics and Design Lecture 42 - Example 6
Link NOC:Engineering Graphics and Design Lecture 43 - Example 7
Link NOC:Engineering Graphics and Design Lecture 44 - Drawing from Solid Model
Link NOC:Engineering Graphics and Design Lecture 45 - Assembly with constraints
Link NOC:Engineering Graphics and Design Lecture 46 - Example 8
Link NOC:Engineering Graphics and Design Lecture 47 - Example 9
Link NOC:Engineering Graphics and Design Lecture 48 - Example 10
Link NOC:Engineering Graphics and Design Lecture 49 - Example 11
Link NOC:Engineering Graphics and Design Lecture 50 - Civil and architectural drawings
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 1 - Ideal fluids, Velocity potential, Potential flows
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 2 - Stream function, Orthogonality of streamlines and equipotential lines
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 3 - Complex variables, Analyticity, Cauchy - Riemann equations, Complex potential, Complex velocity
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 4 - Elementary flows : Uniform flow, Source and Sink, Free vortex
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 5 - Flow in a bend, Flow around a sharp edge
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 6 - Superposition of source and sink : doublet flow
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 7 - Superposition of uniform flow and doublet
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 8 - Superposition of uniform flow, doublet and free vortex
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 9 - Superposition of source and uniform flow
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 10 - Problem solving session - 1
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 11 - Problem solving session - 2
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 12 - Method of images, Forces on a body, Blasius theorem
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 13 - Calculation of forces using derived flow field
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 14 - Introduction to conformal transformation
Link NOC:Ideal Fluid Flows using Complex Analysis Lecture 15 - Singularities and their transformations
Link NOC:Experimental Modal Analysis Lecture 1
Link NOC:Experimental Modal Analysis Lecture 2
Link NOC:Experimental Modal Analysis Lecture 3
Link NOC:Experimental Modal Analysis Lecture 4
Link NOC:Experimental Modal Analysis Lecture 5
Link NOC:Experimental Modal Analysis Lecture 6
Link NOC:Experimental Modal Analysis Lecture 7
Link NOC:Experimental Modal Analysis Lecture 8
Link NOC:Experimental Modal Analysis Lecture 9
Link NOC:Experimental Modal Analysis Lecture 10
Link NOC:Experimental Modal Analysis Lecture 11
Link NOC:Experimental Modal Analysis Lecture 12
Link NOC:Experimental Modal Analysis Lecture 13
Link NOC:Experimental Modal Analysis Lecture 14
Link NOC:Experimental Modal Analysis Lecture 15
Link NOC:Experimental Modal Analysis Lecture 16
Link NOC:Experimental Modal Analysis Lecture 17
Link NOC:Experimental Modal Analysis Lecture 18
Link NOC:Experimental Modal Analysis Lecture 19
Link NOC:Experimental Modal Analysis Lecture 20
Link NOC:Experimental Modal Analysis Lecture 21
Link NOC:Experimental Modal Analysis Lecture 22
Link NOC:Experimental Modal Analysis Lecture 23
Link NOC:Experimental Modal Analysis Lecture 24
Link NOC:Experimental Modal Analysis Lecture 25
Link NOC:Experimental Modal Analysis Lecture 26
Link NOC:Experimental Modal Analysis Lecture 27
Link NOC:Experimental Modal Analysis Lecture 28
Link NOC:Experimental Modal Analysis Lecture 29
Link NOC:Experimental Modal Analysis Lecture 30
Link NOC:Experimental Modal Analysis Lecture 31
Link NOC:Experimental Modal Analysis Lecture 32
Link NOC:Experimental Modal Analysis Lecture 33
Link NOC:Experimental Modal Analysis Lecture 34
Link NOC:Experimental Modal Analysis Lecture 35
Link NOC:Experimental Modal Analysis Lecture 36
Link NOC:Experimental Modal Analysis Lecture 37
Link NOC:Experimental Modal Analysis Lecture 38
Link NOC:Experimental Modal Analysis Lecture 39
Link NOC:Experimental Modal Analysis Lecture 40
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 1 - Introduction to polymers
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 2 - Polymer structure
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 3 - Polymer classification
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 4 - Polymer length, packing and tacticity
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 5 - Glass transition temperature
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 6 - Temperature effects, glassy regime
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 7 - Viscoelastic, rubbery, viscous, decomposition
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 8 - Relaxation and creep tests
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 9 - Failure of polymers
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 10 - Heaviside, Dirac delta, Laplace
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 11 - Introduction to linear viscoelasticity
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 12 - Phenomenological models for linear viscoelasticity
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 13 - Maxwell model
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 14 - Kelvin model
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 15 - Three and four parameter models
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 16 - Generalized Maxwell and Kelvin models
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 17 - Boltzman superposition principle
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 18 - Alfrey's correspondence principle
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 19 - Analysis of viscoelastic bars
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 20 - Analysis of viscoelastic beams
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 21 - Dynamic mechanical analysis (DMA)
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 22 - Dynamic mechanical thermal analysis (DMTA)
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 23 - Time temperature superposition principle (TTSP)
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 24 - Plastic design consideration and practices
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 25 - What are composites?
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 26 - Composite materials and types
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 27 - Composite advantages and applications
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 28 - Fabrication and other aspects of composites
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 29 - 3D stress and strain components
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 30 - Symmetry in stress, strain and stiffness matrix
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 31 - Monoclinic, orthotropic and isotropic materials
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 32 - 3D stress strain relation for orthotropic material
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 33 - Plane stress: Specially orthotropic material
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 34 - Plane stress: Generally orthotropic material
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 35 - Lamina engineering constants
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 36 - Lamina hygrothermal effects
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 37 - Lamina fundamental strengths
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 38 - Lamina failure criteria
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 39 - Tsai-Hill and Hoffman failure criteria
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 40 - Micromechanics: Assumptions, RVE
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 41 - Micromechanics: Stiffness prediction
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 42 - Micromechanics: Stiffness and strength
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 43 - Macromechanics of laminate
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 44 - Classical laminate theory
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 45 - Classical laminate theory - II
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 46 - Symmetric laminates, orthotropic laminates
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 47 - Angle-ply, cross-ply and quasi-isotropic laminates
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 48 - Hygrothermal stresses in laminates
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 49 - Laminate failure
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 50 - Design practices with laminates
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 51 - Sandwich structures
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 52 - Composites testing
Link NOC:Mechanical Behavior of Polymers and Composites Lecture 53 - Joining of composites
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 1 - Introduction to Tribology
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 2 - Tribological Interfaces
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 3 - Fundamentals of Friction and Wear
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 4 - Adhesion, Abrasion, and Surface Fatigue Mechanisms
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 5 - Wear Measurement Techniques
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 6 - Principles of Lubrication, types of Lubricants and their properties
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 7 - Lubrication regimes and film thickness calculations
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 8 - Mixed Lubrication
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 9 - Hydrodynamic Lubrication Theory
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 10 - Design Considerations for Hydrodynamic Lubrication Systems
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 11 - Elastohydrodynamic Lubrication
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 12 - Solid Lubrication
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 13 - Surface modification techniques for tribological applications
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 14 - Thin film coatings and their tribological properties
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 15 - Nanotribology
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 16 - Tribocorrosion
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 17 - Wear testing techniques and standards
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 18 - Measurement and analysis of wear debris
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 19 - Experimental Design and Statistical Analysis
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 20 - Introduction to Data-Enabled Engineering
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 21 - Data Collection and Preprocessing
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 22 - Feature Extraction and Selection
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 23 - Introduction to Machine Learning Algorithms
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 24 - Regression and Classification Algorithms for Tribological Modeling
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 25 - Deep Learning for Tribological Engineering
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 26 - Data-Driven Models for Friction Prediction
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 27 - Data-Driven Models for Wear Prediction
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 28 - Data-Driven Models for Lubricant Optimization
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 29 - Data-Driven Models for Tribofilm Formation
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 30 - Data-Driven Models for Tribocorrosion Prediction
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 31 - Prediction of Coating and Surface Treatment Performance
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 32 - Optimization of Surface Engineering Processes using Machine Learning
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 33 - Uncertainty Quantification and Sensitivity Analysis
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 34 - Data Management and Ethics in Data-Enabled Engineering
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 35 - Case Studies in Data-Enabled Tribological Engineering
Link NOC:Data-Enabled Tribological Engineering: From Experiments to Predictive Models Lecture 36 - Future Directions in Data-Enabled Tribological Engineering
Link Nonlinear Vibration Lecture 1 - Introduction of Nonlinear systems
Link Nonlinear Vibration Lecture 2 - Review of Linear vibrating systems
Link Nonlinear Vibration Lecture 3 - Phenomena associated with Nonlinear systems
Link Nonlinear Vibration Lecture 4 - Commonly observed Phenomena in Nonlinear systems
Link Nonlinear Vibration Lecture 5 - Force and Moment based Approach
Link Nonlinear Vibration Lecture 6 - Energy based approach Extended Hamilton’s principle and Lagrange Priciple
Link Nonlinear Vibration Lecture 7 - Derivation of Equation of motion of nonlinear discrete system (More examples)
Link Nonlinear Vibration Lecture 8 - Derivation of Equation of motion of nonlinear continuous system - 1
Link Nonlinear Vibration Lecture 9 - Derivation of Equation of motion of nonlinear continuous system - 2
Link Nonlinear Vibration Lecture 10 - Ordering of nonlinear Equation of motion
Link Nonlinear Vibration Lecture 11 - Qualitative Analysis Straight forward expansion
Link Nonlinear Vibration Lecture 12 - Numerical method Straight forward expansion
Link Nonlinear Vibration Lecture 13 - Lindstedt Poincare’ technique
Link Nonlinear Vibration Lecture 14 - Method of multiple scales
Link Nonlinear Vibration Lecture 15 - Method of Harmonic balance
Link Nonlinear Vibration Lecture 16 - Method of averaging
Link Nonlinear Vibration Lecture 17 - Generalized Method of averaging
Link Nonlinear Vibration Lecture 18 - Krylov-Bogoliubov-Mitropolski technique
Link Nonlinear Vibration Lecture 19 - Incremental harmonic balance method and Intrinsic multiple scale harmonic balance method
Link Nonlinear Vibration Lecture 20 - Modified Lindstedt Poincare’ technique
Link Nonlinear Vibration Lecture 21 - Stability and Bifurcation of Fixed-point response - 1
Link Nonlinear Vibration Lecture 22 - Stability and Bifurcation of Fixed-point response - 2
Link Nonlinear Vibration Lecture 23 - Stability and Bifurcation of Fixed-point response - 3
Link Nonlinear Vibration Lecture 24 - Stability and Bifurcation of Fixed-point response - 4
Link Nonlinear Vibration Lecture 25 - Stability Analysis of Periodic response
Link Nonlinear Vibration Lecture 26 - Bifurcation of Periodic response And Introduction to quasi-periodic and Chaotic response
Link Nonlinear Vibration Lecture 27 - Quasi-Periodic and Chaotic response
Link Nonlinear Vibration Lecture 28 - Numerical methods to obtain roots of characteristic equation and time response
Link Nonlinear Vibration Lecture 29 - Numerical methods to obtain time response
Link Nonlinear Vibration Lecture 30 - Numerical methods to obtain frequency response
Link Nonlinear Vibration Lecture 31 - Free Vibration of Single degree of freedom Nonlinear systems with Cubic and quadratic nonlinearities
Link Nonlinear Vibration Lecture 32 - Free Vibration of Single degree of freedom Nonlinear systems with Cubic and quadratic nonlinearities: effect of damping
Link Nonlinear Vibration Lecture 33 - Free Vibration of multi- degree of freedom Nonlinear systems with Cubic and quadratic nonlinearities
Link Nonlinear Vibration Lecture 34 - Forced nonlinear Vibration Single degree of freedom Nonlinear systems with Cubic nonlinearities:
Link Nonlinear Vibration Lecture 35 - Forced nonlinear Vibration Single and multi- degree of freedom Nonlinear systems
Link Nonlinear Vibration Lecture 36 - Nonlinear Forced-Vibration of Single and Multi Degree-of-Freedom System
Link Nonlinear Vibration Lecture 37 - Analysis of Multi- degree of freedom system
Link Nonlinear Vibration Lecture 38 - Nonlinear Vibration of Parametrically excited system: Axially loaded sandwich beam
Link Nonlinear Vibration Lecture 39 - Nonlinear Vibration of Parametrically excited system: Elastic and Magneto-elastic beam
Link Nonlinear Vibration Lecture 40 - Nonlinear Vibration of Parametrically excited system with internal resonance
Link Theory and Practice of Rotor Dynamics Lecture 1 - Introduction
Link Theory and Practice of Rotor Dynamics Lecture 2 - A Brief History of Rotor Dynamics
Link Theory and Practice of Rotor Dynamics Lecture 3 - The State of the Art of Rotor Dynamics
Link Theory and Practice of Rotor Dynamics Lecture 4 - Simple Rotor Models with Rigid Bearings
Link Theory and Practice of Rotor Dynamics Lecture 5 - Jeffcott Rotor Model
Link Theory and Practice of Rotor Dynamics Lecture 6 - Variant of Jeffcott Rotor Model
Link Theory and Practice of Rotor Dynamics Lecture 7 - Rigid Rotor Mounted on Simple Anistropic Springs as Bearings
Link Theory and Practice of Rotor Dynamics Lecture 8 - Rigid Rotor Mounted on Complex Anisotropic Bearings
Link Theory and Practice of Rotor Dynamics Lecture 9 - Flexible Shaft with a Rigid Disc Mounted on Anistropic Supports
Link Theory and Practice of Rotor Dynamics Lecture 10 - Gyroscopic Effects : Synchronous whirl of a Rotor Systems with a thin Disc
Link Theory and Practice of Rotor Dynamics Lecture 11 - Gyroscopic Effects : Synchronous and Asynchronous pure wobbling motions
Link Theory and Practice of Rotor Dynamics Lecture 12 - Gyroscopic Effects : Asynchronous whirl of a Rotor system with a thin Disc
Link Theory and Practice of Rotor Dynamics Lecture 13 - Gyroscopic Effects : Asynchronous whirl analysis with Dynamic Approach
Link Theory and Practice of Rotor Dynamics Lecture 14 - Torsional Vibrations: Simple Rotor Systems
Link Theory and Practice of Rotor Dynamics Lecture 15 - Three Disc Rotor System
Link Theory and Practice of Rotor Dynamics Lecture 16 - Transfer Matrix Approach - Part I
Link Theory and Practice of Rotor Dynamics Lecture 17 - Transfer Matrix Approach - Part II
Link Theory and Practice of Rotor Dynamics Lecture 18 - Transfer Matrix Approach - Part III
Link Theory and Practice of Rotor Dynamics Lecture 19 - Geared and Branched Systems
Link Theory and Practice of Rotor Dynamics Lecture 20 - Continuous System and Finite Element Method
Link Theory and Practice of Rotor Dynamics Lecture 21 - Finite Element Method
Link Theory and Practice of Rotor Dynamics Lecture 22 - Finite Element Analysis
Link Theory and Practice of Rotor Dynamics Lecture 23 - Finite Element Analysis - Part III
Link Theory and Practice of Rotor Dynamics Lecture 24 - Influence Coefficient Method
Link Theory and Practice of Rotor Dynamics Lecture 25 - Transfer Matrix Method - Part I
Link Theory and Practice of Rotor Dynamics Lecture 26 - Transfer Matrix Method - Part II
Link Theory and Practice of Rotor Dynamics Lecture 27 - Transfer Matrix Method - Part III
Link Theory and Practice of Rotor Dynamics Lecture 28 - Continuous System Approach
Link Theory and Practice of Rotor Dynamics Lecture 29 - Finite Element Method - Part I
Link Theory and Practice of Rotor Dynamics Lecture 30 - Finite Element Method - Part II
Link Theory and Practice of Rotor Dynamics Lecture 31 - Finite Element Method - Part III
Link Theory and Practice of Rotor Dynamics Lecture 32 - Instability in Rotor Systems: Bearings
Link Theory and Practice of Rotor Dynamics Lecture 33 - Fluid-Film Bearings
Link Theory and Practice of Rotor Dynamics Lecture 34 - Internal Damping & Asymmetrical Shaft
Link Theory and Practice of Rotor Dynamics Lecture 35 - Steam Whirl and Seals
Link Theory and Practice of Rotor Dynamics Lecture 36 - Subcritical Speed Whirl
Link Theory and Practice of Rotor Dynamics Lecture 37 - Introduction to Rigid Rotor Balancing
Link Theory and Practice of Rotor Dynamics Lecture 38 - Dynamic Balancing of Rotors: Rigid Rotor Balancing
Link Theory and Practice of Rotor Dynamics Lecture 39 - Dynamic Balancing of Rotors:Flexible Rotor Model Balancing
Link Theory and Practice of Rotor Dynamics Lecture 40 - Dynamic Balancing of Rotors:Influence Coefficient Method for Flexible Rotor
Link Theory and Practice of Rotor Dynamics Lecture 41 - Common Faults & Vibration signatures
Link Theory and Practice of Rotor Dynamics Lecture 42 - Condition Based Monitoring
Link Engineering Mechanics Lecture 1 - Fundamentals Of Engineering Mechanics
Link Engineering Mechanics Lecture 2 - Equations of Equilibrium
Link Engineering Mechanics Lecture 3 - Truss Analysis - Part 1
Link Engineering Mechanics Lecture 4 - Truss Analysis - Part 2
Link Engineering Mechanics Lecture 5 - Analysis of Frames Machines
Link Engineering Mechanics Lecture 6 - Internal Forces
Link Engineering Mechanics Lecture 7 - Internal Forces in Beams
Link Engineering Mechanics Lecture 8 - Cables
Link Engineering Mechanics Lecture 9 - Friction
Link Engineering Mechanics Lecture 10 - Application of Friction - Part 1
Link Engineering Mechanics Lecture 11 - Application of Friction - Part 2
Link Engineering Mechanics Lecture 12 - Application of Friction - Part 3
Link Engineering Mechanics Lecture 13 - Centroids Center of Mass
Link Engineering Mechanics Lecture 14 - Centroids Area of Moments
Link Engineering Mechanics Lecture 15 - Product of Inertia, Rotation of Axis and Principle Moments of Inertia
Link Engineering Mechanics Lecture 16 - Principle Mass Moments of Inertia
Link Engineering Mechanics Lecture 17 - Second Moment of Mass
Link Engineering Mechanics Lecture 18 - Virtual Work of Ideal System
Link Engineering Mechanics Lecture 19 - Principle of Virtual Work
Link Engineering Mechanics Lecture 20 - Systems with Friction
Link Engineering Mechanics Lecture 21 - Potential Energy
Link Engineering Mechanics Lecture 22 - Stability of Equilibrium
Link Engineering Mechanics Lecture 23 - Kinematics of a Particles
Link Engineering Mechanics Lecture 24 - Kinematics of a Particle Moving on a Curve
Link Engineering Mechanics Lecture 25 - Relative Motion
Link Engineering Mechanics Lecture 26 - Plane Kinematics of Rigid Bodies
Link Engineering Mechanics Lecture 27 - Kinematics of a Particle
Link Engineering Mechanics Lecture 28 - Work and Energy
Link Engineering Mechanics Lecture 29 - Impulse and Momentum
Link Engineering Mechanics Lecture 30 - Direct and Oblique Impulse
Link Engineering Mechanics Lecture 31 - Plane Kinetics of Rigid Bodies
Link Engineering Mechanics Lecture 32 - Kinetics of a Body
Link Engineering Mechanics Lecture 33 - Method of Momentum and Analysis of Robot Manipulator
Link Engineering Mechanics Lecture 34 - Kinematics in 3D
Link Engineering Mechanics Lecture 35 - Kinetics in 3D
Link Engineering Mechanics Lecture 36 - Free Vibration
Link Engineering Mechanics Lecture 37 - Forced Vibration Damped Undamped
Link Engineering Mechanics Lecture 38 - Vibration of Rigid Bodies - Part 1
Link Engineering Mechanics Lecture 39 - Vibration of Rigid Bodies - Part 2
Link Engineering Mechanics Lecture 40 - Some Problems of Vibration
Link Mechanical Vibrations Lecture 1 - Overview of the Course, Practical and Research Trends
Link Mechanical Vibrations Lecture 2 - Harmonic and Periodic Motions, Vibration Terminology
Link Mechanical Vibrations Lecture 3 - Vibration Model, Equation of Motion-Natural Frequency
Link Mechanical Vibrations Lecture 4 - Energy Method, Principle of Virtual Work
Link Mechanical Vibrations Lecture 5 - Viscously Damped Free Vibration Special Cases: Oscillatory
Link Mechanical Vibrations Lecture 6 - Logarithmic Decrement Experimental Determination of Damping Coefficient Hystersis Loop
Link Mechanical Vibrations Lecture 7 - Coulomb Damping other Damping Models
Link Mechanical Vibrations Lecture 8 - Forced Harmonic Vibration, Magnification Factor
Link Mechanical Vibrations Lecture 9 - Laplace Transform, Superposition Theorem
Link Mechanical Vibrations Lecture 10 - Rotor Unbalance and Whirling of Shaft, Transmissibility
Link Mechanical Vibrations Lecture 11 - Support Motion, Vibration Isolation
Link Mechanical Vibrations Lecture 12 - Sharpness of Resonance, Vibration Measuring Instruments
Link Mechanical Vibrations Lecture 13 - Generalized and Principle Coordinates, Derivation of Equation of Motion
Link Mechanical Vibrations Lecture 14 - Lagranges's Equation
Link Mechanical Vibrations Lecture 15 - Coordinate Coupling
Link Mechanical Vibrations Lecture 16 - Forced Harmonic Vibration
Link Mechanical Vibrations Lecture 17 - Tuned Absorber, Determination of Mass Ratio
Link Mechanical Vibrations Lecture 18 - Tuned and Damped Absorber, Untuned Viscous Damper
Link Mechanical Vibrations Lecture 19 - Derivation of Equations of Motion, Influence Coefficient Method
Link Mechanical Vibrations Lecture 20 - Properties of Vibrating Systems: Flexibility & Stiffness Matrices, Reciprocity Theorem
Link Mechanical Vibrations Lecture 21 - Modal Analysis: Undamped
Link Mechanical Vibrations Lecture 22 - Modal Analysis: Damped
Link Mechanical Vibrations Lecture 23 - Simple Systems With One Two or Three Discs Geared System
Link Mechanical Vibrations Lecture 24 - Multi-Degree of Freedom Systems-Transfer Matrix Method Branched Systems
Link Mechanical Vibrations Lecture 25 - Derivation of Equations of Motion Part 1 - Newton
Link Mechanical Vibrations Lecture 26 - Derivation of Equations of Motion Part 2 - Newton
Link Mechanical Vibrations Lecture 27 - Vibration of Strings
Link Mechanical Vibrations Lecture 28 - Longitudinal and Torsional Vibration of Rods
Link Mechanical Vibrations Lecture 29 - Transverse Vibration of Beams, Equations of Motion and Boundary Conditions
Link Mechanical Vibrations Lecture 30 - Transverse Vibration of Beams: Natural Frequencies and Mode Shapes
Link Mechanical Vibrations Lecture 31 - Rayleigh's Energy Method
Link Mechanical Vibrations Lecture 32 - Matrix Iteration Method
Link Mechanical Vibrations Lecture 33 - Durkerley, Rayleigh-Ritz and Galerkin Method
Link Mechanical Vibrations Lecture 34 - Finite Element Formulation for Rods, Gear Train and Branched System
Link Mechanical Vibrations Lecture 35 - Finite Element Formulation for Beams: Galerkin
Link Mechanical Vibrations Lecture 36 - Global Finite Element Assembly and Imposition of Boundary Conditions
Link Mechanical Vibrations Lecture 37 - Vibration Testing Equipments: Signal Measurements
Link Mechanical Vibrations Lecture 38 - Vibration Testing Equipments: Signal Analysis
Link Mechanical Vibrations Lecture 39 - Field Balancing of Rotors
Link Mechanical Vibrations Lecture 40 - Condition Monitoring
Link NOC:Advanced Machining Processes Lecture 1 - Introduction to advanced machining processes
Link NOC:Advanced Machining Processes Lecture 2 - Ultrasonic machining - Part I
Link NOC:Advanced Machining Processes Lecture 3 - Ultrasonic machining - Part II
Link NOC:Advanced Machining Processes Lecture 4 - Abrasive jet machining
Link NOC:Advanced Machining Processes Lecture 5 - Water jet cutting and Abrasive water jet machining
Link NOC:Advanced Machining Processes Lecture 6 - Magnetic abrasive finishing
Link NOC:Advanced Machining Processes Lecture 7 - Abrasive Flow Finishing
Link NOC:Advanced Machining Processes Lecture 8 - Magnetorheological Finishing
Link NOC:Advanced Machining Processes Lecture 9 - Magnetorheological Abrasive Flow Finishing - Part I
Link NOC:Advanced Machining Processes Lecture 10 - Magnetorheological Abrasive Flow Finishing - Part II
Link NOC:Advanced Machining Processes Lecture 11 - Magnetorheological Abrasive Flow Finishing - Part III
Link NOC:Advanced Machining Processes Lecture 12 - Electric discharge machining (EDM)
Link NOC:Advanced Machining Processes Lecture 13 - Electric Discharge Grinding, Electric Discharge Diamond Grinding and Wire Electric Discharge Machining
Link NOC:Advanced Machining Processes Lecture 14 - Electrochemical Machining (ECM)
Link NOC:Advanced Machining Processes Lecture 15 - Electrochemical Grinding, Electrostream Drilling, Shaped Tube Electrolytic Machining
Link NOC:Advanced Machining Processes Lecture 16 - Plasma Arc Machining (PAM)
Link NOC:Advanced Machining Processes Lecture 17 - Electron Beam Machining (EBM) Edit Lesson
Link NOC:Advanced Machining Processes Lecture 18 - Laser Beam Machining (LBM)
Link NOC:Advanced Machining Processes Lecture 19 - Chemical Machining (ChM)
Link NOC:Fundamentals of Nuclear Power Generation Lecture 1 - Introduction of nuclear energy
Link NOC:Fundamentals of Nuclear Power Generation Lecture 2 - Binding energy and mass defect
Link NOC:Fundamentals of Nuclear Power Generation Lecture 3 - Radioactivity and radioactive decay
Link NOC:Fundamentals of Nuclear Power Generation Lecture 4 - Different types of nuclear transmutation
Link NOC:Fundamentals of Nuclear Power Generation Lecture 5 - Artificial radioactivity and neutron-nucleus interactions
Link NOC:Fundamentals of Nuclear Power Generation Lecture 6 - Energy and momentum conservation
Link NOC:Fundamentals of Nuclear Power Generation Lecture 7 - Fission and role of neutron energy
Link NOC:Fundamentals of Nuclear Power Generation Lecture 8 - Theory of elastic scattering
Link NOC:Fundamentals of Nuclear Power Generation Lecture 9 - Neutron multiplication factor
Link NOC:Fundamentals of Nuclear Power Generation Lecture 10 - Neutron diffusion theory
Link NOC:Fundamentals of Nuclear Power Generation Lecture 11 - Solution of one-group diffusion equation
Link NOC:Fundamentals of Nuclear Power Generation Lecture 12 - Simple reactor theory
Link NOC:Fundamentals of Nuclear Power Generation Lecture 13 - Nuclear fuel and simple energy consideration
Link NOC:Fundamentals of Nuclear Power Generation Lecture 14 - Axial temperature distribution and heat transfer coefficient
Link NOC:Fundamentals of Nuclear Power Generation Lecture 15 - Prompt and delayed neutrons
Link NOC:Fundamentals of Nuclear Power Generation Lecture 16 - Delayed neutron kinetics
Link NOC:Fundamentals of Nuclear Power Generation Lecture 17 - Different control mechanisms and various effects
Link NOC:Fundamentals of Nuclear Power Generation Lecture 18 - Classical reactor designs
Link NOC:Fundamentals of Nuclear Power Generation Lecture 19 - Evolution of reactors from Gen-I to Gen-IV
Link NOC:Fundamentals of Nuclear Power Generation Lecture 20 - The concept of breeding
Link NOC:Fundamentals of Nuclear Power Generation Lecture 21 - Fuel cycles and FBR
Link NOC:Fundamentals of Nuclear Power Generation Lecture 22 - Gen-IV FBR designs
Link NOC:Fundamentals of Nuclear Power Generation Lecture 23 - Hydrogen fusion reactions
Link NOC:Fundamentals of Nuclear Power Generation Lecture 24 - Coulomb barrier and other critical factors
Link NOC:Fundamentals of Nuclear Power Generation Lecture 25 - Radiation dose and gross biological effects
Link NOC:Fundamentals of Nuclear Power Generation Lecture 26 - Stochastic and deterministic effects of human cells
Link NOC:Fundamentals of Nuclear Power Generation Lecture 27 - Lessons from TMI and Chernobyl
Link NOC:Fundamentals of Nuclear Power Generation Lecture 28 - Defence-in-depth Philosophy
Link NOC:Fundamentals of Nuclear Power Generation Lecture 29 - Waste classification and Disposal of Mill Tailings
Link NOC:Fundamentals of Nuclear Power Generation Lecture 30 - Disposal methodologies for HLW and IMW
Link NOC:Advances in Welding and Joining Technologies Lecture 1 - Fundamentals of Welding and Joining - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 2 - Fundamentals of Welding and Joining - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 3 - Fundamentals of Welding and Joining - Part III
Link NOC:Advances in Welding and Joining Technologies Lecture 4 - Fundamentals of Welding and Joining - Part IV
Link NOC:Advances in Welding and Joining Technologies Lecture 5 - Fundamentals of Welding and Joining - Part V
Link NOC:Advances in Welding and Joining Technologies Lecture 6 - Laser and Electron Beam Welding - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 7 - Laser and Electron Beam Welding - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 8 - Solid State Welding Processes - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 9 - Solid State Welding Processes - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 10 - Solid State Welding Processes - Part III
Link NOC:Advances in Welding and Joining Technologies Lecture 11 - Computational Welding Mechanics - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 12 - Computational Welding Mechanics - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 13 - Computational Welding Mechanics - Part III
Link NOC:Advances in Welding and Joining Technologies Lecture 14 - Micro and Nano Joining Processes - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 15 - Micro and Nano Joining Processes - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 16 - Micro and Nano Joining Processes - Part III
Link NOC:Advances in Welding and Joining Technologies Lecture 17 - Welding Metallurgy - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 18 - Welding Metallurgy - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 19 - Welding Metallurgy - Part III
Link NOC:Advances in Welding and Joining Technologies Lecture 20 - Welding Metallurgy - Part IV
Link NOC:Advances in Welding and Joining Technologies Lecture 21 - Welding and Joining of Non-Metals - Part I
Link NOC:Advances in Welding and Joining Technologies Lecture 22 - Welding and Joining of Non-Metals - Part II
Link NOC:Advances in Welding and Joining Technologies Lecture 23 - Metal Transfer in Welding and Metal Printing
Link NOC:Introduction to Machining and Machining Fluids Lecture 1 - Introduction
Link NOC:Introduction to Machining and Machining Fluids Lecture 2 - Introduction and Importance of Machining
Link NOC:Introduction to Machining and Machining Fluids Lecture 3 - Principles of Machining or Metal Cutting
Link NOC:Introduction to Machining and Machining Fluids Lecture 4 - Cutting Tools
Link NOC:Introduction to Machining and Machining Fluids Lecture 5 - Forces in Machining
Link NOC:Introduction to Machining and Machining Fluids Lecture 6 - Tribology in Machining
Link NOC:Introduction to Machining and Machining Fluids Lecture 7 - Lubrication surface roughness in Machining
Link NOC:Introduction to Machining and Machining Fluids Lecture 8 - Machinability and Thermal Aspects
Link NOC:Introduction to Machining and Machining Fluids Lecture 9 - Tool Wear and Tool life - Part 1
Link NOC:Introduction to Machining and Machining Fluids Lecture 10 - Tool Wear and Tool life - Part 2
Link NOC:Introduction to Machining and Machining Fluids Lecture 11 - Tool Wear and Tool life - Part 3
Link NOC:Introduction to Machining and Machining Fluids Lecture 12 - Tool Materials and Coatings
Link NOC:Introduction to Machining and Machining Fluids Lecture 13 - Machining Fluids / Cutting Fluids and its Additives - Part 1
Link NOC:Introduction to Machining and Machining Fluids Lecture 14 - Machining Fluids / Cutting Fluids and its Additives - Part 2
Link NOC:Introduction to Machining and Machining Fluids Lecture 15 - Machining Fluids / Cutting Fluids and its Emissions
Link NOC:Introduction to Machining and Machining Fluids Lecture 16 - Eco Friendly Cutting Fluids - Part 1
Link NOC:Introduction to Machining and Machining Fluids Lecture 17 - Eco Friendly Cutting Fluids - Part 2
Link NOC:Introduction to Machining and Machining Fluids Lecture 18 - Rheology and Thermal Characterization of Machining / Cutting Fluids
Link NOC:Introduction to Machining and Machining Fluids Lecture 19 - Bio-degradation Studies of Machining / Cutting Fluids
Link NOC:Introduction to Machining and Machining Fluids Lecture 20 - Cutting Fluid Application in Machining Region
Link NOC:Introduction to Machining and Machining Fluids Lecture 21 - Practical Machining Processes - 1
Link NOC:Introduction to Machining and Machining Fluids Lecture 22 - Practical Machining Processes - 2
Link NOC:Introduction to Machining and Machining Fluids Lecture 23 - Introduction to Abrasive Processes - Grinding
Link NOC:Introduction to Machining and Machining Fluids Lecture 24 - Cutting fluids in Grinding Process
Link NOC:Introduction to Machining and Machining Fluids Lecture 25 - Unbonded Conventional Abrasive Processes
Link NOC:Introduction to Machining and Machining Fluids Lecture 26 - Advances in Metal Cutting_Machining Processes
Link NOC:Introduction to Machining and Machining Fluids Lecture 27 - Advances in Metal Cutting_Machining Processes - 2
Link NOC:Mechanics of Machining Lecture 1 - Deformation of Metals
Link NOC:Mechanics of Machining Lecture 2 - Mechanism of Plastic Deformation
Link NOC:Mechanics of Machining Lecture 3 - Machining Processes: Single Edge Tool, Types of Chips
Link NOC:Mechanics of Machining Lecture 4 - Tool Geometry: Single Point Cutting Tool Specifications
Link NOC:Mechanics of Machining Lecture 5 - Tool Specifications, Conversion Of Tool Angles, Multi-Point Cutting Tools
Link NOC:Mechanics of Machining Lecture 6 - Mechanics of Orthogonal Cutting, Force Relationships
Link NOC:Mechanics of Machining Lecture 7 - Determination of Stress, Strain, and Strain Rate
Link NOC:Mechanics of Machining Lecture 8 - Measurement of Shear Angle
Link NOC:Mechanics of Machining Lecture 9 - Other Analysis for Force Relationships
Link NOC:Mechanics of Machining Lecture 10 - Mechanics of Oblique Cutting
Link NOC:Mechanics of Machining Lecture 11 - Measurement of Cutting Forces
Link NOC:Mechanics of Machining Lecture 12 - Thermal Aspects Of Machining: Temperatures in Orthogonal Cutting
Link NOC:Mechanics of Machining Lecture 13 - Tool Wear and Tool Life and Tool Life Equations
Link NOC:Mechanics of Machining Lecture 14 - Economics in Machining
Link NOC:Mechanics of Machining Lecture 15 - Practical Machining Operations: Turning And Shaping and Planning Operation
Link NOC:Mechanics of Machining Lecture 16 - Practical Machining Operations: Milling And Drilling
Link NOC:Mechanics of Machining Lecture 17 - Grinding of Metals and Mechanics of Grinding Process
Link NOC:Mechanics of Machining Lecture 18 - Abrasive Machining and Finishing Operations
Link NOC:Mechanics of Machining Lecture 19 - CNC Machines and CNC Programming
Link NOC:Mechanics of Machining Lecture 20 - Introduction to Advanced Machining Processes
Link NOC:Principle of Hydraulic Machines and System Design Lecture 1 - Introduction to hydraulic machines: classifications and operational principles
Link NOC:Principle of Hydraulic Machines and System Design Lecture 2 - Euler equation for turbomachines: net head developed by the pump/turbines
Link NOC:Principle of Hydraulic Machines and System Design Lecture 3 - Velocity triangles of pumps, effect of inlet swirl on pump operation
Link NOC:Principle of Hydraulic Machines and System Design Lecture 4 - Velocity triangles of pumps, effect of inlet swirl on pump operation
Link NOC:Principle of Hydraulic Machines and System Design Lecture 5 - Pump casings, Efficiencies and Problems - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 6 - Pump casings, Efficiencies and Problems - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 7 - Pump casings, Efficiencies and Problems - III
Link NOC:Principle of Hydraulic Machines and System Design Lecture 8 - Axial flow pump, HQ curve, System Resistance Curve - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 9 - Axial flow pump, HQ curve, System Resistance Curve - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 10 - HQ Curve, System Resistance Curve - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 11 - HQ Curve, System Resistance Curve - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 12 - Introduction to Cavitation
Link NOC:Principle of Hydraulic Machines and System Design Lecture 13 - Condition for Cavitation and NPSH
Link NOC:Principle of Hydraulic Machines and System Design Lecture 14 - Net Positive Suction Head (NPSH)
Link NOC:Principle of Hydraulic Machines and System Design Lecture 15 - Suction number and Introduction to off design condition
Link NOC:Principle of Hydraulic Machines and System Design Lecture 16 - Cavitation: The effect of off-design Conditions
Link NOC:Principle of Hydraulic Machines and System Design Lecture 17 - Cavitation: Preventive Measures
Link NOC:Principle of Hydraulic Machines and System Design Lecture 18 - Cavitation: Preventive Measures, Effect on Pump Characteristic
Link NOC:Principle of Hydraulic Machines and System Design Lecture 19 - Problems on Cavitation
Link NOC:Principle of Hydraulic Machines and System Design Lecture 20 - Introduction to Slip : Stodola Slip Model
Link NOC:Principle of Hydraulic Machines and System Design Lecture 21 - Departure from Euler theory
Link NOC:Principle of Hydraulic Machines and System Design Lecture 22 - Slip Velocity - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 23 - Slip Velocity - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 24 - Problem on slip
Link NOC:Principle of Hydraulic Machines and System Design Lecture 25 - Degree of reaction of pump
Link NOC:Principle of Hydraulic Machines and System Design Lecture 26 - Degree of reaction and axial pump design
Link NOC:Principle of Hydraulic Machines and System Design Lecture 27 - Testing of radial flow pump - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 28 - Testing of radial flow pump - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 29 - Problem on radial flow pump testing
Link NOC:Principle of Hydraulic Machines and System Design Lecture 30 - Radial equilibrium of axial flow pump - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 31 - Radial equilibrium of axial flow pump - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 32 - Pump operation: series and parallel connection
Link NOC:Principle of Hydraulic Machines and System Design Lecture 33 - Series and parallel operation of dissimilar pumps
Link NOC:Principle of Hydraulic Machines and System Design Lecture 34 - Pumping system design
Link NOC:Principle of Hydraulic Machines and System Design Lecture 35 - Design of parellel pumping system
Link NOC:Principle of Hydraulic Machines and System Design Lecture 36 - Numerical problem on pumps - I
Link NOC:Principle of Hydraulic Machines and System Design Lecture 37 - Numerical problem on pumps - II
Link NOC:Principle of Hydraulic Machines and System Design Lecture 38 - Numerical problem on pumps - III
Link NOC:Principle of Hydraulic Machines and System Design Lecture 39 - Working principle and Indicator diagram of PD pump
Link NOC:Principle of Hydraulic Machines and System Design Lecture 40 - Working principle and Indicator diagram of PD pump (Continued...)
Link NOC:Principle of Hydraulic Machines and System Design Lecture 41 - Modified indicator diagram and Head-Discharge curve
Link NOC:Principle of Hydraulic Machines and System Design Lecture 42 - Analysis and Head-Discharge curve of PD pump
Link NOC:Principle of Hydraulic Machines and System Design Lecture 43 - Analysis and efficiencies of PD pump
Link NOC:Principle of Hydraulic Machines and System Design Lecture 44 - Requirement of air chamber in PD pump
Link NOC:Principle of Hydraulic Machines and System Design Lecture 45 - Numerical problem on PD pump with air chamber
Link NOC:Principle of Hydraulic Machines and System Design Lecture 46 - Similarity and dimensional analysis of hydraulic machines
Link NOC:Principle of Hydraulic Machines and System Design Lecture 47 - Dimensional analysis of hydraulic machines: Buckingham's theorem
Link NOC:Principle of Hydraulic Machines and System Design Lecture 48 - Buckingham's theorem: Specific speed of hydraulic machines
Link NOC:Principle of Hydraulic Machines and System Design Lecture 49 - Turbine Classification and Operational principle of Pelton wheel
Link NOC:Principle of Hydraulic Machines and System Design Lecture 50 - Velocity Tiangles and analysis
Link NOC:Principle of Hydraulic Machines and System Design Lecture 51 - Operational Principle of Reaction turbine
Link NOC:Principle of Hydraulic Machines and System Design Lecture 52 - Degree of Reaction and Introduction to axial flow turbine
Link NOC:Principle of Hydraulic Machines and System Design Lecture 53 - Kaplan Turbine: Operational Principle, Turbine efficiencies
Link NOC:Principle of Hydraulic Machines and System Design Lecture 54 - Draft Tube for Reaction Turbine and Cavitation
Link NOC:Principle of Hydraulic Machines and System Design Lecture 55 - Energy Balance and NPSH
Link NOC:Principle of Hydraulic Machines and System Design Lecture 56 - Thoma Cavitation Factor
Link NOC:Principle of Hydraulic Machines and System Design Lecture 57 - Reaction Turbine: Design aspects and Characteristic Curves
Link NOC:Principle of Hydraulic Machines and System Design Lecture 58 - Problems on Impulse and Reaction Turbines
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 1 - Introduction to Abrasive Machining and Finishing Processes
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 2 - Grinding Process
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 3 - Grinding Fluids and Its Additives
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 4 - Grinding Fluids and its Emissions
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 5 - Sustainable Grinding Process: Biodegradation of Grinding Fluids
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 6 - Sustainable Grinding Process: MQL in Grinding Process
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 7 - Honing Process
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 8 - Lapping Process
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 9 - Super Finishing and Sand Blasting
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 10 - Vibratory Bowl Finishing,Rotary Barrel Finishing or Tumbling
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 11 - Drag Finishing, Ice-bonded Abrasive Finishing, Pitch Polishing, Pad Polishing
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 12 - Introduction to Surface Texture in abrasive Process
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 13 - Representation of Surface Roughness
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 14 - Abrasive Jet Machining (AJM)
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 15 - Abrasive Water Jet Machining (AWJM)
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 16 - Ultrasonic Machining (USM)
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 17 - EDM, Wire-EDM, EDG, EDDG, AW-EDG
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 18 - Elastic Emission Machining
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 19 - PMEDM and ECD and ELID, ECH
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 20 - Abrasive Flow Finishing: Part 1
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 21 - Abrasive Flow Finishing: Part 2
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 22 - Magnetic Field Assisted Abrasive Finishing: MAF, MADe, MFP
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 23 - Magneto Rheological Finishing and BE-MRF
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 24 - Magnetic Field Assisted Abrasive Finishing:CNP,CMMRF,MRAFF,R-MRAFF
Link NOC:Introduction to Abrasive Machining and Finishing Processes Lecture 25 - Summary of the Course
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 1 - Basic of Solid Mechanics
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 2 - Enegry Principles
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 3 - Classification of Plate Theories and Some Basics
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 4 - Tutorial: Transformation of Tensors
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 5 - Governing Equation for Plate - 1
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 6 - Governing Equation for Plate - 2
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 7 - Tutorial: Reduced Stiffness and Plate Stiffness
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 8 - Navier Solution + Levy solution
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 9 - Levy Solution
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 10 - Tutorial: Load Matrices Calculation
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 11 - EKM and buckling of plates
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 12 - 3D Solutions
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 13 - Matlab Coding + ABAQUS
Link NOC:Theory of Rectangular Plates - Part 1 Lecture 14 - Tutorial: Levy Solutions
Link NOC:Principles of Mechanical Measurement Lecture 1 - Introduction to measurement
Link NOC:Principles of Mechanical Measurement Lecture 2 - Generalized measurement system and static characteristics
Link NOC:Principles of Mechanical Measurement Lecture 3 - Uncertainties in measurement
Link NOC:Principles of Mechanical Measurement Lecture 4 - Statistical treatment of random errors
Link NOC:Principles of Mechanical Measurement Lecture 5 - System response to periodic inputs
Link NOC:Principles of Mechanical Measurement Lecture 6 - Zeroth and first order systems
Link NOC:Principles of Mechanical Measurement Lecture 7 - First and second order systems
Link NOC:Principles of Mechanical Measurement Lecture 8 - Basics of digitization and number systems
Link NOC:Principles of Mechanical Measurement Lecture 9 - Binary logic gates and binary codes
Link NOC:Principles of Mechanical Measurement Lecture 10 - Analog-to-digital conversion
Link NOC:Principles of Mechanical Measurement Lecture 11 - Digital-to-analog conversion
Link NOC:Principles of Mechanical Measurement Lecture 12 - Electromagnetic indicators
Link NOC:Principles of Mechanical Measurement Lecture 13 - Electronic amplifiers and filters
Link NOC:Principles of Mechanical Measurement Lecture 14 - Resistive devices
Link NOC:Principles of Mechanical Measurement Lecture 15 - Inductive, capacitive and optical devices
Link NOC:Principles of Mechanical Measurement Lecture 16 - Piezoelectric and nozzle-flapper transducers
Link NOC:Principles of Mechanical Measurement Lecture 17 - Resistive strain gages and associated circuitry
Link NOC:Principles of Mechanical Measurement Lecture 18 - Strain gage rosettes and gage orientation
Link NOC:Principles of Mechanical Measurement Lecture 19 - Elastic and strain gage load cells
Link NOC:Principles of Mechanical Measurement Lecture 20 - Various load cells and dynamometers
Link NOC:Principles of Mechanical Measurement Lecture 21 - Principles of manometry
Link NOC:Principles of Mechanical Measurement Lecture 22 - Piezometer and elastic pressure transducer
Link NOC:Principles of Mechanical Measurement Lecture 23 - Electric pressure transducer and high and low pressure measurement
Link NOC:Principles of Mechanical Measurement Lecture 24 - Bernoulli's equation in obstruction meters
Link NOC:Principles of Mechanical Measurement Lecture 25 - Obstruction meters and volume flowmeters
Link NOC:Principles of Mechanical Measurement Lecture 26 - Mass flowmeters and velocity probes
Link NOC:Principles of Mechanical Measurement Lecture 27 - Expansion-based devices
Link NOC:Principles of Mechanical Measurement Lecture 28 - RTD, Thermistor and Thermocouple
Link NOC:Principles of Mechanical Measurement Lecture 29 - Introduction to pyrometers
Link NOC:Principles of Mechanical Measurement Lecture 30 - Basic seismic transducer
Link NOC:Principles of Mechanical Measurement Lecture 31 - Vibro-, velo- and accelerometer
Link NOC:Principles of Mechanical Measurement Lecture 32 - Introduction to acoustic measurement
Link NOC:Principles of Mechanical Measurement Lecture 33 - Radioactivity and its biological effects
Link NOC:IC Engines and Gas Turbines Lecture 1 - External and Internal combustion engines, Engine components, SI and CI engines
Link NOC:IC Engines and Gas Turbines Lecture 2 - Four-stroke and Two-stroke engines, Comparison between SI and CI engines, and Four-stroke and Two-stroke engines
Link NOC:IC Engines and Gas Turbines Lecture 3 - Classification of IC engines
Link NOC:IC Engines and Gas Turbines Lecture 4 - Engine operating characteristics
Link NOC:IC Engines and Gas Turbines Lecture 5 - Otto, Diesel and Dual cycles
Link NOC:IC Engines and Gas Turbines Lecture 6 - Otto, Diesel and Dual cycles (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 7 - Otto, Diesel and Dual cycles (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 8 - Otto, Diesel and Dual cycles (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 9 - Comparison between the cycles, Actual cycles and their analysis
Link NOC:IC Engines and Gas Turbines Lecture 10 - Carburetor, Mixture requirements
Link NOC:IC Engines and Gas Turbines Lecture 11 - Carburetor, Mixture requirements (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 12 - Idling, cruising and power ranges
Link NOC:IC Engines and Gas Turbines Lecture 13 - Idling, cruising and power ranges (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 14 - Classification, types of nozzles, Ignition system, Battery and Magneto ignition systems
Link NOC:IC Engines and Gas Turbines Lecture 15 - Classification, types of nozzles, Ignition system, Battery and Magneto ignition systems (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 16 - Classification, types of nozzles, Ignition system, Battery and Magneto ignition systems (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 17 - Engine friction, Lubrication systems, forces on piston
Link NOC:IC Engines and Gas Turbines Lecture 18 - Lubricating oils, Thermochemistry and Fuels, Self-ignition
Link NOC:IC Engines and Gas Turbines Lecture 19 - Octane and Cetane Numbers, Alternative Fuels - Methanol, Ethanol, hydrogen, Natural Gas
Link NOC:IC Engines and Gas Turbines Lecture 20 - Octane and Cetane Numbers, Alternative Fuels - Methanol, Ethanol, hydrogen, Natural Gas (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 21 - Combustion in SI and CI Engines, Pressure Crank Angle Diagram
Link NOC:IC Engines and Gas Turbines Lecture 22 - Combustion in SI and CI Engines, Pressure Crank Angle Diagram (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 23 - Combustion in SI and CI Engines, Pressure Crank Angle Diagram (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 24 - SI engine injection system, Energy distribution, Engine temperatures, Heat transfer in combustion chambers
Link NOC:IC Engines and Gas Turbines Lecture 25 - SI engine injection system, Energy distribution, Engine temperatures, Heat transfer in combustion chambers (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 26 - CI engine injection systems, Air-cooled and liquid-cooled engines, Modern trends
Link NOC:IC Engines and Gas Turbines Lecture 27 - CI engine injection systems, Air-cooled and liquid-cooled engines, Modern trends (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 28 - CI engine injection systems, Air-cooled and liquid-cooled engines, Modern trends (Continued...)
Link NOC:IC Engines and Gas Turbines Lecture 29 - Problems on IC engine
Link NOC:IC Engines and Gas Turbines Lecture 30 - Turbomachines, Gas Turbine theory
Link NOC:IC Engines and Gas Turbines Lecture 31 - Open Cycle Gas Turbine Power Plant, Twin Shaft Arrangement
Link NOC:IC Engines and Gas Turbines Lecture 32 - Closed Cycle, Multi-Spool Arrangement, Steam Power Plant
Link NOC:IC Engines and Gas Turbines Lecture 33 - Basic Thermodynamics
Link NOC:IC Engines and Gas Turbines Lecture 34 - Brayton Cycle: Introducton and General Relationships
Link NOC:IC Engines and Gas Turbines Lecture 35 - Brayton Cycle: Efficiency, Work Ratio and Optimum Work Output Condition
Link NOC:IC Engines and Gas Turbines Lecture 36 - Brayton Cycle with Heat Exchanger/Reheater
Link NOC:IC Engines and Gas Turbines Lecture 37 - Brayton Cycle with Intercooler
Link NOC:IC Engines and Gas Turbines Lecture 38 - Real Brayton Cycle, Solved Example for Ideal Cycle
Link NOC:IC Engines and Gas Turbines Lecture 39 - Solved Examples for Real Brayton Cycle
Link NOC:IC Engines and Gas Turbines Lecture 40 - Introduction and Performance Parameters of Propulsion System
Link NOC:IC Engines and Gas Turbines Lecture 41 - Basics of Various Aircraft Engine
Link NOC:IC Engines and Gas Turbines Lecture 42 - Eular Turbomachinary Equation
Link NOC:IC Engines and Gas Turbines Lecture 43 - Introduction and Flow Analysis of Centrifugal Compressors
Link NOC:IC Engines and Gas Turbines Lecture 44 - Thermodynamics Analysis of Centrifugal Compressors
Link NOC:IC Engines and Gas Turbines Lecture 45 - Axial Compressor: Basics, Velocity triangles, T-S diagram and Work Intraction
Link NOC:IC Engines and Gas Turbines Lecture 46 - Axial Compressor: Different factors, Degree of Reaction and Free Vortex Condition
Link NOC:IC Engines and Gas Turbines Lecture 47 - Complete Analysis of Axial Flow Gas Turbine
Link NOC:IC Engines and Gas Turbines Lecture 48 - Solved Examples for Axial Compressors,Centrifugal Compressors and Turbine
Link NOC:IC Engines and Gas Turbines Lecture 49 - Radial Flow Turbine, Solved Example of Free vortex Condition
Link NOC:IC Engines and Gas Turbines Lecture 50 - Nozzles and Diffuers: Introduction, Intake efficiency,Nozzle efficiency
Link NOC:Fundamental of Welding Science and Technology Lecture 1 - Introduction of welding
Link NOC:Fundamental of Welding Science and Technology Lecture 2 - Classification of welding and joints
Link NOC:Fundamental of Welding Science and Technology Lecture 3 - Parts of weld joint
Link NOC:Fundamental of Welding Science and Technology Lecture 4 - Welding Symbol
Link NOC:Fundamental of Welding Science and Technology Lecture 5 - welding power source - 1
Link NOC:Fundamental of Welding Science and Technology Lecture 6 - Welding power source - 2
Link NOC:Fundamental of Welding Science and Technology Lecture 7 - Welding Power sources characteristics - 1
Link NOC:Fundamental of Welding Science and Technology Lecture 8 - Welding Power sources characteristics - 2
Link NOC:Fundamental of Welding Science and Technology Lecture 9 - Physics of welding - 1
Link NOC:Fundamental of Welding Science and Technology Lecture 10 - Physics of welding - 2
Link NOC:Fundamental of Welding Science and Technology Lecture 11 - Physics of welding - 4 (Arc Stability and Arc Blow)
Link NOC:Fundamental of Welding Science and Technology Lecture 12 - Physics of welding - 3
Link NOC:Fundamental of Welding Science and Technology Lecture 13 - Physics of welding - 5 (Metal Transfer-1)
Link NOC:Fundamental of Welding Science and Technology Lecture 14 - Physics of welding - 6 (Metal Transfer-2)
Link NOC:Fundamental of Welding Science and Technology Lecture 15 - Physics of welding - 7 (Metal Transfer-3)
Link NOC:Fundamental of Welding Science and Technology Lecture 16 - Physics of welding - 8 (Metal Transfer-4)
Link NOC:Fundamental of Welding Science and Technology Lecture 17 - Physics of welding - 9 (Metal Transfer-5)
Link NOC:Fundamental of Welding Science and Technology Lecture 18 - Physics of welding - 10 (Metalting Efficiency)
Link NOC:Fundamental of Welding Science and Technology Lecture 19 - Oxy-Fuel Gas Welding
Link NOC:Fundamental of Welding Science and Technology Lecture 20 - Shielded Metal Arc Welding
Link NOC:Fundamental of Welding Science and Technology Lecture 21 - Gas Tungsten Arc Welding
Link NOC:Fundamental of Welding Science and Technology Lecture 22 - Gas Metal Arc Welding
Link NOC:Fundamental of Welding Science and Technology Lecture 23 - Submerged Arc Welding
Link NOC:Fundamental of Welding Science and Technology Lecture 24 - Welding Defects and Inspection
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 1 - Introduction to Polymer Assisted Abrasive Finishing Processes
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 2 - Surface Integrity and Surface roughness representation - Part I
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 3 - Surface Integrity and Surface roughness representation - Part II
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 4 - Introduction to Grinding and Polymer assisted Grinding Wheels
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 5 - Polymer medium for vibratory bowl finishing, Tumbling, Drag finishing
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 6 - Polymer Pad and Chemo-mechanical Polishing
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 7 - Elastic Emission Machining
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 8 - Hydrodynamic Polishing, Elasto Abrasive Finishing
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 9 - Abrasive Flow Machining and Finishing - Part I
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 10 - Abrasive Flow Machining and Finishing - Part II
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 11 - Advances in Abrasive Flow Finishing: DBGAFF, CFAAFM
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 12 - Advances in Abrasive Flow Finishing: Spiral Polishing, R-AFF
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 13 - AFF Processes: Magnetio AFF (MRAFF), UAA-AFF, EC-AFF
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 14 - Finishing of Biomedical implants (Micro AFF: Micro holes, Micro slots, Bio Implants: Knee implants , Hip implants and Applications of one way, two way and orbital AFF)
Link NOC:Polymer Assisted Abrasive Finishing Processes Lecture 15 - Summary of the Course
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 1 - Materials and manufacturing Processes - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 2 - Materials and manufacturing Processes - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 3 - Physics based modeling approach at different scale
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 4 - Evaluation of properties and process modelling
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 5 - Thermofluid and electromagnetic analysis
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 6 - Solid-state deformation and residual stress - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 7 - Solid-state deformation and residual stress - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 8 - Meltiing, solidification and additive manufacturing
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 9 - Force and velocity diagram - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 10 - Force and velocity diagram - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 11 - Heat transfer analysis
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 12 - Principal and mechanism at different processes - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 13 - Principal and mechanism at different processes - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 14 - Mechanics of bulk metal forming
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 15 - Mechanics of sheet metal forming - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 16 - Mechanics of sheet metal forming - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 17 - Heat transfer and thermomechanical processing
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 18 - Fusion welding processes - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 19 - Fusion welding processes - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 20 - Physics of welding and metal transfer
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 21 - Heat source model in fusion welding
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 22 - Heat transfer and material flow
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 23 - Solidification in welding - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 24 - Solidification in welding - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 25 - Solid state welding - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 26 - Solid state welding - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 27 - Hybrid welding, residual stress and distortion
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 28 - Cooling and solidification at different casting processes
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 29 - Powder metallurgy
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 30 - Principle of surface and coating technologies
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 31 - Principle and development of additive manufacturing technologies - 1
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 32 - Principle and development of additive manufacturing technologies - 2
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 33 - Fundamentals of heat treatment
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 34 - Evaluation of microstructural properties and residual stress
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 35 - Down-scaling of conventional manufacturing processes and Micro-to-nano manufacturing
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 36 - Packaging, micro-finishing and micro-manufacturing processes
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 37 - Processing and shaping of non-metals and bio-materials
Link NOC:Mathematical Modeling of Manufacturing Processes Lecture 38 - Principle of glass and ceramics processing and their shaping
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 1 - Introduction and Notation
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 2 - Flow Regimes and Flow Regime Maps
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 3 - The Homogeneous Model
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 4 - The Separated Flow Model
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 5 - The Separated Flow Model (Continued...)
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 6 - The Drift Flux Model
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 7 - Estimation of pressure drop in two phase flow
Link NOC:Two-Phase flow with phase change in Conventional and Miniature Channels Lecture 8 - Two phase flow and pressure drop in miniature channels
Link NOC:Applied Thermodynamics for Engineers Lecture 1 - Overview of thermodynamic system and state
Link NOC:Applied Thermodynamics for Engineers Lecture 2 - First and second laws of thermodynamics
Link NOC:Applied Thermodynamics for Engineers Lecture 3 - Concept of entropy and entropy generation
Link NOC:Applied Thermodynamics for Engineers Lecture 4 - Concept of exergy and exergy destruction
Link NOC:Applied Thermodynamics for Engineers Lecture 5 - Thermodynamic potentials and Maxwell relations
Link NOC:Applied Thermodynamics for Engineers Lecture 6 - Generalized relations for entropy and specific heats
Link NOC:Applied Thermodynamics for Engineers Lecture 7 - Joule-Thomson coefficient and Clapeyron equation
Link NOC:Applied Thermodynamics for Engineers Lecture 8 - Liquid-vapor phase-change process
Link NOC:Applied Thermodynamics for Engineers Lecture 9 - Use of property tables
Link NOC:Applied Thermodynamics for Engineers Lecture 10 - Equations-of-state and Compressibility factor
Link NOC:Applied Thermodynamics for Engineers Lecture 11 - Ideal cycles for reciprocating engines
Link NOC:Applied Thermodynamics for Engineers Lecture 12 - Otto, Diesel and Dual combustion cycles
Link NOC:Applied Thermodynamics for Engineers Lecture 13 - Stirling and Ericsson cycles
Link NOC:Applied Thermodynamics for Engineers Lecture 14 - Fuel-air cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 15 - Numerical exercise on Fuel-air cycles
Link NOC:Applied Thermodynamics for Engineers Lecture 16 - Losses in actual cycle and valve-timing diagram
Link NOC:Applied Thermodynamics for Engineers Lecture 17 - Ideal Brayton cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 18 - Intercooling and reheating in Brayton cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 19 - Regeneration in Brayton cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 20 - Ideal Rankine cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 21 - Improvements and modifications in Rankine cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 22 - Regenerative Rankine cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 23 - Binary vapor power cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 24 - Combined gas-steam power plant
Link NOC:Applied Thermodynamics for Engineers Lecture 25 - Different arrangments in combined cycles
Link NOC:Applied Thermodynamics for Engineers Lecture 26 - Vapor compression refrigeration cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 27 - SSS cycles and refrigerants
Link NOC:Applied Thermodynamics for Engineers Lecture 28 - Modifications in VCR systems
Link NOC:Applied Thermodynamics for Engineers Lecture 29 - Vapor absorption refrigeration cycle
Link NOC:Applied Thermodynamics for Engineers Lecture 30 - P-v-T behavior of gas mixtures
Link NOC:Applied Thermodynamics for Engineers Lecture 31 - Numerical examples
Link NOC:Applied Thermodynamics for Engineers Lecture 32 - Properties of moist air
Link NOC:Applied Thermodynamics for Engineers Lecture 33 - Psychrometric chart and various psychrometric processes
Link NOC:Applied Thermodynamics for Engineers Lecture 34 - Sensible heat factor and bypass factor
Link NOC:Applied Thermodynamics for Engineers Lecture 35 - Theoretical and actual combustion process
Link NOC:Applied Thermodynamics for Engineers Lecture 36 - Thermodynamic analyses of reacting systems
Link NOC:Fundamentals of Conduction and Radiation Lecture 1 - Relationship of Thermodynamics with Heat transfer
Link NOC:Fundamentals of Conduction and Radiation Lecture 2 - Modes of heat transfer
Link NOC:Fundamentals of Conduction and Radiation Lecture 3 - Fourier's law and thermal conductivity
Link NOC:Fundamentals of Conduction and Radiation Lecture 4 - Generalized heat diffusion equation
Link NOC:Fundamentals of Conduction and Radiation Lecture 5 - Heat diffusion equation in curvilinear coordinates
Link NOC:Fundamentals of Conduction and Radiation Lecture 6 - Concept of thermal resistance
Link NOC:Fundamentals of Conduction and Radiation Lecture 7 - Use of network of resistances in wall and cylinder
Link NOC:Fundamentals of Conduction and Radiation Lecture 8 - Critical thickness of insulation
Link NOC:Fundamentals of Conduction and Radiation Lecture 9 - Conduction with energy generation - I
Link NOC:Fundamentals of Conduction and Radiation Lecture 10 - Conduction with energy generation - II
Link NOC:Fundamentals of Conduction and Radiation Lecture 11 - General Heat Transfer Analysis
Link NOC:Fundamentals of Conduction and Radiation Lecture 12 - Fins with uniform cross-section area - I
Link NOC:Fundamentals of Conduction and Radiation Lecture 13 - Fins with uniform cross-section area - II
Link NOC:Fundamentals of Conduction and Radiation Lecture 14 - Fins with non-uniform cross-section area
Link NOC:Fundamentals of Conduction and Radiation Lecture 15 - Method of Separation of Variables
Link NOC:Fundamentals of Conduction and Radiation Lecture 16 - Graphical approach
Link NOC:Fundamentals of Conduction and Radiation Lecture 17 - Method of Superposition
Link NOC:Fundamentals of Conduction and Radiation Lecture 18 - Lumped capacitance approach - I
Link NOC:Fundamentals of Conduction and Radiation Lecture 19 - Lumped capacitance approach - II
Link NOC:Fundamentals of Conduction and Radiation Lecture 20 - Semi-infinite Solid
Link NOC:Fundamentals of Conduction and Radiation Lecture 21 - Steady Heat Conduction
Link NOC:Fundamentals of Conduction and Radiation Lecture 22 - Unsteady Heat Conduction
Link NOC:Fundamentals of Conduction and Radiation Lecture 23 - Problem solving using Energy Balance Method
Link NOC:Fundamentals of Conduction and Radiation Lecture 24 - Introduction to radiative heat fluxes
Link NOC:Fundamentals of Conduction and Radiation Lecture 25 - Spectral and directional definitions
Link NOC:Fundamentals of Conduction and Radiation Lecture 26 - Blackbody radiation
Link NOC:Fundamentals of Conduction and Radiation Lecture 27 - Emissivity
Link NOC:Fundamentals of Conduction and Radiation Lecture 28 - Irradiation of real surfaces
Link NOC:Fundamentals of Conduction and Radiation Lecture 29 - View factor
Link NOC:Fundamentals of Conduction and Radiation Lecture 30 - Blackbody radiation exchange
Link NOC:Fundamentals of Conduction and Radiation Lecture 31 - Radiation networks
Link NOC:Fundamentals of Conduction and Radiation Lecture 32 - Gas radiation
Link NOC:Fundamentals of Conduction and Radiation Lecture 33 - Radiative Transfer Equation
Link NOC:Steam Power Engineering Lecture 1 - Review of thermodynamics
Link NOC:Steam Power Engineering Lecture 2 - Rankine cycle
Link NOC:Steam Power Engineering Lecture 3 - Performance estimation of steam power cycles
Link NOC:Steam Power Engineering Lecture 4 - Carnot cycle examples
Link NOC:Steam Power Engineering Lecture 5 - Rankine cycle with superheat
Link NOC:Steam Power Engineering Lecture 6 - Rankine cycle with reheat theory and example
Link NOC:Steam Power Engineering Lecture 7 - Examples of Rankine cycle
Link NOC:Steam Power Engineering Lecture 8 - Examples of reheat Rankine cycle
Link NOC:Steam Power Engineering Lecture 9 - Rankine cycle with regeneration
Link NOC:Steam Power Engineering Lecture 10 - Feedwater heaters
Link NOC:Steam Power Engineering Lecture 11 - Cogeneration of power and process heat
Link NOC:Steam Power Engineering Lecture 12 - Examples of regeneration
Link NOC:Steam Power Engineering Lecture 13 - Examples of regenerative Rankine cycle
Link NOC:Steam Power Engineering Lecture 14 - Binary/multi-fluid cycles
Link NOC:Steam Power Engineering Lecture 15 - Low temperature power cycles
Link NOC:Steam Power Engineering Lecture 16 - Examples of binary cycles
Link NOC:Steam Power Engineering Lecture 17 - Types of boilers
Link NOC:Steam Power Engineering Lecture 18 - Boiler accessories
Link NOC:Steam Power Engineering Lecture 19 - Practice examples
Link NOC:Steam Power Engineering Lecture 20 - Stagnation conditions and Nozzle flow
Link NOC:Steam Power Engineering Lecture 21 - Nozzle flow
Link NOC:Steam Power Engineering Lecture 22 - Examples of Nozzle
Link NOC:Steam Power Engineering Lecture 23 - Impulse Turbine - 1
Link NOC:Steam Power Engineering Lecture 24 - Impulse Turbine - 2
Link NOC:Steam Power Engineering Lecture 25 - Examples on Impulse Turbine
Link NOC:Steam Power Engineering Lecture 26 - Reaction Turbine
Link NOC:Steam Power Engineering Lecture 27 - Reheat Factor
Link NOC:Steam Power Engineering Lecture 28 - Examples on Turbine - 1
Link NOC:Steam Power Engineering Lecture 29 - Examples on Turbine - 2
Link NOC:Steam Power Engineering Lecture 30 - Gas Mixture
Link NOC:Steam Power Engineering Lecture 31 - Psychrometry - 1
Link NOC:Steam Power Engineering Lecture 32 - Psychrometry - 2
Link NOC:Steam Power Engineering Lecture 33 - Condensers
Link NOC:Dynamic Behaviour of Materials Lecture 1 - Introduction to Dynamic Behaviour of Materials - I
Link NOC:Dynamic Behaviour of Materials Lecture 2 - Introduction to Dynamic Behaviour of Materials - II
Link NOC:Dynamic Behaviour of Materials Lecture 3 - Introduction to Waves
Link NOC:Dynamic Behaviour of Materials Lecture 4 - Quasi-static vs Dynamic Deformation
Link NOC:Dynamic Behaviour of Materials Lecture 5 - Elastic Wave and its Classification
Link NOC:Dynamic Behaviour of Materials Lecture 6 - Propagation of Elastic Waves in Continuum
Link NOC:Dynamic Behaviour of Materials Lecture 7 - Wave Reflection, Refraction and Interaction
Link NOC:Dynamic Behaviour of Materials Lecture 8 - General Solution of Elastic Wave Equation
Link NOC:Dynamic Behaviour of Materials Lecture 9 - Additional Considerations of Elastic Wave in Cylindrical Bar
Link NOC:Dynamic Behaviour of Materials Lecture 10 - Introduction to Plastic Waves
Link NOC:Dynamic Behaviour of Materials Lecture 11 - Plastic Waves of Uniaxial Stress
Link NOC:Dynamic Behaviour of Materials Lecture 12 - Plastic Waves of Combined Stress
Link NOC:Dynamic Behaviour of Materials Lecture 13 - Taylor's Experiment for Plastic Wave Propagation - 1
Link NOC:Dynamic Behaviour of Materials Lecture 14 - Taylor's Experiment for Plastic Wave Propagation - 2
Link NOC:Dynamic Behaviour of Materials Lecture 15 - Taylor's Experiment: Wilkins-Guinan Analysis
Link NOC:Dynamic Behaviour of Materials Lecture 16 - Introduction to Shock Waves - I
Link NOC:Dynamic Behaviour of Materials Lecture 17 - Introduction to Shock Waves - II
Link NOC:Dynamic Behaviour of Materials Lecture 18 - Shock Wave: Rankine Hugonoit Treatment
Link NOC:Dynamic Behaviour of Materials Lecture 19 - Rankine Hugonoit Treatment and Shock Wave under Impact
Link NOC:Dynamic Behaviour of Materials Lecture 20 - Shock Wave under Impact
Link NOC:Dynamic Behaviour of Materials Lecture 21 - Equations of States (Shock Waves) : Experimental Methods
Link NOC:Dynamic Behaviour of Materials Lecture 22 - Equations of States (Shock Waves) : Theoretical Calculations
Link NOC:Dynamic Behaviour of Materials Lecture 23 - Complex Problems of Shock Waves and Temperature Rise under Shock Wave
Link NOC:Dynamic Behaviour of Materials Lecture 24 - Shock Wave Attenuation, Interaction and Reflection - I
Link NOC:Dynamic Behaviour of Materials Lecture 25 - Shock Wave Attenuation, Interaction and Reflection - II
Link NOC:Dynamic Behaviour of Materials Lecture 26 - Shock Wave Interaction and Reflection
Link NOC:Dynamic Behaviour of Materials Lecture 27 - Fundamentals of Materials Science and Engineering
Link NOC:Dynamic Behaviour of Materials Lecture 28 - Shock Wave Induced Phase Transformations - 1
Link NOC:Dynamic Behaviour of Materials Lecture 29 - Shock Wave Induced Phase Transformations - 2
Link NOC:Dynamic Behaviour of Materials Lecture 30 - Shock Wave Induced Phase Transformations - 3
Link NOC:Dynamic Behaviour of Materials Lecture 31 - Shock Wave Induced Phase Transformations - 4
Link NOC:Dynamic Behaviour of Materials Lecture 32 - Experimental Techniques for Dynamic Deformation - 1
Link NOC:Dynamic Behaviour of Materials Lecture 33 - Experimental Techniques for Dynamic Deformation - 2
Link NOC:Dynamic Behaviour of Materials Lecture 34 - Plastic Deformation at High Strain Rates - 1
Link NOC:Dynamic Behaviour of Materials Lecture 35 - Plastic Deformation at High Strain Rates - 2
Link NOC:Dynamic Behaviour of Materials Lecture 36 - Plastic Deformation at High Strain Rates - 3
Link NOC:Dynamic Behaviour of Materials Lecture 37 - Plastic Deformation at High Strain Rates - 4
Link NOC:Dynamic Behaviour of Materials Lecture 38 - Plastic Deformation at High Strain Rates - 5
Link NOC:Dynamic Behaviour of Materials Lecture 39 - Plastic Deformation Under Shock Waves - 1
Link NOC:Dynamic Behaviour of Materials Lecture 40 - Plastic Deformation Under Shock Waves - 2
Link NOC:Dynamic Behaviour of Materials Lecture 41 - Plastic Deformation Under Shock Waves - 3
Link NOC:Dynamic Behaviour of Materials Lecture 42 - Shear Band - 1
Link NOC:Dynamic Behaviour of Materials Lecture 43 - Shear Band - 2
Link NOC:Dynamic Behaviour of Materials Lecture 44 - Dynamic Fracture - 1
Link NOC:Dynamic Behaviour of Materials Lecture 45 - Dynamic Fracture - 2
Link NOC:Plastic Working of Metallic Materials Lecture 1 - Introduction to Plastic Working of Metals
Link NOC:Plastic Working of Metallic Materials Lecture 2 - Uniaxial Tension Test Analysis
Link NOC:Plastic Working of Metallic Materials Lecture 3 - Temperature effects in metal forming
Link NOC:Plastic Working of Metallic Materials Lecture 4 - Friction and Lubrication
Link NOC:Plastic Working of Metallic Materials Lecture 5 - Friction and Lubrication (Continued...)
Link NOC:Plastic Working of Metallic Materials Lecture 6 - Deformation zone + worked examples
Link NOC:Plastic Working of Metallic Materials Lecture 7 - Stresses at point and Theory of Plasticity
Link NOC:Plastic Working of Metallic Materials Lecture 8 - Slab Analysis
Link NOC:Plastic Working of Metallic Materials Lecture 9 - Slip Line Field Theory - Part 1
Link NOC:Plastic Working of Metallic Materials Lecture 10 - Slip Line Field Theory - Part 2
Link NOC:Plastic Working of Metallic Materials Lecture 11 - Upper Bound Theorem
Link NOC:Plastic Working of Metallic Materials Lecture 12 - Plasticity equations
Link NOC:Plastic Working of Metallic Materials Lecture 13 - Forging
Link NOC:Plastic Working of Metallic Materials Lecture 14 - Analysis of Forging
Link NOC:Plastic Working of Metallic Materials Lecture 15 - Analysis of Forging (Continued...)
Link NOC:Plastic Working of Metallic Materials Lecture 16 - Forging Die Design consideration
Link NOC:Plastic Working of Metallic Materials Lecture 17 - Forging Load
Link NOC:Plastic Working of Metallic Materials Lecture 18 - Rolling of Metals
Link NOC:Plastic Working of Metallic Materials Lecture 19 - Analysis of Rolling
Link NOC:Plastic Working of Metallic Materials Lecture 20 - Analysis of Rolling (Continued...)
Link NOC:Plastic Working of Metallic Materials Lecture 21 - Strain rate in the deformation zone
Link NOC:Plastic Working of Metallic Materials Lecture 22 - Rolling mills
Link NOC:Plastic Working of Metallic Materials Lecture 23 - Prblem on rolling
Link NOC:Plastic Working of Metallic Materials Lecture 24 - Drawing of Rods, Wires and Tubes
Link NOC:Plastic Working of Metallic Materials Lecture 25 - Drawing of Rods, Wires and Tubes (Continued...)
Link NOC:Plastic Working of Metallic Materials Lecture 26 - Analysis of Wire Drawing
Link NOC:Plastic Working of Metallic Materials Lecture 27 - Wire Drawing: Tutorial Problems
Link NOC:Plastic Working of Metallic Materials Lecture 28 - Extrusion Process
Link NOC:Plastic Working of Metallic Materials Lecture 29 - Analysis of Extrusion
Link NOC:Plastic Working of Metallic Materials Lecture 30 - Introduction
Link NOC:Plastic Working of Metallic Materials Lecture 31 - Sheet deformation process
Link NOC:Plastic Working of Metallic Materials Lecture 32 - Deformation of sheet in plane stress
Link NOC:Plastic Working of Metallic Materials Lecture 33 - Analysis of stamping
Link NOC:Plastic Working of Metallic Materials Lecture 34 - Instability in sheet metal forming
Link NOC:Plastic Working of Metallic Materials Lecture 35 - Deep drawing
Link NOC:Plastic Working of Metallic Materials Lecture 36 - Hydroforming
Link NOC:Fundamentals of Artificial Intelligence Lecture 1 - Introduction to Artificial Intelligence
Link NOC:Fundamentals of Artificial Intelligence Lecture 2 - Problem Solving as State Space Search
Link NOC:Fundamentals of Artificial Intelligence Lecture 3 - Uninformed Search
Link NOC:Fundamentals of Artificial Intelligence Lecture 4 - Heuristic Search
Link NOC:Fundamentals of Artificial Intelligence Lecture 5 - Informed Search
Link NOC:Fundamentals of Artificial Intelligence Lecture 6 - Constraint Satisfaction Problems
Link NOC:Fundamentals of Artificial Intelligence Lecture 7 - Searching AND/OR Graphs
Link NOC:Fundamentals of Artificial Intelligence Lecture 8 - Game Playing
Link NOC:Fundamentals of Artificial Intelligence Lecture 9 - Minimax + Alpha-Beta
Link NOC:Fundamentals of Artificial Intelligence Lecture 10 - Introduction to Knowledge Representation
Link NOC:Fundamentals of Artificial Intelligence Lecture 11 - Propositional Logic
Link NOC:Fundamentals of Artificial Intelligence Lecture 12 - First Order Logic - I
Link NOC:Fundamentals of Artificial Intelligence Lecture 13 - First Order Logic - II
Link NOC:Fundamentals of Artificial Intelligence Lecture 14 - Inference in First Order Logic - I
Link NOC:Fundamentals of Artificial Intelligence Lecture 15 - Inference in First Order Logic - II
Link NOC:Fundamentals of Artificial Intelligence Lecture 16 - Answer Extraction
Link NOC:Fundamentals of Artificial Intelligence Lecture 17 - Procedural Control of Reasoning
Link NOC:Fundamentals of Artificial Intelligence Lecture 18 - Reasoning under Uncertainty
Link NOC:Fundamentals of Artificial Intelligence Lecture 19 - Bayesian Network
Link NOC:Fundamentals of Artificial Intelligence Lecture 20 - Decision Network
Link NOC:Fundamentals of Artificial Intelligence Lecture 21 - Introduction to Planning
Link NOC:Fundamentals of Artificial Intelligence Lecture 22 - Plan Space Planning
Link NOC:Fundamentals of Artificial Intelligence Lecture 23 - Planning Graph and GraphPlan
Link NOC:Fundamentals of Artificial Intelligence Lecture 24 - Practical Planning and Acting
Link NOC:Fundamentals of Artificial Intelligence Lecture 25 - Sequential Decision Problems
Link NOC:Fundamentals of Artificial Intelligence Lecture 26 - Making Complex Decisions
Link NOC:Fundamentals of Artificial Intelligence Lecture 27 - Introduction to Machine Learning
Link NOC:Fundamentals of Artificial Intelligence Lecture 28 - Learning Decision Trees
Link NOC:Fundamentals of Artificial Intelligence Lecture 29 - Linear Regression
Link NOC:Fundamentals of Artificial Intelligence Lecture 30 - Support Vector Machines
Link NOC:Fundamentals of Artificial Intelligence Lecture 31 - Unsupervised Learning
Link NOC:Fundamentals of Artificial Intelligence Lecture 32 - Reinforcement Learning
Link NOC:Fundamentals of Artificial Intelligence Lecture 33 - Learning in Neural Networks
Link NOC:Fundamentals of Artificial Intelligence Lecture 34 - Deep Learning: A Brief Overview
Link NOC:Aircraft Propulsion Lecture 1 - Overview of Basic Thermodynamics
Link NOC:Aircraft Propulsion Lecture 2 - Solved Examples for Flow process
Link NOC:Aircraft Propulsion Lecture 3 - Turbomachines: Introduction, Classification, Types
Link NOC:Aircraft Propulsion Lecture 4 - Components of Gas Turbine Power Plant, Gas Turbine Attachments
Link NOC:Aircraft Propulsion Lecture 5 - Introduction to Various Aircraft engines, Engine Performance parameters
Link NOC:Aircraft Propulsion Lecture 6 - Air Standard Ideal Brayton Cycle
Link NOC:Aircraft Propulsion Lecture 7 - Examples for Ideal Brayton Cycle
Link NOC:Aircraft Propulsion Lecture 8 - Non-Ideal Brayton Cycle
Link NOC:Aircraft Propulsion Lecture 9 - Examples for Non-Ideal Brayton Cycle
Link NOC:Aircraft Propulsion Lecture 10 - Brayton Cycle with Heat Exchanger / Re-heater
Link NOC:Aircraft Propulsion Lecture 11 - Brayton Cycle with Intercooler / All Attachments
Link NOC:Aircraft Propulsion Lecture 12 - Examples of Gas Turbine Attachment
Link NOC:Aircraft Propulsion Lecture 13 - Examples of Gas Turbine Attachment
Link NOC:Aircraft Propulsion Lecture 14 - Stagnation Conditions, Real Brayton Cycle with Stagnation Conditions
Link NOC:Aircraft Propulsion Lecture 15 - Polytropic Efficiency of Compressor and Turbine
Link NOC:Aircraft Propulsion Lecture 16 - Examples of Real Cycle
Link NOC:Aircraft Propulsion Lecture 17 - Nozzle Flow: Isentropic Relations, Area Velocity Relation, Choked Mass Flow Rate
Link NOC:Aircraft Propulsion Lecture 18 - Aircraft Engine Intake, Intake Efficiency
Link NOC:Aircraft Propulsion Lecture 19 - Propelling Nozzle, Nozzle Efficiency
Link NOC:Aircraft Propulsion Lecture 20 - Turbojet engine: Confriguration and Examples
Link NOC:Aircraft Propulsion Lecture 21 - Turbofan engine: Confriguration and Examples
Link NOC:Aircraft Propulsion Lecture 22 - Ramjet engine: Parameters and losses
Link NOC:Aircraft Propulsion Lecture 23 - Examples of Ramjet Engine
Link NOC:Aircraft Propulsion Lecture 24 - Thrust Augmentation and Engine performance parameters for Aircrafts
Link NOC:Aircraft Propulsion Lecture 25 - Introduction to Turbomachinary
Link NOC:Aircraft Propulsion Lecture 26 - Centrifugal Compressor: Velocity diagrams, Workdone
Link NOC:Aircraft Propulsion Lecture 27 - Centrifugal Compressor: Thermodynamic analysis, Stage efficiency and Degree of reaction
Link NOC:Aircraft Propulsion Lecture 28 - Examples of Centrifugal compressor
Link NOC:Aircraft Propulsion Lecture 29 - Axial Flow Compressor: Velocity diagrams, Workdone and Degree of Reaction
Link NOC:Aircraft Propulsion Lecture 30 - Axial Flow Compressor: Free vortex Condition
Link NOC:Aircraft Propulsion Lecture 31 - Examples of Axial Flow Compressor - 1
Link NOC:Aircraft Propulsion Lecture 32 - Examples of Axial Flow Compressor - 2
Link NOC:Aircraft Propulsion Lecture 33 - Examples of Axial Flow Compressor - 3
Link NOC:Aircraft Propulsion Lecture 34 - Axial Turbine: Velocity diagrams, Workdone, and Degree of Reaction
Link NOC:Aircraft Propulsion Lecture 35 - Radial Turbine: Velocity diagrams, h-s diagram, Stage effieciency and degree of reaction
Link NOC:Aircraft Propulsion Lecture 36 - Examples of Axial Turbine
Link NOC:Aircraft Propulsion Lecture 37 - Practice examples of Axial Turbine and cetrifugal compressor
Link NOC:Aircraft Propulsion Lecture 38 - Cascade theory and Blade design
Link NOC:Aircraft Propulsion Lecture 39 - Cascade variables and Turbine Cascade
Link NOC:Aircraft Propulsion Lecture 40 - Velocity diagrams of Turbine Cascade, Compressor cascade
Link NOC:Aircraft Propulsion Lecture 41 - Turbine cooling methods
Link NOC:Aircraft Propulsion Lecture 42 - Practice examples of aircraft engine
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 1 - Applications of CFD
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 2 - Basic equations of fluid dynamics and heat transfer
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 3 - Initial and boundary conditions
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 4 - Physical Classification, System of first-order PDEs
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 5 - System of second-order PDEs
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 6 - Finite difference by Taylor series expansion
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 7 - Finite difference by general approximation and polynomials
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 8 - Finite difference in non-uniform grid
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 9 - Types of error and accuracy of FD solutions
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 10 - Finite difference formulations of Elliptic Equations with boundary condition treatment
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 11 - Iterative Methods
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 12 - Applications
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 13 - Linear Solvers
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 14 - Finite difference formulations of Parabolic Equations
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 15 - Finite difference formulations of Parabolic Equations: Implicit Methods
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 16 - Finite difference formulations of Parabolic Equations: Unsteady Two-Dimensional Equation
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 17 - Finite difference formulations of Parabolic Equations: Unsteady Three-Dimensional Equation
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 18 - Finite difference formulations of the first order wave equation: Explicit Method
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 19 - Finite difference formulations of the first order wave equation: Implicit Method
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 20 - Von Neumann stability analysis of different schemes for Parabolic equations
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 21 - Von Neumann stability analysis of different schemes for Parabolic equations
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 22 - Von Neumann stability analysis of different schemes for Hyperbolic equations
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 23 - Modified equation, Artificial viscosity, Numerical diffusion
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 24 - Discretization vorticity-stream function equations using FDM
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 25 - Boundary conditions for flow problems
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 26 - Solutions of vorticity-stream function equations
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 27 - Solution of Navier-Stokes Equation using FDM
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 28 - Solution of Navier-Stokes Equation using FDM (Continued...)
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 29 - Introduction to finite volume method
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 30 - Finite volume discretization of steady diffusion equation
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 31 - Finite volume discretization of unsteady diffusion equation
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 32 - Finite volume discretization of steady convection-diffusion equation
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 33 - Finite volume discretization of unsteady convection-diffusion equation
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 34 - Convection Schemes
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 35 - Solution of Navier-Stokes Equations using FVM - I
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 36 - Solution of Navier-Stokes Equations using FVM - II
Link NOC:Computational Fluid Dynamics for Incompressible Flows Lecture 37 - Boundary Conditions
Link NOC:Experimental Methods in Fluid Mechanics Lecture 1 - Basic concepts, Calibration
Link NOC:Experimental Methods in Fluid Mechanics Lecture 2 - Dimensions, Units, Standards, Systems of dimensions, System of units, Unit conversion table
Link NOC:Experimental Methods in Fluid Mechanics Lecture 3 - Basic concept of dynamic measurements
Link NOC:Experimental Methods in Fluid Mechanics Lecture 4 - Basic concept of dynamic measurements (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 5 - Basic concept of dynamic measurements (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 6 - System response and distortion, Impedence matching
Link NOC:Experimental Methods in Fluid Mechanics Lecture 7 - Dimensional measurement Gauge blocks, The pneumatic displacement gauge
Link NOC:Experimental Methods in Fluid Mechanics Lecture 8 - Dimensional measurement Gauge blocks, The pneumatic displacement gauge
Link NOC:Experimental Methods in Fluid Mechanics Lecture 9 - Pressure Measurements: Definition of pressure and Dynamic response considerations
Link NOC:Experimental Methods in Fluid Mechanics Lecture 10 - Mechanical pressure measurement devices, U-tube manometer, The inclined well type manometer
Link NOC:Experimental Methods in Fluid Mechanics Lecture 11 - The aneroid barometer, Diaphragm and Bellows Gauges
Link NOC:Experimental Methods in Fluid Mechanics Lecture 12 - The Mcleod gauge, The Pirani gauge, The Ionization gauge
Link NOC:Experimental Methods in Fluid Mechanics Lecture 13 - The Mcleod gauge, The Pirani gauge, The Ionization gauge (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 14 - The Mcleod gauge, The Pirani gauge, The Ionization gauge (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 15 - Pressure measurement using 3 holes/probes
Link NOC:Experimental Methods in Fluid Mechanics Lecture 16 - Pressure measurement using 3 holes/probes (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 17 - Flow obstruction flow rate measuerement(venturimeter/orificemeter), the Rotameter
Link NOC:Experimental Methods in Fluid Mechanics Lecture 18 - Flow obstruction flow rate measuerement(venturimeter/orificemeter), the Rotameter (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 19 - Thermal Anemometry(hot wire/hot film), Hot wire anemometer
Link NOC:Experimental Methods in Fluid Mechanics Lecture 20 - Thermal Anemometry(hot wire/hot film), Hot wire anemometer (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 21 - Laser Doppler anemometry
Link NOC:Experimental Methods in Fluid Mechanics Lecture 22 - Measurement of velocity components by 3 holes and 4 holes probes
Link NOC:Experimental Methods in Fluid Mechanics Lecture 23 - Ideal gas thermometer, Temperature measurement by mechanical and electrical effects
Link NOC:Experimental Methods in Fluid Mechanics Lecture 24 - Ideal gas thermometer, Temperature measurement by mechanical and electrical effects (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 25 - Thermostatic temperature, Resistance Temperature Detectors (RTD), Thermistors, Thermocouples
Link NOC:Experimental Methods in Fluid Mechanics Lecture 26 - Temperature measurement by Radiation, The optical pyrometer
Link NOC:Experimental Methods in Fluid Mechanics Lecture 27 - Transient response of thermal system, Thermocouple compensation, high speed flow
Link NOC:Experimental Methods in Fluid Mechanics Lecture 28 - Transient response of thermal system, Thermocouple compensation, high speed flow (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 29 - Transient response of thermal system, Thermocouple compensation, high speed flow (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 30 - Constant temperature hot-wire anemometer, LDA
Link NOC:Experimental Methods in Fluid Mechanics Lecture 31 - Use of PIV
Link NOC:Experimental Methods in Fluid Mechanics Lecture 32 - Use of PIV (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 33 - Use of PIV (Continued...)
Link NOC:Experimental Methods in Fluid Mechanics Lecture 34 - Measurement of pitch angle
Link NOC:Experimental Methods in Fluid Mechanics Lecture 35 - Measurement of torque by dynamometers, straingauge, transducers
Link NOC:Experimental Methods in Fluid Mechanics Lecture 36 - Measurement of microscale flow features - I
Link NOC:Experimental Methods in Fluid Mechanics Lecture 37 - Measurement of microscale flow features - II
Link NOC:Experimental Methods in Fluid Mechanics Lecture 38 - Transient and Frequency response consideration
Link NOC:Experimental Methods in Fluid Mechanics Lecture 39 - Examples
Link NOC:Experimental Methods in Fluid Mechanics Lecture 40 - Analysis of experimental data, causes and types of experimental errors
Link NOC:Experimental Methods in Fluid Mechanics Lecture 41 - Rejection of data: Chauvenets Criterion with example
Link NOC:Experimental Methods in Fluid Mechanics Lecture 42 - Error propagation: function of two variables, several variables
Link NOC:Experimental Methods in Fluid Mechanics Lecture 43 - The Method of Least square with example
Link NOC:Automation in Manufacturing Lecture 1 - Basic concepts
Link NOC:Automation in Manufacturing Lecture 2 - Mechatronics
Link NOC:Automation in Manufacturing Lecture 3 - Mechatronics based systems
Link NOC:Automation in Manufacturing Lecture 4 - Automated systems and equipment used in manufacturing - Part I
Link NOC:Automation in Manufacturing Lecture 5 - Automated systems and equipment used in manufacturing - Part II
Link NOC:Automation in Manufacturing Lecture 6 - Selection of electrical and electronics components for mechatronics based systems
Link NOC:Automation in Manufacturing Lecture 7 - Terms related to performance of electro-mechanical systems
Link NOC:Automation in Manufacturing Lecture 8 - Computer aided design of components
Link NOC:Automation in Manufacturing Lecture 9 - Fabrication Processes
Link NOC:Automation in Manufacturing Lecture 10 - Measurement system and potentiometer sensors
Link NOC:Automation in Manufacturing Lecture 11 - Displacement, position and proximity sensors - I
Link NOC:Automation in Manufacturing Lecture 12 - Displacement, position and proximity sensors - II
Link NOC:Automation in Manufacturing Lecture 13 - Fluid flow, pressure, and temperature measurement
Link NOC:Automation in Manufacturing Lecture 14 - Signal Conditioning: amplification, filtering
Link NOC:Automation in Manufacturing Lecture 15 - Pulse modulation, Protection devices, and Wheatstone bridge
Link NOC:Automation in Manufacturing Lecture 16 - Signal conversion
Link NOC:Automation in Manufacturing Lecture 17 - Microprocessor Technology
Link NOC:Automation in Manufacturing Lecture 18 - Introduction to Microprocessor Programming
Link NOC:Automation in Manufacturing Lecture 19 - Application of electric drives in automation
Link NOC:Automation in Manufacturing Lecture 20 - DC and AC motors
Link NOC:Automation in Manufacturing Lecture 21 - Stepper motor and servo motor
Link NOC:Automation in Manufacturing Lecture 22 - Types of industrial automation and mechanisms
Link NOC:Automation in Manufacturing Lecture 23 - Ball screw based linear motion drives
Link NOC:Automation in Manufacturing Lecture 24 - Application of cams in automation
Link NOC:Automation in Manufacturing Lecture 25 - Application of indexing mechanisms in automation
Link NOC:Automation in Manufacturing Lecture 26 - Application of tool magazines in automation
Link NOC:Automation in Manufacturing Lecture 27 - Material handling systems
Link NOC:Automation in Manufacturing Lecture 28 - Fundamental concepts
Link NOC:Automation in Manufacturing Lecture 29 - Hydraulic pumps
Link NOC:Automation in Manufacturing Lecture 30 - Direction control valves
Link NOC:Automation in Manufacturing Lecture 31 - Flow control and pressure relief valves
Link NOC:Automation in Manufacturing Lecture 32 - Graphical representation of hydraulic system elements
Link NOC:Automation in Manufacturing Lecture 33 - Basic concepts and air compressors
Link NOC:Automation in Manufacturing Lecture 34 - Air treatment and pressure regulation
Link NOC:Automation in Manufacturing Lecture 35 - Graphical representation and pneumatic circuits
Link NOC:Automation in Manufacturing Lecture 36 - Computer aided manufacturing and process planning
Link NOC:Automation in Manufacturing Lecture 37 - CNC machines and interpolation
Link NOC:Automation in Manufacturing Lecture 38 - CNC Programming
Link NOC:Fundamentals of Compressible Flow Lecture 1 - Review Concepts of Fluid Mechanics and Thermodynamics - I
Link NOC:Fundamentals of Compressible Flow Lecture 2 - Review Concepts of Fluid Mechanics and Thermodynamics - II
Link NOC:Fundamentals of Compressible Flow Lecture 3 - Review Concepts of Fluid Mechanics and Thermodynamics - III
Link NOC:Fundamentals of Compressible Flow Lecture 4 - Wave Propagation in Compressible Medium - I
Link NOC:Fundamentals of Compressible Flow Lecture 5 - Wave Propagation in Compressible Medium - II
Link NOC:Fundamentals of Compressible Flow Lecture 6 - Wave Propagation in Compressible Medium - III
Link NOC:Fundamentals of Compressible Flow Lecture 7 - Quasi-One Dimensional Isentropic Flow - I
Link NOC:Fundamentals of Compressible Flow Lecture 8 - Quasi-One Dimensional Isentropic Flow - II
Link NOC:Fundamentals of Compressible Flow Lecture 9 - Quasi-One Dimensional Isentropic Flow - III
Link NOC:Fundamentals of Compressible Flow Lecture 10 - Normal Shock Waves - I
Link NOC:Fundamentals of Compressible Flow Lecture 11 - Normal Shock Waves - II
Link NOC:Fundamentals of Compressible Flow Lecture 12 - Normal Shock Waves - III
Link NOC:Fundamentals of Compressible Flow Lecture 13 - Normal Shock Waves - IV
Link NOC:Fundamentals of Compressible Flow Lecture 14 - Expansion Waves and Oblique Shocks - I
Link NOC:Fundamentals of Compressible Flow Lecture 15 - Expansion Waves and Oblique Shocks - II
Link NOC:Fundamentals of Compressible Flow Lecture 16 - Expansion Waves and Oblique Shocks - III
Link NOC:Fundamentals of Compressible Flow Lecture 17 - Expansion Waves and Oblique Shocks - IV
Link NOC:Fundamentals of Compressible Flow Lecture 18 - Expansion Waves and Oblique Shocks - V
Link NOC:Fundamentals of Compressible Flow Lecture 19 - Expansion Waves and Oblique Shocks - VI
Link NOC:Fundamentals of Compressible Flow Lecture 20 - Supersonic Nozzles and Diffusers - I
Link NOC:Fundamentals of Compressible Flow Lecture 21 - Supersonic Nozzles and Diffusers - II
Link NOC:Fundamentals of Compressible Flow Lecture 22 - Supersonic Nozzles and Diffusers - III
Link NOC:Fundamentals of Compressible Flow Lecture 23 - Measurement Diagnostics and Experimental Facilitates for Compressible Flow - II
Link NOC:Fundamentals of Compressible Flow Lecture 24 - Compressible Flow with Friction and Heat Transfer - II
Link NOC:Fundamentals of Compressible Flow Lecture 25 - Compressible Flow with Friction and Heat Transfer - III
Link NOC:Fundamentals of Compressible Flow Lecture 26 - Measurement Diagnostics and Experimental Facilities for Compressible Flow - I
Link NOC:Fundamentals of Compressible Flow Lecture 27 - Measurement Diagnostics and Experimental Facilities for Compressible Flow - II
Link NOC:Fundamentals of Compressible Flow Lecture 28 - Measurement Diagnostics and Experimental Facilities for Compressible Flow - III
Link NOC:Fundamentals of Compressible Flow Lecture 29 - Measurement Diagnostics and Experimental Facilities for Compressible Flow - IV
Link NOC:Fundamentals of Compressible Flow Lecture 30 - Measurement Diagnostics and Experimental Facilities for Compressible Flow - V
Link NOC:Fundamentals of Compressible Flow Lecture 31 - Measurement Diagnostics and Experimental Facilities for Compressible Flow - VI
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 1 - Functional, First variation, Euler Lagrange equation; Several Dependent variables
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 2 - Functional with higher order derivatives; Variational statement
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 3 - Differential equation, Variational statement and Minimization problem; Rayleigh-Ritz method
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 4 - FEM steps: Explained with discrete linear springs; Gaussian Quadrature rule for integration
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 5 - Solving one Ordinary Differential Equation using Linear Finite Element
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 6 - Solving one Ordinary Differential Equation using Quadratic Finite Element
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 7 - Bar Element: Elemental equation; Matlab Implementation with Example
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 8 - Bar Element: Postprocessing; Comparison with Analytical Solution; Bar with linear springs
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 9 - Truss Element: Elemental equation; Matlab Implementation with Example
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 10 - Beam Element: Variational statement; Hermite shape function
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 11 - Beam Element: Elemental equation; Matlab implementation with Example
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 12 - Beam Element: Matlab implementation for the example with Non-uniform distributed load
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 13 - Frame Element: Derivation of elemental equation in global reference frame
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 14 - Frame Element: Matlab implementation with one Example
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 15 - Generalization of Geometry data; Stiffness matrix, Load vector formation at element level
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 16 - Generalization of Assembly, Imposition of Boundary condition and Load information
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 17 - Indicial Notation: Summation convention, Kronecker delta, Permutation symbol
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 18 - Second order tensor; Gradient, Divergence, Curl and Laplacian in Indicial notation
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 19 - Gauss Divergence theorem and its application in Heat transfer and Structural analysis
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 20 - Derivation of weak form of 2D steady-state heat conduction problem
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 21 - Triangular element, calculating element stiffness and element force vector
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 22 - Numerical example, assembly, mapping
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 23 - Numerical integration, Neumann boundary, and higher order shape functions
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 24 - Quadrilateral element, Lagrange shape functions, Serendipity elements
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 25 - Development of a MATLAB code for solving 2D steady-state heat conduction problem
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 26 - Demonstration of the MATLAB code
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 27 - Elasticity problems in two dimension and obtaining the weak form
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 28 - Deriving element stiffness matrix and element force vector, numerical example
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 29 - Development of a MATLAB code for solving planar elasticity problems
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 30 - Superconvergent Patch Recovery, error estimator, adaptive refinement
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 31 - Solving eigenvalue problem in bar and beam, writing FEM code in MATLAB
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 32 - Solving eigenvalue problem of membrane, writing FEM code in MATLAB
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 33 - Solving transient problems (parabolic type)
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 34 - Solving transient problems (hyperbolic type)
Link NOC:Finite Element Method: Variational Methods to Computer Programming Lecture 35 - Solving elasticity problems in 3D using FEM, Solvers
Link NOC:Computational Continuum Mechanics Lecture 1 - Origin of nonlinearities - 1
Link NOC:Computational Continuum Mechanics Lecture 2 - Origin of nonlinearities - 2
Link NOC:Computational Continuum Mechanics Lecture 3 - Tensor and Tensor Algebra - 1
Link NOC:Computational Continuum Mechanics Lecture 4 - Tensor and Tensor Algebra - 2
Link NOC:Computational Continuum Mechanics Lecture 5 - Tensor and Tensor Algebra - 3
Link NOC:Computational Continuum Mechanics Lecture 6 - Tensor and Tensor Algebra - 4
Link NOC:Computational Continuum Mechanics Lecture 7 - Linearization and directional derivative, Tensor analysis - 1
Link NOC:Computational Continuum Mechanics Lecture 8 - Linearization and directional derivative, Tensor analysis - 2
Link NOC:Computational Continuum Mechanics Lecture 9 - Worked Examples - 1
Link NOC:Computational Continuum Mechanics Lecture 10 - Worked Examples - 2
Link NOC:Computational Continuum Mechanics Lecture 11 - Idea of Motion, Material and Spatial Descriptions, Deformation Gradient Tensor
Link NOC:Computational Continuum Mechanics Lecture 12 - Strain, Polar Decomposition - 1
Link NOC:Computational Continuum Mechanics Lecture 13 - Polar Decomposition - 2, Volume and Area Change
Link NOC:Computational Continuum Mechanics Lecture 14 - Worked Examples, Linearized Kinematics
Link NOC:Computational Continuum Mechanics Lecture 15 - Velocity, Acceleration, Material Time Derivative
Link NOC:Computational Continuum Mechanics Lecture 16 - Velocity Gradient, Rate of Deformation tensor, Area and Volume Rate, Reynolds Transport Theorem
Link NOC:Computational Continuum Mechanics Lecture 17 - Solved Examples
Link NOC:Computational Continuum Mechanics Lecture 18 - Conservation of Mass, Balance of Linear Momentum, Cauchy's Stress Principle - 1
Link NOC:Computational Continuum Mechanics Lecture 19 - Cauchy's Stress Principle - 2, Cauchy Stress Tensor
Link NOC:Computational Continuum Mechanics Lecture 20 - Objectivity, Stress Objectivity, Equilibrium Equations - 1
Link NOC:Computational Continuum Mechanics Lecture 21 - Equilibrium Equations - 2, Principle of Virtual Work
Link NOC:Computational Continuum Mechanics Lecture 22 - Work Conjugacy, First Piola-Kirchhoff Stress Tensor
Link NOC:Computational Continuum Mechanics Lecture 23 - Second Piola-Kirchhoff Stress Tensor, Decomposition of Stress - 1
Link NOC:Computational Continuum Mechanics Lecture 24 - Decomposition of Stress - 2, Objective Stress Measures
Link NOC:Computational Continuum Mechanics Lecture 25 - Solved Examples
Link NOC:Computational Continuum Mechanics Lecture 26 - Constitutive relations and constraints, Hyperelasticity, Material elasticity tensor
Link NOC:Computational Continuum Mechanics Lecture 27 - Spatial Elasticity Tensor, Solved Example
Link NOC:Computational Continuum Mechanics Lecture 28 - Isotropic hyperelasticity - material and spatial description, Hyperelastic models
Link NOC:Computational Continuum Mechanics Lecture 29 - Isotropic Hyperelasticity, Neo-Hookean Material Model, Solved Examples
Link NOC:Computational Continuum Mechanics Lecture 30 - Introduction, Linearization Process Overview
Link NOC:Computational Continuum Mechanics Lecture 31 - Linearization of Internal Virtual Work and External Virtual Work
Link NOC:Computational Continuum Mechanics Lecture 32 - Discretization of Kinematic Quantities, Equilibrium Equations
Link NOC:Computational Continuum Mechanics Lecture 33 - Discretization of Linearized Equilibrium Equations
Link NOC:Computational Continuum Mechanics Lecture 34 - Newton Raphson Method
Link NOC:Computational Continuum Mechanics Lecture 35 - Line Search Method
Link NOC:Computational Continuum Mechanics Lecture 36 - Arc Length Method, Solved Examples
Link NOC:Computational Continuum Mechanics Lecture 37 - FE Formulation of Ductile Fracture in Dynamic Elasto-Plastic Contact Problem - Introduction
Link NOC:Computational Continuum Mechanics Lecture 38 - FE Formulation of Ductile Fracture in Dynamic Elasto-Plastic Contact Problem - Formulation
Link NOC:Computational Continuum Mechanics Lecture 39 - FE Formulation of Ductile Fracture in Dynamic Elasto-Plastic Contact Problem - FEM
Link NOC:Computational Continuum Mechanics Lecture 40 - FE Formulation of Ductile Fracture in Dynamic Elasto-Plastic Contact Problem - Results
Link NOC:Fundamentals of Convective Heat Transfer Lecture 1 - Application of convective heat transfer
Link NOC:Fundamentals of Convective Heat Transfer Lecture 2 - Foundations of heat transfer
Link NOC:Fundamentals of Convective Heat Transfer Lecture 3 - Derivation of energy equation
Link NOC:Fundamentals of Convective Heat Transfer Lecture 4 - Derivation of boundary layer equation
Link NOC:Fundamentals of Convective Heat Transfer Lecture 5 - Derivation of boundary layer energy equation
Link NOC:Fundamentals of Convective Heat Transfer Lecture 6 - Blasius solution: similarity method
Link NOC:Fundamentals of Convective Heat Transfer Lecture 7 - Pohlhausen solution: similarity method
Link NOC:Fundamentals of Convective Heat Transfer Lecture 8 - Pohlhausen solution: heat transfer parameters
Link NOC:Fundamentals of Convective Heat Transfer Lecture 9 - Falkner-Skan equation: Boundary layer flow over a wedge
Link NOC:Fundamentals of Convective Heat Transfer Lecture 10 - Momentum integral equation for flat plate boundary layer
Link NOC:Fundamentals of Convective Heat Transfer Lecture 11 - Laminar BL flow over flat plate: Uniform surface temperature
Link NOC:Fundamentals of Convective Heat Transfer Lecture 12 - Laminar BL flow over flat plate: Uniform surface heat flux
Link NOC:Fundamentals of Convective Heat Transfer Lecture 13 - Solution of example problems
Link NOC:Fundamentals of Convective Heat Transfer Lecture 14 - Hydrodynamic and thermal regions
Link NOC:Fundamentals of Convective Heat Transfer Lecture 15 - Energy balance in channel flow
Link NOC:Fundamentals of Convective Heat Transfer Lecture 16 - Determination of heat transfer coefficient
Link NOC:Fundamentals of Convective Heat Transfer Lecture 17 - Velocity profile in fully-developed channel flows
Link NOC:Fundamentals of Convective Heat Transfer Lecture 18 - Thermally fully developed laminar slug flow with uniform wall heat flux condition
Link NOC:Fundamentals of Convective Heat Transfer Lecture 19 - Hydrodynamically and thermally fully developed flow with uniform wall heat flux condition
Link NOC:Fundamentals of Convective Heat Transfer Lecture 20 - Fully developed flow through parallel plate channel with uniform wall temperature
Link NOC:Fundamentals of Convective Heat Transfer Lecture 21 - Fully developed flow through circular pipe with uniform wall temperature
Link NOC:Fundamentals of Convective Heat Transfer Lecture 22 - Thermally developing flow through circular pipe with uniform wall heat flux
Link NOC:Fundamentals of Convective Heat Transfer Lecture 23 - Thermally developing flow through circular pipe with uniform wall temperature
Link NOC:Fundamentals of Convective Heat Transfer Lecture 24 - Heat transfer in plane Couette flow
Link NOC:Fundamentals of Convective Heat Transfer Lecture 25 - Solutions of example problems
Link NOC:Fundamentals of Convective Heat Transfer Lecture 26 - Introduction and scale analysis
Link NOC:Fundamentals of Convective Heat Transfer Lecture 27 - Natural convection over a vertical plate: Similarity Solution
Link NOC:Fundamentals of Convective Heat Transfer Lecture 28 - Natural convection over a vertical plate: Similarity solution of energy equation
Link NOC:Fundamentals of Convective Heat Transfer Lecture 29 - Natural convection over a vertical plate: Integral solution
Link NOC:Fundamentals of Convective Heat Transfer Lecture 30 - Natural convection over inclined plate and mixed convection
Link NOC:Fundamentals of Convective Heat Transfer Lecture 31 - Natural convection inside enclosures
Link NOC:Fundamentals of Convective Heat Transfer Lecture 32 - Solution of example problems
Link NOC:Fundamentals of Convective Heat Transfer Lecture 33 - Basics of finite difference method
Link NOC:Fundamentals of Convective Heat Transfer Lecture 34 - Solution of Navier-Stokes equations
Link NOC:Fundamentals of Convective Heat Transfer Lecture 35 - Solution of energy equation
Link NOC:Fundamentals of Convective Heat Transfer Lecture 36 - Derivation of Reynolds Averaged Navier-Stokes Equations
Link NOC:Fundamentals of Convective Heat Transfer Lecture 37 - External Turbulent Flow
Link NOC:Fundamentals of Convective Heat Transfer Lecture 38 - Integral solution for turbulent boundary layer flow over a flat plate
Link NOC:Fundamentals of Convective Heat Transfer Lecture 39 - Convection in turbulent pipe flow
Link NOC:Fundamentals of Convective Heat Transfer Lecture 40 - Boiling regimes and boiling curve
Link NOC:Fundamentals of Convective Heat Transfer Lecture 41 - Laminar film condensation on a vertical plate
Link NOC:Fundamentals of Convective Heat Transfer Lecture 42 - Laminar film condensation on horizontal tube
Link NOC:Fundamentals of Convective Heat Transfer Lecture 43 - Solution of example problems
Link NOC:Theory of Composite Shells Lecture 1 - Introduction to composite materials
Link NOC:Theory of Composite Shells Lecture 2 - Basic terminology in Shell
Link NOC:Theory of Composite Shells Lecture 3 - Derivation of fundamental theorem of surfaces
Link NOC:Theory of Composite Shells Lecture 4 - Derivative of unit vectors and various theorems
Link NOC:Theory of Composite Shells Lecture 5 - Classification of shells
Link NOC:Theory of Composite Shells Lecture 6 - Derivation of strain-displacement relation
Link NOC:Theory of Composite Shells Lecture 7 - Derivation of shell governing equations - 1
Link NOC:Theory of Composite Shells Lecture 8 - Derivation of shell governing equations - 2
Link NOC:Theory of Composite Shells Lecture 9 - Derivation of shell governing equations - 3
Link NOC:Theory of Composite Shells Lecture 10 - Derivation of special cases
Link NOC:Theory of Composite Shells Lecture 11 - Derivation of shell constitutive relations
Link NOC:Theory of Composite Shells Lecture 12 - Solved examples on membrane theory and moment shell theory
Link NOC:Theory of Composite Shells Lecture 13 - Shell of revolution problems
Link NOC:Theory of Composite Shells Lecture 14 - Derivation of Navier solution for infinite shell panel
Link NOC:Theory of Composite Shells Lecture 15 - Basics of MATLAB coding
Link NOC:Theory of Composite Shells Lecture 16 - Derivation of Navier solution for finite shell panel
Link NOC:Theory of Composite Shells Lecture 17 - ABAQUS Modelling
Link NOC:Theory of Composite Shells Lecture 18 - Extended Kanatrovich method for shell panel
Link NOC:Theory of Composite Shells Lecture 19 - Free Vibration solution of shell panels under Navier and Levy supports - 1
Link NOC:Theory of Composite Shells Lecture 20 - Free Vibration solution of shell panels under Navier and Levy supports - 2
Link NOC:Theory of Composite Shells Lecture 21 - Basics of Buckling of shells
Link NOC:Theory of Composite Shells Lecture 22 - Buckling of cylindrical shells
Link NOC:Theory of Composite Shells Lecture 23 - Buckling of Levy-type cylindrical shells
Link NOC:Theory of Composite Shells Lecture 24 - 3D Bending
Link NOC:Theory of Composite Shells Lecture 25 - 3D Free vibration
Link NOC:Theory of Composite Shells Lecture 26 - 3D Buckling
Link NOC:Theory of Composite Shells Lecture 27 - Advanced Material
Link NOC:Theory of Composite Shells Lecture 28 - Free vibration of a composite cylindrical shell
Link NOC:Finite Element Modeling of Welding Processes Lecture 1 - Properties, Modelling approaches, Process modelling and Optimization
Link NOC:Finite Element Modeling of Welding Processes Lecture 2 - Fusion welding - 1
Link NOC:Finite Element Modeling of Welding Processes Lecture 3 - Fusion welding - 2
Link NOC:Finite Element Modeling of Welding Processes Lecture 4 - Soldering, Brazing, Solid-state welding processes
Link NOC:Finite Element Modeling of Welding Processes Lecture 5 - Advanced welding processes
Link NOC:Finite Element Modeling of Welding Processes Lecture 6 - Advances in laser microwelding
Link NOC:Finite Element Modeling of Welding Processes Lecture 7 - Additive manufacturing processes
Link NOC:Finite Element Modeling of Welding Processes Lecture 8 - Elastic stress analysis - I
Link NOC:Finite Element Modeling of Welding Processes Lecture 9 - Elastic stress analysis - II and Potential energy method
Link NOC:Finite Element Modeling of Welding Processes Lecture 10 - Three-Dimensional element
Link NOC:Finite Element Modeling of Welding Processes Lecture 11 - Weighted residual method
Link NOC:Finite Element Modeling of Welding Processes Lecture 12 - Material nonlineaity - I
Link NOC:Finite Element Modeling of Welding Processes Lecture 13 - Material nonlineaity - II
Link NOC:Finite Element Modeling of Welding Processes Lecture 14 - Fluid flow and Natural coordinate system - I
Link NOC:Finite Element Modeling of Welding Processes Lecture 15 - Natural coordinate system in 3D and XFEM
Link NOC:Finite Element Modeling of Welding Processes Lecture 16 - Introduction to heat source model
Link NOC:Finite Element Modeling of Welding Processes Lecture 17 - Heat source models in welding - I
Link NOC:Finite Element Modeling of Welding Processes Lecture 18 - Heat source models in welding - II
Link NOC:Finite Element Modeling of Welding Processes Lecture 19 - Heat source model for Keyhole mode and solid state welding
Link NOC:Finite Element Modeling of Welding Processes Lecture 20 - Implementation of FEM in fusion welding processes
Link NOC:Finite Element Modeling of Welding Processes Lecture 21 - Implementation of FEM for fluid flow in fusion welding processes
Link NOC:Finite Element Modeling of Welding Processes Lecture 22 - FEM modeling of EBW and RSW
Link NOC:Finite Element Modeling of Welding Processes Lecture 23 - FEM modeling of FSW and hybrid FSW
Link NOC:Finite Element Modeling of Welding Processes Lecture 24 - Demonstration of thermal model development using commercial software
Link NOC:Finite Element Modeling of Welding Processes Lecture 25 - Fluid flow modeling in welding processes
Link NOC:Finite Element Modeling of Welding Processes Lecture 26 - Heat transfer and fluid flow analysis in quasi-steady state
Link NOC:Finite Element Modeling of Welding Processes Lecture 27 - Prediction of free surface profile
Link NOC:Finite Element Modeling of Welding Processes Lecture 28 - Principle stress, Hydrostatic and Deviatoric Components of Stress
Link NOC:Finite Element Modeling of Welding Processes Lecture 29 - Yield Function, Von Mises Yield Surface and Hardening rule
Link NOC:Finite Element Modeling of Welding Processes Lecture 30 - Material models, Residual stress and distortion
Link NOC:Finite Element Modeling of Welding Processes Lecture 31 - Phase transformation effect on Residual stress and distortion
Link NOC:Finite Element Modeling of Welding Processes Lecture 32 - Demonstration of thermo-mechanical model development using commercial software
Link NOC:Finite Element Modeling of Welding Processes Lecture 33 - Fundamentals of metal transfer in arc welding
Link NOC:Finite Element Modeling of Welding Processes Lecture 34 - FE-based modelling approaches
Link NOC:Finite Element Modeling of Welding Processes Lecture 35 - Theoretical development of heat transfer model
Link NOC:Finite Element Modeling of Welding Processes Lecture 36 - Heating of nano-film
Link NOC:Finite Element Modeling of Welding Processes Lecture 37 - Theoretical development of stress analysis model
Link NOC:Finite Element Modeling of Welding Processes Lecture 38 - Fundamentals of wire arc additive manufacturing processes - I
Link NOC:Finite Element Modeling of Welding Processes Lecture 39 - Fundamentals of wire arc additive manufacturing processes - II
Link NOC:Finite Element Modeling of Welding Processes Lecture 40 - Modelling approaches of additive manufacturing
Link NOC:Nonlinear Vibration Lecture 1 - Introduction to mechanical systems
Link NOC:Nonlinear Vibration Lecture 2 - Superposition rule, Commonly used nonlinear equations
Link NOC:Nonlinear Vibration Lecture 3 - Equilibrium points: potential function
Link NOC:Nonlinear Vibration Lecture 4 - Force and moment based Approach, Lagrange Principle
Link NOC:Nonlinear Vibration Lecture 5 - Extended Hamilton’s principle
Link NOC:Nonlinear Vibration Lecture 6 - Use of scaling and book-keeping parameter for ordering
Link NOC:Nonlinear Vibration Lecture 7 - Numerical solution, Analytical solutions: Harmonic Balance method
Link NOC:Nonlinear Vibration Lecture 8 - Straight forward expansion
Link NOC:Nonlinear Vibration Lecture 9 - Lindstd-Poincare’ method
Link NOC:Nonlinear Vibration Lecture 10 - Method of Averaging
Link NOC:Nonlinear Vibration Lecture 11 - Method of multiple scales
Link NOC:Nonlinear Vibration Lecture 12 - Method of generalized Harmonic Balance method
Link NOC:Nonlinear Vibration Lecture 13 - Free vibration of undamped and damped SDOF systems with quadratic and cubic nonlinearity
Link NOC:Nonlinear Vibration Lecture 14 - Super and sub harmonic resonance conditions
Link NOC:Nonlinear Vibration Lecture 15 - Bifurcation analysis of fixed-point response
Link NOC:Nonlinear Vibration Lecture 16 - Nonlinear system with hard excitations
Link NOC:Nonlinear Vibration Lecture 17 - Super and sub harmonic resonance conditions
Link NOC:Nonlinear Vibration Lecture 18 - Bifurcation analysis of fixed-point response
Link NOC:Nonlinear Vibration Lecture 19 - Floquet theory, Hill's infinite determinant, Resonance in parametrically excited systems
Link NOC:Nonlinear Vibration Lecture 20 - Parametrically excited pneumatic artificial muscle
Link NOC:Nonlinear Vibration Lecture 21 - Parametric instability of sandwich plate
Link NOC:Nonlinear Vibration Lecture 22 - Analysis of periodic, quasi-periodic and chaotic systems
Link NOC:Nonlinear Vibration Lecture 23 - Stability and bifurcation analysis of periodic and quasi-periodic response
Link NOC:Nonlinear Vibration Lecture 24 - Analysis of chaotic system
Link NOC:Nonlinear Vibration Lecture 25 - Numerical methods for finding roots and solutions of ODE
Link NOC:Nonlinear Vibration Lecture 26 - Time response, phase portraits, frequency response
Link NOC:Nonlinear Vibration Lecture 27 - Poincare section, FFT, Lyapunov exponent
Link NOC:Nonlinear Vibration Lecture 28 - Pasive and active vibration absorber with displacement and acceleration feedback
Link NOC:Nonlinear Vibration Lecture 29 - Active vibration absorber with time delay acceleration feedback by HBM
Link NOC:Nonlinear Vibration Lecture 30 - Application of Active vibration absorber with combination feedback
Link NOC:Nonlinear Vibration Lecture 31 - Cantilever beam with tip mass for principal parametric resonance
Link NOC:Nonlinear Vibration Lecture 32 - Cantilever beam with tip mass for combination resonance
Link NOC:Nonlinear Vibration Lecture 33 - Cantilever beam based piezoelectric based energy harvestor
Link NOC:Nonlinear Vibration Lecture 34 - Nonlinear dynamics of turning operation with delay and internal resonance
Link NOC:Nonlinear Vibration Lecture 35 - Chatter in rolling mills and dynamic analysis of artificial pneumatic muscle
Link NOC:Nonlinear Vibration Lecture 36 - Chaotic systems and control of chaos
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 1 - Introduction to Optimization
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 2 - Introduction to Evolutionary Computation
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 3 - Binary-Coded Genetic Algorithm (BGA)
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 4 - Operators and Simulations of Binary-Coded Genetic Algorithm
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 5 - Real-Coded Genetic Algorithm (RGA)
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 6 - Operators and Simulations of Real-Coded Genetic Algorithm
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 7 - Algorithmic Implementation of BGA and RGA
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 8 - Particle Swarm Optimization (PSO)
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 9 - Simulations and Algorithmic Implementation of Particle Swarm Optimization
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 10 - Differential Evolution (DE)
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 11 - Simulations and Algorithmic Implementation of Differential Evolution
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 12 - Constrained Optimization: Introduction and Optimality
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 13 - Penalty Function Methods for Evolutionary Computing Techniques
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 14 - Evolutionary Computing Techniques: Separation of Objective Function and Constraints
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 15 - Simulations of Constraint Handling Techniques - Part 1
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 16 - Simulations of Constraint Handling Techniques - Part 2
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 17 - Introduction to Multi-Objective Optimization - Part 1
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 18 - Introduction to Multi-Objective Optimization - Part 2
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 19 - Multi-Objective Optimization: Ranking and Diversity
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 20 - Classical Multi-Objective Optimization Methods
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 21 - Non-Dominated Genetic Algorithm: NSGA-II: Introduction
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 22 - Non-Dominated Genetic Algorithm: NSGA-II: Simulations
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 23 - Strength Pareto Evolutionary Algorithm: SPEA2: Introduction
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 24 - Strength Pareto Evolutionary Algorithm: SPEA2: Simulations
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 25 - Performance Assessment of Multi-Objective EC Techniques
Link NOC:Evolutionary Computation for Single and Multi Objective Optimization Lecture 26 - Closure of EC for Single and Multi-Objective Optimization
Link NOC:Viscous Fluid Flow Lecture 1 - Preliminary concepts
Link NOC:Viscous Fluid Flow Lecture 2 - Fluid Kinematics
Link NOC:Viscous Fluid Flow Lecture 3 - Derivation of incompressible Navier-Stokes equations
Link NOC:Viscous Fluid Flow Lecture 4 - Initial and Boundary Conditions
Link NOC:Viscous Fluid Flow Lecture 5 - Plane Couette Flow
Link NOC:Viscous Fluid Flow Lecture 6 - Plane Poiseuille Flow
Link NOC:Viscous Fluid Flow Lecture 7 - Plane Poiseuille Flow with Slip and Thin Film Flow
Link NOC:Viscous Fluid Flow Lecture 8 - Combined Couette - Poiseuille Flow
Link NOC:Viscous Fluid Flow Lecture 9 - Example Problems
Link NOC:Viscous Fluid Flow Lecture 10 - Hagen - Poiseuille Flow
Link NOC:Viscous Fluid Flow Lecture 11 - Thin Film Flow and Annular Flow
Link NOC:Viscous Fluid Flow Lecture 12 - Steady Flow Between Rotating Cylinders
Link NOC:Viscous Fluid Flow Lecture 13 - Flow near a plate suddenly set in motion
Link NOC:Viscous Fluid Flow Lecture 14 - Flow due to an oscillating plate
Link NOC:Viscous Fluid Flow Lecture 15 - Transient Plane Couette Flow
Link NOC:Viscous Fluid Flow Lecture 16 - Transient Axisymmetric Poiseuille Flow
Link NOC:Viscous Fluid Flow Lecture 17 - Flow Through Rectangular Duct
Link NOC:Viscous Fluid Flow Lecture 18 - Flow Through Equilateral Triangular Duct
Link NOC:Viscous Fluid Flow Lecture 19 - Flow Through Elliptical Duct
Link NOC:Viscous Fluid Flow Lecture 20 - Example Problems
Link NOC:Viscous Fluid Flow Lecture 21 - Creeping Flow Around a Sphere
Link NOC:Viscous Fluid Flow Lecture 22 - Reynolds Equation for Lubrication
Link NOC:Viscous Fluid Flow Lecture 23 - One-dimensional Slider Bearing
Link NOC:Viscous Fluid Flow Lecture 24 - Journal Bearing and Piston-ring Lubrication
Link NOC:Viscous Fluid Flow Lecture 25 - Derivation of Boundary Layer Equations
Link NOC:Viscous Fluid Flow Lecture 26 - Blasius Flow Over A Flat Plate: Similarity Solution
Link NOC:Viscous Fluid Flow Lecture 27 - Momentum Integral Equation For Flat Plate Boundary Layer
Link NOC:Viscous Fluid Flow Lecture 28 - Falkner-Skan equation: Boundary layer flow over a wedge
Link NOC:Viscous Fluid Flow Lecture 29 - Karman-Pohlhausen Method for Non-zero Pressure Gradient Flows
Link NOC:Viscous Fluid Flow Lecture 30 - The Correlation Method by Thwaites
Link NOC:Viscous Fluid Flow Lecture 31 - Separation of Boundary Layer
Link NOC:Viscous Fluid Flow Lecture 32 - Example Problems
Link NOC:Viscous Fluid Flow Lecture 33 - Two-dimensional Laminar Jet
Link NOC:Viscous Fluid Flow Lecture 34 - Flow in the Wake of a Flat Plate
Link NOC:Viscous Fluid Flow Lecture 35 - Free Shear Layer Between Two Different Streams
Link NOC:Viscous Fluid Flow Lecture 36 - Derivation of Orr-Sommerfeld Equation
Link NOC:Viscous Fluid Flow Lecture 37 - Viscous Stability
Link NOC:Viscous Fluid Flow Lecture 38 - Inviscid Analysis
Link NOC:Viscous Fluid Flow Lecture 39 - Introduction to Turbulent Flows
Link NOC:Viscous Fluid Flow Lecture 40 - Derivation of Reynolds Averaged Navier-Stokes Equations
Link NOC:Viscous Fluid Flow Lecture 41 - External Turbulent Flows
Link NOC:Viscous Fluid Flow Lecture 42 - Integral Solution for Turbulent Boundary Layer Flow
Link NOC:Viscous Fluid Flow Lecture 43 - Internal Turbulent Flow
Link NOC:Viscous Fluid Flow Lecture 44 - Turbulence Modelling
Link NOC:Welding Application Technology Lecture 1 - Plasma Arc Welding (PAW)
Link NOC:Welding Application Technology Lecture 2 - Flux Cored Arc Welding (FCAW)
Link NOC:Welding Application Technology Lecture 3 - Thermit Welding
Link NOC:Welding Application Technology Lecture 4 - Resistance Welding - Part 1 (Resistance Spot Welding)
Link NOC:Welding Application Technology Lecture 5 - Resistance Welding - Part 2 (Types of Resistance Welding)
Link NOC:Welding Application Technology Lecture 6 - Friction Welding
Link NOC:Welding Application Technology Lecture 7 - Friction Stir Welding - Part 1
Link NOC:Welding Application Technology Lecture 8 - Friction Stir Welding - Part 2
Link NOC:Welding Application Technology Lecture 9 - Soldering
Link NOC:Welding Application Technology Lecture 10 - Brazing
Link NOC:Welding Application Technology Lecture 11 - Residual Stress - Part 1
Link NOC:Welding Application Technology Lecture 12 - Residual Stress - Part 2
Link NOC:Welding Application Technology Lecture 13 - Influencing Factors and Control of Residual Stresses
Link NOC:Welding Application Technology Lecture 14 - Residual Stress Measurement - 1
Link NOC:Welding Application Technology Lecture 15 - Residual Stress Measurement - 2
Link NOC:Welding Application Technology Lecture 16 - Residual Stress Measurement by NDT
Link NOC:Welding Application Technology Lecture 17 - Welding Induced Distortion
Link NOC:Welding Application Technology Lecture 18 - Welding Induced Distortion (Control and Measurement)
Link NOC:Welding Application Technology Lecture 19 - Welding Induced Distortion (Measurement and Prediction)
Link NOC:Welding Application Technology Lecture 20 - Welded Joint Analysis
Link NOC:Welding Application Technology Lecture 21 - Welded Joints Analysis (Strength of Parallel and Transverse Fillet Welds)
Link NOC:Welding Application Technology Lecture 22 - Welded Joints Analysis (Analysis of Eccentrically Loaded Welded Joint)
Link NOC:Welding Application Technology Lecture 23 - Welded Joints Static Analysis (Analysis of Eccentrically Loaded Welded Joint - Part 1)
Link NOC:Welding Application Technology Lecture 24 - Welded Joints Static Analysis (Analysis of Eccentrically Loaded Welded Joint - Part 2)
Link NOC:Welding Application Technology Lecture 25 - Welded Joints Static Analysis (Welded Joint Subjected to Bending Moment)
Link NOC:Welding Application Technology Lecture 26 - Welded Joints Static Analysis (Welded Joint Subjected to Bending Moment - Part 1)
Link NOC:Welding Application Technology Lecture 27 - Welded Joints Static Analysis (Welded Joint Subjected to Bending Moment - Part 2)
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 1 - Introduction to Additive Manufacturing
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 2 - CAD Models for Additive Manufacturing
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 3 - Manipulation of STL Files
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 4 - Slicing Methods - Part A
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 5 - Slicing Methods - Part B
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 6 - Toolpath Planning
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 7 - Demonstration of CAD-CAM Packages
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 8 - Introduction to Liquid AM
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 9 - Stereolithography Apparatus: Fundamentals of Photopolymerization - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 10 - Stereolithography Apparatus: Fundamentals of Photopolymerization - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 11 - Stereolithography Apparatus: Sub-systems - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 12 - Stereolithography Apparatus: Sub-systems - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 13 - Other Liquid AM Processes - 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 14 - Other Liquid AM Processes - 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 15 - Sheet Additive Manufacturing - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 16 - Sheet Additive Manufacturing - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 17 - Wire Additive Manufacturing
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 18 - Fused Deposition Modeling
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 19 - Metal Wire Additive Manufacturing
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 20 - Metal Inert Gas-Wire Arc Additive Manufacturing (MIG-WAAM) - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 21 - Metal Inert Gas-Wire Arc Additive Manufacturing (MIG-WAAM) - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 22 - Tungsten Inert Gas/Plasma-Wire Arc Additive Manufacturing (TIG/Plasma-WAAM)
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 23 - Electron beam-based Wire Beam Additive Manufacturing (WBAM)
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 24 - Laser Metal Wire Additive Manufacturing
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 25 - Powder-Feed Additive Manufacturing - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 26 - Powder-Feed Additive Manufacturing - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 27 - Process Modeling for Powder Feed Additive Manufacturing - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 28 - Process Modeling for Powder Feed Additive Manufacturing - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 29 - Laser Beam based Powder Bed Additive Manufacturing - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 30 - Laser Beam based Powder Bed Additive Manufacturing - Part 2
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 31 - Electron Beam based Powder Bed Additive Manufacturing
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 32 - Binder based Powder Bed Additive Manufacturing - Part 1
Link NOC:Fundamentals of Additive Manufacturing Technologies Lecture 33 - Binder based Powder Bed Additive Manufacturing - Part 2
Link NOC:Applied Thermodynamics Lecture 1 - Thermodynamic Systems and Pure Substance
Link NOC:Applied Thermodynamics Lecture 2 - Heat and Work Transfer - First Law of Thermodynamics
Link NOC:Applied Thermodynamics Lecture 3 - Second Law of Thermodynamics
Link NOC:Applied Thermodynamics Lecture 4 - Entropy and Exergy
Link NOC:Applied Thermodynamics Lecture 5 - Introduction to Steam Power Plant
Link NOC:Applied Thermodynamics Lecture 6 - Thermodynamics aspects of Steam Power Plant-Efficiency and Work ration
Link NOC:Applied Thermodynamics Lecture 7 - Rankine Cycle and its analysis
Link NOC:Applied Thermodynamics Lecture 8 - Improvement in Rankine Cycle Efficiency: Superheating and Reheating
Link NOC:Applied Thermodynamics Lecture 9 - Improvement in Rankine Cycle Efficiency: Reheating and Regenerative Methods
Link NOC:Applied Thermodynamics Lecture 10 - Improvement in Rankine Cycle Efficiency: Regenerative Methods
Link NOC:Applied Thermodynamics Lecture 11 - Regenerative Cycles
Link NOC:Applied Thermodynamics Lecture 12 - Impulse Steam Turbine: Velocity Diagrams,Work Transfer,Blade Efficiency
Link NOC:Applied Thermodynamics Lecture 13 - Impulse Steam Turbine: Velocity Diagrams,Work Transfer,Blade Efficiency (Continued...)
Link NOC:Applied Thermodynamics Lecture 14 - Reaction Steam Turbine
Link NOC:Applied Thermodynamics Lecture 15 - Reaction Steam Turbine: Velocity Diagram, Work transfer, Blade Efficiency
Link NOC:Applied Thermodynamics Lecture 16 - Steam Nozzle: Analysis and Efficiency
Link NOC:Applied Thermodynamics Lecture 17 - Steam Nozzle: Analysis and Efficiency (Continued...)
Link NOC:Applied Thermodynamics Lecture 18 - Boilers and Condensers
Link NOC:Applied Thermodynamics Lecture 19 - Condensers and Second Law Analysis of Steam Power cycle
Link NOC:Applied Thermodynamics Lecture 20 - Exergy Analysis of a Steam Turbine
Link NOC:Applied Thermodynamics Lecture 21 - Numerical Problems: Steam Power Cycle
Link NOC:Applied Thermodynamics Lecture 22 - IC engine-Components, Nomenclature and Classifications
Link NOC:Applied Thermodynamics Lecture 23 - Basic Engine Cycle and Engine Kinematic Analysis
Link NOC:Applied Thermodynamics Lecture 24 - Engine Operating Characteristics
Link NOC:Applied Thermodynamics Lecture 25 - Thermodynamics Analysis of Air Standard Cycles
Link NOC:Applied Thermodynamics Lecture 26 - Valve Timing Diagram and Fuel-Air Cycle
Link NOC:Applied Thermodynamics Lecture 27 - Thermochemistry and Fuel Characteristics
Link NOC:Applied Thermodynamics Lecture 28 - Combustion Phenomena in Engines
Link NOC:Applied Thermodynamics Lecture 29 - Heat Transfer Analysis in Engines
Link NOC:Applied Thermodynamics Lecture 30 - Exergy Analysis and Engine Emission/Pollution
Link NOC:Applied Thermodynamics Lecture 31 - Gas Turbine Engine-Components and Thermal Circuit
Link NOC:Applied Thermodynamics Lecture 32 - Gas Turbine Performance Cycle - I
Link NOC:Applied Thermodynamics Lecture 33 - Gas Turbine Performance Cycle - II
Link NOC:Applied Thermodynamics Lecture 34 - Real Gas Turbine Performance Cycle
Link NOC:Applied Thermodynamics Lecture 35 - Aircraft Propulsion Cycle - I
Link NOC:Applied Thermodynamics Lecture 36 - Aircraft Propulsion Cycle - II
Link NOC:Applied Thermodynamics Lecture 37 - Vapour Compression Refrigeration System - I
Link NOC:Applied Thermodynamics Lecture 38 - Vapour Compression Refrigeration System - II
Link NOC:Applied Thermodynamics Lecture 39 - Absorption Refrigeration and Refrigerants
Link NOC:Applied Thermodynamics Lecture 40 - Fundamentals of Psychrometrics
Link NOC:Applied Thermodynamics Lecture 41 - Air-Conditioning Processes
Link NOC:Applied Thermodynamics Lecture 42 - Cooling Tower and Air Washers
Link NOC:Applied Thermodynamics Lecture 43 - Reciprocating Compressor - Analysis and Modelling
Link NOC:Applied Thermodynamics Lecture 44 - Multistage Compression - Analysis and Modelling
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 1 - Composite Materials - Introduction
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 2 - Composite Materials - Classification
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 3 - Anisotropic Elasticity
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 4 - Orthotropic Materials
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 5 - Hooke’s Law for 2D Lamina
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 6 - Engineering Constants for 2D Lamina
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 7 - Strength Failure Criteria - Part I
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 8 - Strength Failure Criteria - Part II
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 9 - Hygrothermal Behavior of Lamina
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 10 - Introduction and Terminologies
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 11 - Evaluation of Elastic Moduli
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 12 - Evaluation of Longitudinal Strength
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 13 - Evaluation of Transverse and Shear Strengths
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 14 - Evaluation of Hygrothermal Properties
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 15 - Elasticity Approach
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 16 - Experimental Evaluation
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 17 - Laminate - Introduction
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 18 - Classical Lamination Theory - Part I
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 19 - Classical Lamination Theory - Part II
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 20 - Response of Laminate - Significance of ABBD
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 21 - Special Classes of Laminates
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 22 - Engineering Constants of Laminates
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 23 - Hygrothermal Behaviour of Laminates
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 24 - Analysis of Laminates
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 25 - Failure of Laminates
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 26 - Failure Analysis under Combined Loading
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 27 - Design Example - I
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 28 - Design Example - II
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 29 - Interlaminar Stresses- Delamination
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 30 - Prediction of Delamination
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 31 - Transverse Deflection
Link NOC:Mechanics of Fiber Reinforced Polymer Composite Structures Lecture 32 - Buckling and Free Vibration
Link NOC:Laser Based Manufacturing Lecture 1 - Lasers in Manufacturing: Importance and Applications
Link NOC:Laser Based Manufacturing Lecture 2 - Fundamentals of Laser Technology
Link NOC:Laser Based Manufacturing Lecture 3 - Laser System: Construction and Types
Link NOC:Laser Based Manufacturing Lecture 4 - Principle of Operation, Types of Laser Cutting, and Kerf Geometry
Link NOC:Laser Based Manufacturing Lecture 5 - Types of Lasers in Material Removal, Process and Performance Parameters
Link NOC:Laser Based Manufacturing Lecture 6 - A Case-study on Cutting a Circular Part using CO2 Laser Machine
Link NOC:Laser Based Manufacturing Lecture 7 - Mechanisms of Laser Welding - Part I
Link NOC:Laser Based Manufacturing Lecture 8 - Mechanisms of Laser Welding - Part II
Link NOC:Laser Based Manufacturing Lecture 9 - Effects of Process Parameters during Laser Welding and Study of Defects in Weld Beads
Link NOC:Laser Based Manufacturing Lecture 10 - A Case Study on Welding of Mild Steel Sheets using 2.5 kW CO2 Laser Machine
Link NOC:Laser Based Manufacturing Lecture 11 - Material Forming and Fundamentals of Laser Forming
Link NOC:Laser Based Manufacturing Lecture 12 - Mechanisms of Laser Forming
Link NOC:Laser Based Manufacturing Lecture 13 - Process Parameters and their Effects on the Performance of Laser Forming
Link NOC:Laser Based Manufacturing Lecture 14 - Surface Treatment and Application of Lasers
Link NOC:Laser Based Manufacturing Lecture 15 - Laser Surface Hardening
Link NOC:Laser Based Manufacturing Lecture 16 - Laser Surface Alloying
Link NOC:Laser Based Manufacturing Lecture 17 - Laser Cladding
Link NOC:Laser Based Manufacturing Lecture 18 - Additive Manufacturing Techniques
Link NOC:Laser Based Manufacturing Lecture 19 - Laser Scanning Stereolithography
Link NOC:Laser Based Manufacturing Lecture 20 - Selective Laser Sintering and Selective Laser Melting
Link NOC:Laser Based Manufacturing Lecture 21 - Process and Performance Parameters of Laser Based Additive Manufacturing Techniques
Link NOC:Laser Based Manufacturing Lecture 22 - Lasers in Manufacturing Automation
Link NOC:Laser Based Manufacturing Lecture 23 - CNC for Laser Based Manufacturing
Link NOC:Laser Based Manufacturing Lecture 24 - CAD for Laser Based Manufacturing
Link NOC:Laser Based Manufacturing Lecture 25 - Laser-assisted Material Forming
Link NOC:Laser Based Manufacturing Lecture 26 - Effect of Coatings, 3D Laser Forming and Micro-forming
Link NOC:Advanced Thermodynamics and Combustion Lecture 1 - Temperature and Zeroth Law of Thermodynamics
Link NOC:Advanced Thermodynamics and Combustion Lecture 2 - Work and Heat Transfer - First Law of Thermodynamics
Link NOC:Advanced Thermodynamics and Combustion Lecture 3 - Heat Engines and Refrigerators/Heat Pump - Second Law of Thermodynamics
Link NOC:Advanced Thermodynamics and Combustion Lecture 4 - Entropy Analysis - Part I
Link NOC:Advanced Thermodynamics and Combustion Lecture 5 - Entropy Analysis - Part II
Link NOC:Advanced Thermodynamics and Combustion Lecture 6 - Entropy Analysis - Part III
Link NOC:Advanced Thermodynamics and Combustion Lecture 7 - Exergy Analysis - Part I
Link NOC:Advanced Thermodynamics and Combustion Lecture 8 - Exergy Analysis - Part II
Link NOC:Advanced Thermodynamics and Combustion Lecture 9 - Exergy Analysis - Part III
Link NOC:Advanced Thermodynamics and Combustion Lecture 10 - Thermodynamic Functions and Maxwell's Equations
Link NOC:Advanced Thermodynamics and Combustion Lecture 11 - Property Relations for Phase Change Processes
Link NOC:Advanced Thermodynamics and Combustion Lecture 12 - Property Relations for Single Phase Systems
Link NOC:Advanced Thermodynamics and Combustion Lecture 13 - Heat Capacity Equations and its Applications
Link NOC:Advanced Thermodynamics and Combustion Lecture 14 - Joule - Thomson Coefficient and Liquefaction of Gases
Link NOC:Advanced Thermodynamics and Combustion Lecture 15 - Ideal Gas and Real Gas
Link NOC:Advanced Thermodynamics and Combustion Lecture 16 - Gas Mixtures and Multi-Component System
Link NOC:Advanced Thermodynamics and Combustion Lecture 17 - Ideal Gas Mixture
Link NOC:Advanced Thermodynamics and Combustion Lecture 18 - Mixing Analysis of Thermodynamic Systems
Link NOC:Advanced Thermodynamics and Combustion Lecture 19 - Thermodynamic Considerations of Combustion
Link NOC:Advanced Thermodynamics and Combustion Lecture 20 - Conservation of Energy for Reacting Systems
Link NOC:Advanced Thermodynamics and Combustion Lecture 21 - Adiabatic Flame Temperature, Entropy and Gibbs Function for Reacting System
Link NOC:Advanced Thermodynamics and Combustion Lecture 22 - Equilibrium Products of Combustion and Effective Energy Utilization
Link NOC:Advanced Thermodynamics and Combustion Lecture 23 - Fundamentals of Chemical Reactions
Link NOC:Advanced Thermodynamics and Combustion Lecture 24 - Reaction Mechanisms - Part I
Link NOC:Advanced Thermodynamics and Combustion Lecture 25 - Reaction Mechanisms - Part II
Link NOC:Advanced Thermodynamics and Combustion Lecture 26 - Chemical and Thermal Analysis of Reacting Systems
Link NOC:Advanced Thermodynamics and Combustion Lecture 27 - Simplified Conservation Equations for Reacting Flows
Link NOC:Advanced Thermodynamics and Combustion Lecture 28 - Laminar Premixed Flame - Part I
Link NOC:Advanced Thermodynamics and Combustion Lecture 29 - Laminar Premixed Flame - Part II
Link NOC:Advanced Thermodynamics and Combustion Lecture 30 - Laminar Diffusion Flame
Link NOC:Advanced Thermodynamics and Combustion Lecture 31 - Droplet Evaporation and Turbulent Flame
Link NOC:Advanced Thermodynamics and Combustion Lecture 32 - Engine Combustion and Pollution
Link NOC:Thermal Engineering: Basic and Applied Lecture 1 - First law of Thermodynamics for control mass and control volume systems
Link NOC:Thermal Engineering: Basic and Applied Lecture 2 - First law of Thermodynamics for control volume system (Flow system)
Link NOC:Thermal Engineering: Basic and Applied Lecture 3 - Steady State Steady Flow Processes, combination of First and Second Laws
Link NOC:Thermal Engineering: Basic and Applied Lecture 4 - Second Law of Thermodynamics: A Brief Review
Link NOC:Thermal Engineering: Basic and Applied Lecture 5 - Combined First and Second Laws Applied to Processes
Link NOC:Thermal Engineering: Basic and Applied Lecture 6 - Combined First and Second Laws: Flow and Non-Flow Processes
Link NOC:Thermal Engineering: Basic and Applied Lecture 7 - Description of Steam Power Plant: Application of 1st and 2nd Laws to Different Processes
Link NOC:Thermal Engineering: Basic and Applied Lecture 8 - Second Law Applied to Processes of Power Plant and Ideal Cycle of Power Plant
Link NOC:Thermal Engineering: Basic and Applied Lecture 9 - Steam Power Plant: Thermodynamic aspects, Efficiency, Work ratio and Ideal Cycle
Link NOC:Thermal Engineering: Basic and Applied Lecture 10 - Ideal Power Cycle and its Limitations, Introduction to Actual Power Cycle
Link NOC:Thermal Engineering: Basic and Applied Lecture 11 - Limitations of Carnot Cycle, Simple Rankine Cycle and Analysis
Link NOC:Thermal Engineering: Basic and Applied Lecture 12 - Analysis of Simple Rankine Cycle and its Design Modifications
Link NOC:Thermal Engineering: Basic and Applied Lecture 13 - Reheat Cycle and Analysis
Link NOC:Thermal Engineering: Basic and Applied Lecture 14 - Reheat Cycle and Analysis (Continued...)
Link NOC:Thermal Engineering: Basic and Applied Lecture 15 - Regenerative Principle of Steam Power Cycles
Link NOC:Thermal Engineering: Basic and Applied Lecture 16 - Analysis of Regenerative Steam Power Cycles
Link NOC:Thermal Engineering: Basic and Applied Lecture 17 - Regenerative Steam Power Cycle with Closed Feed-Water Heater, Ideal Working Fluid
Link NOC:Thermal Engineering: Basic and Applied Lecture 18 - Multi-fluid Cycle and Analysis
Link NOC:Thermal Engineering: Basic and Applied Lecture 19 - Analysis of Multi-fluid Cycle; Second Law Analysis of Steam Power Cycle
Link NOC:Thermal Engineering: Basic and Applied Lecture 20 - Problems of Steam Power Cycle
Link NOC:Thermal Engineering: Basic and Applied Lecture 21 - Problems of Steam Power Cycle (Continued...)
Link NOC:Thermal Engineering: Basic and Applied Lecture 22 - Types of Boiler, Different Cycles in Boiler Operation, Boiler attachment
Link NOC:Thermal Engineering: Basic and Applied Lecture 23 - Cochran Boiler Operation, Boiler attachment
Link NOC:Thermal Engineering: Basic and Applied Lecture 24 - Boiler Attachments
Link NOC:Thermal Engineering: Basic and Applied Lecture 25 - Superheaters and their Arrangements, Steam Temperature Control
Link NOC:Thermal Engineering: Basic and Applied Lecture 26 - Characteristics of Convective and Radiant Superheaters; Steam Temperature Control
Link NOC:Thermal Engineering: Basic and Applied Lecture 27 - Problems on Boiler/Steam Generator
Link NOC:Thermal Engineering: Basic and Applied Lecture 28 - Use of nozzles in steam power plant, flow analysis of steam in nozzle
Link NOC:Thermal Engineering: Basic and Applied Lecture 29 - Flow analysis of steam in nozzle: Mass flow rate
Link NOC:Thermal Engineering: Basic and Applied Lecture 30 - Mass flow rate of steam in nozzle, Critical Pressure Ratio
Link NOC:Thermal Engineering: Basic and Applied Lecture 31 - Critical Pressure Ratio and its Physical Significance
Link NOC:Thermal Engineering: Basic and Applied Lecture 32 - Nozzle efficiency and factors that affect the efficiency
Link NOC:Thermal Engineering: Basic and Applied Lecture 33 - Factors that affect the efficiency, problem on flow nozzle
Link NOC:Thermal Engineering: Basic and Applied Lecture 34 - Problem on flow nozzle
Link NOC:Thermal Engineering: Basic and Applied Lecture 35 - Steam Turbines: types and analysis using velocity triangles
Link NOC:Thermal Engineering: Basic and Applied Lecture 36 - Analysis of Impulse Steam Turbine
Link NOC:Thermal Engineering: Basic and Applied Lecture 37 - Compounding of Steam Turbine
Link NOC:Thermal Engineering: Basic and Applied Lecture 38 - Analysis of Reaction Steam Turbine
Link NOC:Thermal Engineering: Basic and Applied Lecture 39 - Problems on Steam Turbine
Link NOC:Thermal Engineering: Basic and Applied Lecture 40 - The Role of Condenser in Power Plant
Link NOC:Thermal Engineering: Basic and Applied Lecture 41 - Cooling Tower: Types and Analysis
Link NOC:Thermal Engineering: Basic and Applied Lecture 42 - Cooling Tower Performance
Link NOC:Thermal Engineering: Basic and Applied Lecture 43 - IC Engines, Classification, Different Parts, SI and CI Engines
Link NOC:Thermal Engineering: Basic and Applied Lecture 44 - Comparison of 2-stroke and 4-stroke Engines
Link NOC:Thermal Engineering: Basic and Applied Lecture 45 - Comparison of SI and CI Engines, Compression Ratio
Link NOC:Thermal Engineering: Basic and Applied Lecture 46 - Introduction to Carburettor and Regimes of Engine Operation
Link NOC:Thermal Engineering: Basic and Applied Lecture 47 - Regimes of Engine Operation and Simple Float Type Carburettor
Link NOC:Thermal Engineering: Basic and Applied Lecture 48 - Simple Float Type Carburettor and its Analysis
Link NOC:Thermal Engineering: Basic and Applied Lecture 49 - Mass Flow Rate of Fuel and limitations of Simple Float Type Carburettor
Link NOC:Thermal Engineering: Basic and Applied Lecture 50 - Limitations of Simple Float Type Carburettor, Problem on Carburettion
Link NOC:Thermal Engineering: Basic and Applied Lecture 51 - Engine Operating Characteristics: MEP and Indicator diagram
Link NOC:Thermal Engineering: Basic and Applied Lecture 52 - Performance Analysis parameters of IC Engine
Link NOC:Thermal Engineering: Basic and Applied Lecture 53 - Fuel of IC Engines
Link NOC:Thermal Engineering: Basic and Applied Lecture 54 - Alternative Fuels and Self Ignition Characteristics of Fuel: Octane Numner, Cetane Number
Link NOC:Thermal Engineering: Basic and Applied Lecture 55 - Thermodynamic Analysis of SI Engine
Link NOC:Thermal Engineering: Basic and Applied Lecture 56 - Thermodynamic Analysis of CI Engine
Link NOC:Thermal Engineering: Basic and Applied Lecture 57 - Numerical Problems on Engine Performance
Link NOC:Thermal Engineering: Basic and Applied Lecture 58 - Pressure-Crank angle diagram, Engine Efficiencies
Link NOC:Thermal Engineering: Basic and Applied Lecture 59 - Numerical Problems on SI and CI Engines
Link NOC:Thermal Engineering: Basic and Applied Lecture 60 - Vapour Compression Refrigeration Cycle and its analysis
Link NOC:Thermal Engineering: Basic and Applied Lecture 61 - Problems on Vapour Compression Refrigeration Cycle
Link NOC:Thermal Engineering: Basic and Applied Lecture 62 - Gas Turbine Units and Thermodynamic Cycles
Link NOC:Thermal Engineering: Basic and Applied Lecture 63 - Gas Compressor and Optimum Pressure Ratio
Link NOC:Thermal Engineering: Basic and Applied Lecture 64 - Compressor Efficiency and Multistage Compression with Intercooling
Link NOC:Thermal Engineering: Basic and Applied Lecture 65 - Gas Turbine Unit: Combined Cycle
Link NOC:Thermal Engineering: Basic and Applied Lecture 66 - Problems On Gas Turbine Cycle
Link NOC:Mechanics of Sheet Metal Forming Lecture 1 - Introduction to sheet forming and tensile test of sheets
Link NOC:Mechanics of Sheet Metal Forming Lecture 2 - Tensile test, effect of properties, exercise problem
Link NOC:Mechanics of Sheet Metal Forming Lecture 3 - Sheet deformation processes
Link NOC:Mechanics of Sheet Metal Forming Lecture 4 - Sheet deformation processes (Continued...)
Link NOC:Mechanics of Sheet Metal Forming Lecture 5 - Sheet deformation processes (Continued...)
Link NOC:Mechanics of Sheet Metal Forming Lecture 6 - Sheet deformation in plane stress
Link NOC:Mechanics of Sheet Metal Forming Lecture 7 - Sheet deformation in plane stress (Continued...)
Link NOC:Mechanics of Sheet Metal Forming Lecture 8 - Stamping analyses
Link NOC:Mechanics of Sheet Metal Forming Lecture 9 - Load instability and tearing
Link NOC:Mechanics of Sheet Metal Forming Lecture 10 - Load instability and tearing
Link NOC:Mechanics of Sheet Metal Forming Lecture 11 - Formability testing of sheet metals
Link NOC:Mechanics of Sheet Metal Forming Lecture 12 - Sheet formability
Link NOC:Mechanics of Sheet Metal Forming Lecture 13 - Sheet formability (Continued...)
Link NOC:Mechanics of Sheet Metal Forming Lecture 14 - Bending of sheets
Link NOC:Mechanics of Sheet Metal Forming Lecture 15 - Bending of sheets (Continued...)
Link NOC:Mechanics of Sheet Metal Forming Lecture 16 - Cup deep drawing
Link NOC:Mechanics of Sheet Metal Forming Lecture 17 - Deep drawing, redrawing, ironing of cup
Link NOC:Mechanics of Sheet Metal Forming Lecture 18 - Stretching of sheet
Link NOC:Mechanics of Sheet Metal Forming Lecture 19 - Hydroforming
Link NOC:Mechanics of Sheet Metal Forming Lecture 20 - Yield functions with sheet anisotropy
Link NOC:Mechanics of Sheet Metal Forming Lecture 21 - Demonstration of sheet forming experiments
Link NOC:Power Plant System Engineering Lecture 1 - Thermodynamics Concepts - Part I
Link NOC:Power Plant System Engineering Lecture 2 - Thermodynamics Concepts - Part II
Link NOC:Power Plant System Engineering Lecture 3 - Thermodynamic Analysis of Vapor Power Cycle
Link NOC:Power Plant System Engineering Lecture 4 - Rankine Cycle
Link NOC:Power Plant System Engineering Lecture 5 - Modified Rankine Cycle
Link NOC:Power Plant System Engineering Lecture 6 - Exergy Analysis of Vapor Power Cycles
Link NOC:Power Plant System Engineering Lecture 7 - Rotodynambic Machines
Link NOC:Power Plant System Engineering Lecture 8 - Impulse Turbine
Link NOC:Power Plant System Engineering Lecture 9 - Reaction Turbine
Link NOC:Power Plant System Engineering Lecture 10 - Performance Analysis of Steam Turbines
Link NOC:Power Plant System Engineering Lecture 11 - Steam Nozzles - Part I
Link NOC:Power Plant System Engineering Lecture 12 - Steam Nozzles - Part II
Link NOC:Power Plant System Engineering Lecture 13 - Steam Generator
Link NOC:Power Plant System Engineering Lecture 14 - Water Tube Boiler - Part I
Link NOC:Power Plant System Engineering Lecture 15 - Water Tube Boiler - Part II
Link NOC:Power Plant System Engineering Lecture 16 - Fuels and Combustion - Part I
Link NOC:Power Plant System Engineering Lecture 17 - Fuels and Combustion - Part II
Link NOC:Power Plant System Engineering Lecture 18 - Steam Condenser
Link NOC:Power Plant System Engineering Lecture 19 - Feed Water Heaters
Link NOC:Power Plant System Engineering Lecture 20 - Cooling Towers
Link NOC:Power Plant System Engineering Lecture 21 - Fundamentals of Gas turbine systems
Link NOC:Power Plant System Engineering Lecture 22 - Modifications of Brayton cycle
Link NOC:Power Plant System Engineering Lecture 23 - Combined Power cycle
Link NOC:Power Plant System Engineering Lecture 24 - Gas Turbines for Aircraft Propulsion
Link NOC:Power Plant System Engineering Lecture 25 - Hydro-Power System - Part I
Link NOC:Power Plant System Engineering Lecture 26 - Hydro-Power System - Part II
Link NOC:Power Plant System Engineering Lecture 27 - Wind Energy - Part I
Link NOC:Power Plant System Engineering Lecture 28 - Wind Energy - Part II
Link NOC:Power Plant System Engineering Lecture 29 - Energy From Oceans - Part I
Link NOC:Power Plant System Engineering Lecture 30 - Energy From Oceans - Part II
Link NOC:Power Plant System Engineering Lecture 31 - Geothermal Energy
Link NOC:Power Plant System Engineering Lecture 32 - Energy Storage - I
Link NOC:Power Plant System Engineering Lecture 33 - Energy Storage - II
Link NOC:Power Plant System Engineering Lecture 34 - Energy Storage - III
Link NOC:Introduction to Solidification Processing Lecture 1 - Introduction to phase diagrams
Link NOC:Introduction to Solidification Processing Lecture 2 - Thermodynamic relations
Link NOC:Introduction to Solidification Processing Lecture 3 - Single component system and binary solutions
Link NOC:Introduction to Solidification Processing Lecture 4 - Regular solutions
Link NOC:Introduction to Solidification Processing Lecture 5 - Real solutions
Link NOC:Introduction to Solidification Processing Lecture 6 - Phase transformations
Link NOC:Introduction to Solidification Processing Lecture 7 - Practice problems (Module 1)
Link NOC:Introduction to Solidification Processing Lecture 8 - Introduction to homogenous nucleation process
Link NOC:Introduction to Solidification Processing Lecture 9 - Fundamental to heterogeneous nucleation
Link NOC:Introduction to Solidification Processing Lecture 10 - Growth of pure metal
Link NOC:Introduction to Solidification Processing Lecture 11 - Alloy solidification
Link NOC:Introduction to Solidification Processing Lecture 12 - Formation of different S/L interface
Link NOC:Introduction to Solidification Processing Lecture 13 - Solidifcation structures and segregation
Link NOC:Introduction to Solidification Processing Lecture 14 - Weld Metal Solidification and Microstructure - I
Link NOC:Introduction to Solidification Processing Lecture 15 - Weld Metal Solidification and Microstructure - II
Link NOC:Introduction to Solidification Processing Lecture 16 - Solidification of additive manufacturing - I
Link NOC:Introduction to Solidification Processing Lecture 17 - Solidification of additive manufacturing - II
Link NOC:Introduction to Solidification Processing Lecture 18 - Rate of solidification-sand casting
Link NOC:Introduction to Solidification Processing Lecture 19 - Rate of solidification-die casting
Link NOC:Introduction to Solidification Processing Lecture 20 - Riser design and solidification of pure metal
Link NOC:Introduction to Solidification Processing Lecture 21 - Zone melting and rapid solidification
Link NOC:Introduction to Solidification Processing Lecture 22 - Semisolid processing and other solidification techniques
Link NOC:Introduction to Solidification Processing Lecture 23 - Demonstration of the solidification process and numerical problems
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 1 - Materials and microcture evolutions - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 2 - Materials and microcture evolutions - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 3 - Materials and microcture evolutions - 3
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 4 - Basics of heat conduction - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 5 - Basics of heat conduction - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 6 - Basics of heat conduction - 3
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 7 - Basics of heat conduction - 4
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 8 - Basics of fluid flow - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 9 - Basics of fluid flow - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 10 - Solidification processing - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 11 - Solidification processing - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 12 - Casting and welding - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 13 - Casting and welding - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 14 - Casting and welding - 3
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 15 - Casting and welding - 4
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 16 - Material forming
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 17 - Material forming: Numerical problem
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 18 - Processing of metal: Casting Process - I
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 19 - Processing of metal: Casting Process - II
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 20 - Processing of polymer: Thermoplastic and thermosets
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 21 - Processing of polymer: Extrusion
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 22 - Processing of polymer: Injection molding
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 23 - Processing of polymer: Blow molding
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 24 - Processing of polymer: Thermosets
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 25 - Processing of ceramics - I
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 26 - Processing of ceramics - II
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 27 - Processing of galss and fused depostion modeling
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 28 - Arc wellding processes
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 29 - Welding of polymers
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 30 - Laser and electron beam welding processes
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 31 - Advanced welding processes
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 32 - Welding solidification
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 33 - Metallic wire additive manufacturing
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 34 - Mechanical responses of metals and polymers
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 35 - Hot working and cold working
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 36 - Types of metal forming processes - I
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 37 - Types of metal forming processes - II
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 38 - Types of metal forming processes - III and Hot rolling of steel
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 39 - Solid state deformation - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 40 - Solid state deformation - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 41 - Powder processing - 1
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 42 - Powder processing - 2
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 43 - Powder processing - 3
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 44 - Ceramic processing: Dry pressing and plastic forming methods
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 45 - Ceramic processing: Colloidal processing, casting, and coating techniques
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 46 - Introduction to steel making and single crystal production
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 47 - Integrated Analysis of Steel Solidification, Fluid Flow, and Prodder Processing Technologies
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 48 - Processing of electronics Materials, A case Study: semiconductor measurements
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 49 - Processing of magnetic materials and Processing of magnetic materials for advanced materials
Link NOC:Materials Processing (Casting, Forming and Welding) Lecture 50 - Processing of optics materials and pertaining case study
Link Acoustics Lecture 1 - Intro, sound wave versus vibration, different types of waves, octave, music scales, sense of SPL
Link Acoustics Lecture 2 - Review: Linearity, complex numbers, and spring mass system
Link Acoustics Lecture 3 - Review: Poles and zeroes, phase and magnitude plots, transfer functions, Bode plots
Link Acoustics Lecture 4 - Review: Transfer functions, and Bode plots
Link Acoustics Lecture 5 - 1-D wave equation, and its solution
Link Acoustics Lecture 6 - Solution for 1-D wave equation
Link Acoustics Lecture 7 - Waveguides, transmission line equations, and standing waves
Link Acoustics Lecture 8 - Waveguides, transmission line equations, and standing waves
Link Acoustics Lecture 9 - Examples of 1-D waves in tubes, short tubes, Kundt's tube
Link Acoustics Lecture 10 - Thermodynamic processes during sound transmission
Link Acoustics Lecture 11 - Numerical examples
Link Acoustics Lecture 12 - Sound transmission through walls
Link Acoustics Lecture 13 - Sound transmission through walls
Link Acoustics Lecture 14 - Leakage in walls, STC Ratings, Octave bands
Link Acoustics Lecture 15 - Instantaneous power flow
Link Acoustics Lecture 16 - Radial propagation of sound, monopoles, and dipoles
Link Acoustics Lecture 17 - Radial propagation of sound, monopoles, and dipoles
Link Acoustics Lecture 18 - Radial propagation of sound, monopoles, and dipoles
Link Acoustics Lecture 19 - Numerical examples
Link Acoustics Lecture 20 - Numerical examples
Link Acoustics Lecture 21 - Directivity
Link Acoustics Lecture 22 - Directivity
Link Acoustics Lecture 23 - Directivity
Link Acoustics Lecture 24 - Directivity
Link Acoustics Lecture 25 - Generalized elements
Link Acoustics Lecture 26 - Examples of electromechanical systems
Link Acoustics Lecture 27 - Transformers, radiation impedance, and Helmholtz resonator
Link Acoustics Lecture 28 - Radiation impedance
Link Acoustics Lecture 29 - Radiation impedance
Link Acoustics Lecture 30 - Models of electro-mechanical-acoustic systems
Link Acoustics Lecture 31 - Solution for a loudspeaker model
Link Acoustics Lecture 32 - Microphones
Link Acoustics Lecture 33 - Vibro-meter, seismometer, accelerometer, shaker table
Link Acoustics Lecture 34 - Sound propagation in rooms, 1-D rooms, 2D rooms
Link Acoustics Lecture 35 - Sound in 3-D rooms
Link Acoustics Lecture 36 - Absorption coefficient, and irregular rooms
Link Acoustics Lecture 37 - Room constant, and Sabine's coefficient
Link Acoustics Lecture 38 - Design of a muffler
Link Acoustics Lecture 39 - Noise in machines, basics of noise management
Link Advanced Machining Processes Lecture 1 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 2 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 3 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 4 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 5 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 6 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 7 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 8 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 9 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 10 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 11 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 12 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 13 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 14 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 15 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 16 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 17 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 18 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 19 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 20 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 21 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 22 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 23 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 24 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 25 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 26 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 27 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 28 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 29 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 30 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 31 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 32 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 33 - Advanced Machining Processes
Link Advanced Machining Processes Lecture 34 - Advanced Machining Processes
Link Biomicroelectromechanical systems Lecture 1
Link Biomicroelectromechanical systems Lecture 2
Link Biomicroelectromechanical systems Lecture 3
Link Biomicroelectromechanical systems Lecture 4
Link Biomicroelectromechanical systems Lecture 5
Link Biomicroelectromechanical systems Lecture 6
Link Biomicroelectromechanical systems Lecture 7
Link Biomicroelectromechanical systems Lecture 8
Link Biomicroelectromechanical systems Lecture 9
Link Biomicroelectromechanical systems Lecture 10 (same as 9)
Link Biomicroelectromechanical systems Lecture 11
Link Biomicroelectromechanical systems Lecture 12
Link Biomicroelectromechanical systems Lecture 13
Link Biomicroelectromechanical systems Lecture 14
Link Biomicroelectromechanical systems Lecture 15
Link Biomicroelectromechanical systems Lecture 16
Link Biomicroelectromechanical systems Lecture 17
Link Biomicroelectromechanical systems Lecture 18
Link Biomicroelectromechanical systems Lecture 19
Link Biomicroelectromechanical systems Lecture 20
Link Biomicroelectromechanical systems Lecture 21
Link Biomicroelectromechanical systems Lecture 22
Link Biomicroelectromechanical systems Lecture 23
Link Biomicroelectromechanical systems Lecture 24
Link Biomicroelectromechanical systems Lecture 25
Link Biomicroelectromechanical systems Lecture 26
Link Biomicroelectromechanical systems Lecture 27
Link Biomicroelectromechanical systems Lecture 28
Link Biomicroelectromechanical systems Lecture 29
Link Biomicroelectromechanical systems Lecture 30
Link Biomicroelectromechanical systems Lecture 31
Link Biomicroelectromechanical systems Lecture 32
Link Biomicroelectromechanical systems Lecture 33
Link Biomicroelectromechanical systems Lecture 34
Link Biomicroelectromechanical systems Lecture 35
Link Biomicroelectromechanical systems Lecture 36
Link Biomicroelectromechanical systems Lecture 37
Link Biomicroelectromechanical systems Lecture 38
Link Biomicroelectromechanical systems Lecture 39
Link Biomicroelectromechanical systems Lecture 40
Link Computer Aided Engineering Design Lecture 1
Link Computer Aided Engineering Design Lecture 2
Link Computer Aided Engineering Design Lecture 3
Link Computer Aided Engineering Design Lecture 4
Link Computer Aided Engineering Design Lecture 5
Link Computer Aided Engineering Design Lecture 6
Link Computer Aided Engineering Design Lecture 7
Link Computer Aided Engineering Design Lecture 8
Link Computer Aided Engineering Design Lecture 9
Link Computer Aided Engineering Design Lecture 10
Link Computer Aided Engineering Design Lecture 11
Link Computer Aided Engineering Design Lecture 12
Link Computer Aided Engineering Design Lecture 13
Link Computer Aided Engineering Design Lecture 14
Link Computer Aided Engineering Design Lecture 15
Link Computer Aided Engineering Design Lecture 16
Link Computer Aided Engineering Design Lecture 17
Link Computer Aided Engineering Design Lecture 18
Link Computer Aided Engineering Design Lecture 19
Link Computer Aided Engineering Design Lecture 20
Link Computer Aided Engineering Design Lecture 21
Link Computer Aided Engineering Design Lecture 22
Link Computer Aided Engineering Design Lecture 23
Link Computer Aided Engineering Design Lecture 24
Link Computer Aided Engineering Design Lecture 25
Link Computer Aided Engineering Design Lecture 26
Link Computer Aided Engineering Design Lecture 27
Link Computer Aided Engineering Design Lecture 28
Link Computer Aided Engineering Design Lecture 29
Link Computer Aided Engineering Design Lecture 30
Link Computer Aided Engineering Design Lecture 31
Link Computer Aided Engineering Design Lecture 32
Link Computer Aided Engineering Design Lecture 33
Link Computer Aided Engineering Design Lecture 34
Link Computer Aided Engineering Design Lecture 35
Link Computer Aided Engineering Design Lecture 36
Link Computer Aided Engineering Design Lecture 37
Link Computer Aided Engineering Design Lecture 38
Link Computer Aided Engineering Design Lecture 39
Link Computer Aided Engineering Design Lecture 40
Link Mathematical Methods in Engineering and Science Lecture 1 - Introduction
Link Mathematical Methods in Engineering and Science Lecture 2 - Basic Ideas of Applied Linear Algebra
Link Mathematical Methods in Engineering and Science Lecture 3 - Systems of Linear Equations
Link Mathematical Methods in Engineering and Science Lecture 4 - Square Non-Singular Systems
Link Mathematical Methods in Engineering and Science Lecture 5 - Ill-Conditioned and Ill-Posed Systems
Link Mathematical Methods in Engineering and Science Lecture 6 - The Algebraic Eigenvalue Problem
Link Mathematical Methods in Engineering and Science Lecture 7 - Canonical Forms, Symmetric Matrices
Link Mathematical Methods in Engineering and Science Lecture 8 - Methods of Plane Rotations
Link Mathematical Methods in Engineering and Science Lecture 9 - Householder Method, Tridiagonal Matrices
Link Mathematical Methods in Engineering and Science Lecture 10 - QR Decomposition, General Matrices
Link Mathematical Methods in Engineering and Science Lecture 11 - Singular Value Decomposition
Link Mathematical Methods in Engineering and Science Lecture 12 - Vector Space: Concepts
Link Mathematical Methods in Engineering and Science Lecture 13 - Multivariate Calculus
Link Mathematical Methods in Engineering and Science Lecture 14 - Vector Calculus in Geometry
Link Mathematical Methods in Engineering and Science Lecture 15 - Vector Calculus in Physics
Link Mathematical Methods in Engineering and Science Lecture 16 - Solution of Equations
Link Mathematical Methods in Engineering and Science Lecture 17 - Introdcution to Optimization
Link Mathematical Methods in Engineering and Science Lecture 18 - Multivariate Optimization
Link Mathematical Methods in Engineering and Science Lecture 19 - Constrained Optimization: Optimality Criteria
Link Mathematical Methods in Engineering and Science Lecture 20 - Constrained Optimization: Further Issues
Link Mathematical Methods in Engineering and Science Lecture 21 - Interpolation
Link Mathematical Methods in Engineering and Science Lecture 22 - Numerical Integration
Link Mathematical Methods in Engineering and Science Lecture 23 - Numerical Solution of ODE's as IVP
Link Mathematical Methods in Engineering and Science Lecture 24 - Boundary Value Problems, Question of Stability in IVP Solution
Link Mathematical Methods in Engineering and Science Lecture 25 - Stiff Differential Equations, Existence and Uniqueness Theory
Link Mathematical Methods in Engineering and Science Lecture 26 - Theory of First Order ODE's
Link Mathematical Methods in Engineering and Science Lecture 27 - Linear Second Order ODE's
Link Mathematical Methods in Engineering and Science Lecture 28 - Methods of Linear ODE's
Link Mathematical Methods in Engineering and Science Lecture 29 - ODE Systems
Link Mathematical Methods in Engineering and Science Lecture 30 - Stability of Dynamic Systems
Link Mathematical Methods in Engineering and Science Lecture 31 - Series Solutions and Special Functions
Link Mathematical Methods in Engineering and Science Lecture 32 - Sturm-Liouville Theory
Link Mathematical Methods in Engineering and Science Lecture 33 - Approximation Theory and Fourier Series
Link Mathematical Methods in Engineering and Science Lecture 34 - Fourier Integral to Fourier Transform, Minimax Approximation
Link Mathematical Methods in Engineering and Science Lecture 35 - Separation of Variables in PDE's, Hyperbolic Equations
Link Mathematical Methods in Engineering and Science Lecture 36 - Parabolic and Elliptic Equations, Membrane Equation
Link Mathematical Methods in Engineering and Science Lecture 37 - Analytic Functions
Link Mathematical Methods in Engineering and Science Lecture 38 - Integration of Complex Functions
Link Mathematical Methods in Engineering and Science Lecture 39 - Singularities and Residues
Link Mathematical Methods in Engineering and Science Lecture 40 - Calculus of Variations
Link Dynamics of Machines Lecture 1 - Rigid Body Motion - Part 1
Link Dynamics of Machines Lecture 2 - Rigid Body Motion - Part 2
Link Dynamics of Machines Lecture 3 - Dynamic Force Analysis of Mechanisms
Link Dynamics of Machines Lecture 4 - Space Motion of Rigid Bodies
Link Dynamics of Machines Lecture 5 - Inertia Tensor Angular Momentum
Link Dynamics of Machines Lecture 6 - Euler's Equation of Motion
Link Dynamics of Machines Lecture 7 - Gyroscopic Action in Machines
Link Dynamics of Machines Lecture 8 - Unbalance in Machines
Link Dynamics of Machines Lecture 9 - Rotary Balancing
Link Dynamics of Machines Lecture 10 - Balancing Machines
Link Dynamics of Machines Lecture 11 - Field Balancing of Rotors
Link Dynamics of Machines Lecture 12 - Single-Cylinder Engine Balancing
Link Dynamics of Machines Lecture 13 - Balancing of Single Slider Machines
Link Dynamics of Machines Lecture 14 - In-Line Engine Balancing
Link Dynamics of Machines Lecture 15 - V and Radial Engine Balancing
Link Dynamics of Machines Lecture 16 - Turning Moment Diagram
Link Dynamics of Machines Lecture 17 - Flywheel Analysis
Link Dynamics of Machines Lecture 18 - Dynamics of Machines
Link Dynamics of Machines Lecture 19 - Dynamics of Machines
Link Dynamics of Machines Lecture 20 - Dynamics of Machines
Link Dynamics of Machines Lecture 21 - Dynamics of Machines
Link Dynamics of Machines Lecture 22 - Dynamics of Machines
Link Dynamics of Machines Lecture 23 - Dynamics of Machines
Link Dynamics of Machines Lecture 24 - Dynamics of Machines
Link Dynamics of Machines Lecture 25 - Dynamics of Machines
Link Dynamics of Machines Lecture 26 - Dynamics of Machines
Link Dynamics of Machines Lecture 27 - Dynamics of Machines
Link Dynamics of Machines Lecture 28 - Dynamics of Machines
Link Dynamics of Machines Lecture 29 - Rotating Vector Approach
Link Dynamics of Machines Lecture 30 - Equivalent viscous damping
Link Dynamics of Machines Lecture 31 - Dynamics of Machines
Link Dynamics of Machines Lecture 32 - Systems with two degree of freedom
Link Dynamics of Machines Lecture 33 - Tuned Vibration Absorber
Link Dynamics of Machines Lecture 34 - Design of Vibration Absorbers
Link Dynamics of Machines Lecture 35 - Flexibility Matrix Influence Coeff
Link Dynamics of Machines Lecture 36 - Forced Vibration of multiple
Link Dynamics of Machines Lecture 37 - Forced Vibration of Multiple degrees
Link Dynamics of Machines Lecture 38 - Vibration of Continuous Systems
Link Dynamics of Machines Lecture 39 - Vibration of Continuous Systems
Link Dynamics of Machines Lecture 40 - Vibration of Beams
Link Dynamics of Machines Lecture 41 - Rayleigh's method
Link Dynamics of Machines Lecture 42 - Rayleigh-Ritz Method
Link Dynamics of Machines Lecture 43 - Vibration Measurement
Link Dynamics of Machines Lecture 44 - Vibration Measurement Types of Pickups
Link Finite Element Method Module 1 - Lecture 1
Link Finite Element Method Module 1 - Lecture 2
Link Finite Element Method Module 1 - Lecture 3
Link Finite Element Method Module 2 - Lecture 1
Link Finite Element Method Module 2 - Lecture 2
Link Finite Element Method Module 2 - Lecture 3
Link Finite Element Method Module 2 - Lecture 4
Link Finite Element Method Module 3 - Lecture 1
Link Finite Element Method Module 3 - Lecture 2
Link Finite Element Method Module 3 - Lecture 3
Link Finite Element Method Module 4 - Lecture 1
Link Finite Element Method Module 4 - Lecture 2
Link Finite Element Method Module 4 - Lecture 3
Link Finite Element Method Module 5 - Lecture 1
Link Finite Element Method Module 5 - Lecture 2
Link Finite Element Method Module 5 - Lecture 3
Link Finite Element Method Module 6 - Lecture 1
Link Finite Element Method Module 6 - Lecture 2
Link Finite Element Method Module 6 - Lecture 3
Link Finite Element Method Module 7 - Lecture 1
Link Finite Element Method Module 7 - Lecture 2
Link Finite Element Method Module 7 - Lecture 3
Link Finite Element Method Module 7 - Lecture 4
Link Finite Element Method Module 8 - Lecture 1
Link Finite Element Method Module 8 - Lecture 2
Link Finite Element Method Module 8 - Lecture 3
Link Finite Element Method Module 9 - Lecture 1
Link Finite Element Method Module 9 - Lecture 2
Link Finite Element Method Module 9 - Lecture 3
Link Finite Element Method Module 10 - Lecture 1
Link Finite Element Method Module 10 - Lecture 2
Link Finite Element Method Module 11 - Lecture 1
Link Finite Element Method Module 11 - Lecture 2
Link Finite Element Method Module 12 - Lecture 1
Link Finite Element Method Module 13 - Lecture 1
Link Finite Element Method Module 13 - Lecture 2
Link Finite Element Method Module 14 - Lecture 1
Link Finite Element Method Module 14 - Lecture 2
Link Kinematics of Machines Module 1 - Lecture 1
Link Kinematics of Machines Module 1 - Lecture 2
Link Kinematics of Machines Module 1 - Lecture 3
Link Kinematics of Machines Module 2 - Lecture 1
Link Kinematics of Machines Module 2 - Lecture 2
Link Kinematics of Machines Module 2 - Lecture 3
Link Kinematics of Machines Module 3 - Lecture 1
Link Kinematics of Machines Module 3 - Lecture 2
Link Kinematics of Machines Module 3 - Lecture 3
Link Kinematics of Machines Module 3 - Lecture 4
Link Kinematics of Machines Module 4 - Lecture 1
Link Kinematics of Machines Module 4 - Lecture 2
Link Kinematics of Machines Module 5 - Lecture 1
Link Kinematics of Machines Module 5 - Lecture 2
Link Kinematics of Machines Module 5 - Lecture 3
Link Kinematics of Machines Module 6 - Lecture 1
Link Kinematics of Machines Module 6 - Lecture 2
Link Kinematics of Machines Module 6 - Lecture 3
Link Kinematics of Machines Module 7 - Lecture 1
Link Kinematics of Machines Module 7 - Lecture 2
Link Kinematics of Machines Module 7 - Lecture 3
Link Kinematics of Machines Module 8 - Lecture 1
Link Kinematics of Machines Module 8 - Lecture 2
Link Kinematics of Machines Module 9 - Lecture 1
Link Kinematics of Machines Module 9 - Lecture 2
Link Kinematics of Machines Module 9 - Lecture 3
Link Kinematics of Machines Module 9 - Lecture 4
Link Kinematics of Machines Module 10 - Lecture 1
Link Kinematics of Machines Module 10 - Lecture 2
Link Kinematics of Machines Module 10 - Lecture 3
Link Kinematics of Machines Module 11 - Lecture 1
Link Kinematics of Machines Module 11 - Lecture 2
Link Kinematics of Machines Module 11 - Lecture 3
Link Kinematics of Machines Module 12 - Lecture 1
Link Kinematics of Machines Module 12 - Lecture 2
Link Kinematics of Machines Module 12 - Lecture 3
Link Kinematics of Machines Module 13 - Lecture 1
Link Kinematics of Machines Module 13 - Lecture 2
Link Kinematics of Machines Module 13 - Lecture 3
Link Advanced manufacturing process for micro sytem fabrication Lecture 1
Link Advanced manufacturing process for micro sytem fabrication Lecture 2
Link Advanced manufacturing process for micro sytem fabrication Lecture 3
Link Advanced manufacturing process for micro sytem fabrication Lecture 4
Link Advanced manufacturing process for micro sytem fabrication Lecture 5
Link Advanced manufacturing process for micro sytem fabrication Lecture 6
Link Advanced manufacturing process for micro sytem fabrication Lecture 7
Link Advanced manufacturing process for micro sytem fabrication Lecture 8
Link Advanced manufacturing process for micro sytem fabrication Lecture 9
Link Advanced manufacturing process for micro sytem fabrication Lecture 10
Link Advanced manufacturing process for micro sytem fabrication Lecture 11
Link Advanced manufacturing process for micro sytem fabrication Lecture 12
Link Advanced manufacturing process for micro sytem fabrication Lecture 13
Link Advanced manufacturing process for micro sytem fabrication Lecture 14
Link Advanced manufacturing process for micro sytem fabrication Lecture 15
Link Advanced manufacturing process for micro sytem fabrication Lecture 16
Link Advanced manufacturing process for micro sytem fabrication Lecture 17
Link Advanced manufacturing process for micro sytem fabrication Lecture 18
Link Advanced manufacturing process for micro sytem fabrication Lecture 19
Link Advanced manufacturing process for micro sytem fabrication Lecture 20
Link Advanced manufacturing process for micro sytem fabrication Lecture 21
Link Advanced manufacturing process for micro sytem fabrication Lecture 22
Link Advanced manufacturing process for micro sytem fabrication Lecture 23
Link Advanced manufacturing process for micro sytem fabrication Lecture 24
Link Advanced manufacturing process for micro sytem fabrication Lecture 25
Link Advanced manufacturing process for micro sytem fabrication Lecture 26
Link Advanced manufacturing process for micro sytem fabrication Lecture 27
Link Advanced manufacturing process for micro sytem fabrication Lecture 28
Link Advanced manufacturing process for micro sytem fabrication Lab session 1 - Advanced manufacturing process for micro sytem fabrication
Link Advanced manufacturing process for micro sytem fabrication Lab session 2 - EDM Micro Machening
Link Advanced manufacturing process for micro sytem fabrication Lab session 3 - EDM Micro Drilling
Link Advanced manufacturing process for micro sytem fabrication Lab session 4 - Laser Machening Process
Link Advanced manufacturing process for micro sytem fabrication Lab session 5 - Vaccume Assisted Forming
Link Advanced manufacturing process for micro sytem fabrication Lab session 6 - Vaccume Forming
Link Advanced manufacturing process for micro sytem fabrication Lab session 7 - Photolithiography
Link Advanced manufacturing process for micro sytem fabrication Lab session 8 - Replication part 1
Link Advanced manufacturing process for micro sytem fabrication Lab session 9 - Replication part 2
Link Advanced manufacturing process for micro sytem fabrication Lab session 10 - PCB Making
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 1 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 2 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 3 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 4 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 5 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 6 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 7 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 8 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 9 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 10 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 11 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 12 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 13 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 14 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 15 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 16 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 17 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 18 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 19 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 20 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 21 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 22 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 23 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 24 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 25 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 26 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 27 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lecture 28 - Technical Arts 101
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 1
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 2
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 3
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 4
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 5
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 6
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 7
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 8
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 9
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 10
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 11
Link Engineering Drawing (Dr. Anupam Saxena) Lab Session 12
Link NOC:BioMEMS and Microsystems Lecture 1 - Lecture 1
Link NOC:BioMEMS and Microsystems Lecture 2 - Lecture 2
Link NOC:BioMEMS and Microsystems Lecture 3 - Lecture 3
Link NOC:BioMEMS and Microsystems Lecture 4 - Review Lecture 1,2,3
Link NOC:BioMEMS and Microsystems Lecture 5 - Lecture 4
Link NOC:BioMEMS and Microsystems Lecture 6 - Lecture 5
Link NOC:BioMEMS and Microsystems Lecture 7 - Lecture 6
Link NOC:BioMEMS and Microsystems Lecture 8 - Review Lecture 4,5,6
Link NOC:BioMEMS and Microsystems Lecture 9 - Lecture 7
Link NOC:BioMEMS and Microsystems Lecture 10 - Lecture 8
Link NOC:BioMEMS and Microsystems Lecture 11 - Lecture 9-10
Link NOC:BioMEMS and Microsystems Lecture 12 - Lecture-11
Link NOC:BioMEMS and Microsystems Lecture 13 - Lecture-12
Link NOC:BioMEMS and Microsystems Lecture 14 - Lecture-13
Link NOC:BioMEMS and Microsystems Lecture 15 - Lecture-14
Link NOC:BioMEMS and Microsystems Lecture 16 - Lecture-15
Link NOC:BioMEMS and Microsystems Lecture 17 - Lecture-16
Link NOC:BioMEMS and Microsystems Lecture 18 - Lecture-17
Link NOC:BioMEMS and Microsystems Lecture 19 - Lecture-18
Link NOC:BioMEMS and Microsystems Lecture 20 - Lecture-19
Link NOC:BioMEMS and Microsystems Lecture 21 - Review Lecture 7 to 10
Link NOC:BioMEMS and Microsystems Lecture 22 - Review Lecture 11 to 13
Link NOC:BioMEMS and Microsystems Lecture 23 - Review Lecture 14 to 16
Link NOC:BioMEMS and Microsystems Lecture 24 - Lecture-20
Link NOC:BioMEMS and Microsystems Lecture 25 - Lecture-21
Link NOC:BioMEMS and Microsystems Lecture 26 - Lecture-22
Link NOC:BioMEMS and Microsystems Lecture 27 - Lecture-23
Link NOC:BioMEMS and Microsystems Lecture 28 - Lecture-24
Link NOC:BioMEMS and Microsystems Lecture 29 - Lecture-25
Link NOC:BioMEMS and Microsystems Lecture 30 - Review Lecture 17,18,19
Link NOC:BioMEMS and Microsystems Lecture 31 - Review Lecture 20,21,22
Link NOC:BioMEMS and Microsystems Lecture 32 - Lecture-26
Link NOC:BioMEMS and Microsystems Lecture 33 - Lecture-27
Link NOC:BioMEMS and Microsystems Lecture 34 - Lecture-28
Link NOC:BioMEMS and Microsystems Lecture 35 - Lecture-29
Link NOC:BioMEMS and Microsystems Lecture 36 - Lecture-30
Link NOC:BioMEMS and Microsystems Lecture 37 - Lecture-31
Link NOC:BioMEMS and Microsystems Lecture 38 - Lecture-32
Link NOC:BioMEMS and Microsystems Lecture 39 - Lecture-33
Link NOC:BioMEMS and Microsystems Lecture 40 - Review lecture 23,24,25
Link NOC:BioMEMS and Microsystems Lecture 41 - Review lecture 26,27,28
Link NOC:BioMEMS and Microsystems Lecture 42 - Review lecture 29 to 33
Link NOC:Manufacturing Systems Technology Lecture 1
Link NOC:Manufacturing Systems Technology Lecture 2
Link NOC:Manufacturing Systems Technology Lecture 3
Link NOC:Manufacturing Systems Technology Lecture 4
Link NOC:Manufacturing Systems Technology Lecture 5
Link NOC:Manufacturing Systems Technology Lecture 6
Link NOC:Manufacturing Systems Technology Lecture 7
Link NOC:Manufacturing Systems Technology Lecture 8
Link NOC:Manufacturing Systems Technology Lecture 9
Link NOC:Manufacturing Systems Technology Lecture 10
Link NOC:Manufacturing Systems Technology Lecture 11
Link NOC:Manufacturing Systems Technology Lecture 12
Link NOC:Manufacturing Systems Technology Lecture 13
Link NOC:Manufacturing Systems Technology Lecture 14
Link NOC:Manufacturing Systems Technology Lecture 15
Link NOC:Manufacturing Systems Technology Lecture 16
Link NOC:Manufacturing Systems Technology Lecture 17
Link NOC:Manufacturing Systems Technology Lecture 18
Link NOC:Manufacturing Systems Technology Lecture 19
Link NOC:Manufacturing Systems Technology Lecture 20
Link NOC:Manufacturing Systems Technology Lecture 21
Link NOC:Manufacturing Systems Technology Lecture 22
Link NOC:Manufacturing Systems Technology Lecture 23
Link NOC:Manufacturing Systems Technology Lecture 24
Link NOC:Manufacturing Systems Technology Lecture 25
Link NOC:Manufacturing Systems Technology Lecture 26
Link NOC:Manufacturing Systems Technology Lecture 27
Link NOC:Manufacturing Systems Technology Lecture 28
Link NOC:Manufacturing Systems Technology Lecture 29
Link NOC:Manufacturing Systems Technology Lecture 30
Link NOC:Manufacturing Systems Technology Lecture 31
Link NOC:Manufacturing Systems Technology Lecture 32
Link NOC:Manufacturing Systems Technology Lecture 33
Link NOC:Manufacturing Systems Technology Lecture 34
Link NOC:Manufacturing Systems Technology Lecture 35
Link NOC:Manufacturing Systems Technology Lecture 36
Link NOC:Manufacturing Systems Technology Lecture 37
Link NOC:Manufacturing Systems Technology Lecture 38
Link NOC:Manufacturing Systems Technology Lecture 39
Link NOC:Manufacturing Systems Technology Lecture 40
Link NOC:Manufacturing Systems Technology Lecture 41
Link NOC:Manufacturing Systems Technology Lecture 42
Link NOC:Manufacturing Systems Technology Lecture 43
Link NOC:Manufacturing Systems Technology Lecture 44
Link NOC:Manufacturing Systems Technology Lecture 45
Link NOC:Manufacturing Systems Technology Lecture 46
Link NOC:Manufacturing Systems Technology Lecture 47
Link NOC:Manufacturing Systems Technology Lecture 48
Link NOC:Manufacturing Systems Technology - Part II Lecture 1 - Introduction to Quality Engineering
Link NOC:Manufacturing Systems Technology - Part II Lecture 2 - Quality Costs
Link NOC:Manufacturing Systems Technology - Part II Lecture 3 - Product Design
Link NOC:Manufacturing Systems Technology - Part II Lecture 4 - Design of Experiments
Link NOC:Manufacturing Systems Technology - Part II Lecture 5 - Applications of Quality Loss Function
Link NOC:Manufacturing Systems Technology - Part II Lecture 6 - Product Selection Strategies
Link NOC:Manufacturing Systems Technology - Part II Lecture 7 - Robust Design Approaches
Link NOC:Manufacturing Systems Technology - Part II Lecture 8 - Taguchi's Method
Link NOC:Manufacturing Systems Technology - Part II Lecture 9 - Failure mode and effects analysis
Link NOC:Manufacturing Systems Technology - Part II Lecture 10 - Problem Solving : Failure mode and effects analysis - 1
Link NOC:Manufacturing Systems Technology - Part II Lecture 11 - Problem solving : Failure mode and effects analysis - 2
Link NOC:Manufacturing Systems Technology - Part II Lecture 12 - Product quality improvement methods
Link NOC:Manufacturing Systems Technology - Part II Lecture 13 - Quality tools - Part 1
Link NOC:Manufacturing Systems Technology - Part II Lecture 14 - Quality Tools - Part 2
Link NOC:Manufacturing Systems Technology - Part II Lecture 15 - Different types of control charts
Link NOC:Manufacturing Systems Technology - Part II Lecture 16 - Mean, Variance and Standard deviation
Link NOC:Manufacturing Systems Technology - Part II Lecture 17 - X bar chart, R-chart
Link NOC:Manufacturing Systems Technology - Part II Lecture 18 - Plotting methods for control charts
Link NOC:Manufacturing Systems Technology - Part II Lecture 19 - Six Sigma - Part 1
Link NOC:Manufacturing Systems Technology - Part II Lecture 20 - Six Sigma - Part 2
Link NOC:Manufacturing Systems Technology - Part II Lecture 21 - Theory of probability
Link NOC:Manufacturing Systems Technology - Part II Lecture 22 - Determining the defective products using Probability
Link NOC:Manufacturing Systems Technology - Part II Lecture 23 - Sampling based on Permutations and Combinations
Link NOC:Manufacturing Systems Technology - Part II Lecture 24 - Bionomial distribution
Link NOC:Manufacturing Systems Technology - Part II Lecture 25 - Poisson distribution
Link NOC:Manufacturing Systems Technology - Part II Lecture 26 - Poisson distribution
Link NOC:Manufacturing Systems Technology - Part II Lecture 27 - Normal Distribution
Link NOC:Manufacturing Systems Technology - Part II Lecture 28 - Overview of control charts and different types of distribution
Link NOC:Manufacturing Systems Technology - Part II Lecture 29 - Fundamental of Robotics and its applications in Automated Systems
Link NOC:Manufacturing Systems Technology - Part II Lecture 30 - Joint configuration systems of Robot
Link NOC:Basics of Finite Element Analysis Lecture 1 - Introduction to Finite Element Analysis(FEA)
Link NOC:Basics of Finite Element Analysis Lecture 2 - Introduction of FEA, Nodes, Elements and Shape Functions
Link NOC:Basics of Finite Element Analysis Lecture 3 - Nodes, Elements and Shape Functions
Link NOC:Basics of Finite Element Analysis Lecture 4 - Polynomials as Shape Functions, Weighted Residuals, Elements and Assembly Level Equations
Link NOC:Basics of Finite Element Analysis Lecture 5 - Types of Errors in FEA, Overall FEA Process and Convergence
Link NOC:Basics of Finite Element Analysis Lecture 6 - Strengths of FE Method, Continuity conditions at Interfaces
Link NOC:Basics of Finite Element Analysis Lecture 7 - Key concepts and terminologies
Link NOC:Basics of Finite Element Analysis Lecture 8 - Weighted integral statements
Link NOC:Basics of Finite Element Analysis Lecture 9 - Integration by parts - Review
Link NOC:Basics of Finite Element Analysis Lecture 10 - Gradient and Divergence Theorems-Part - I
Link NOC:Basics of Finite Element Analysis Lecture 11 - Gradient and Divergence Theorems Part - II
Link NOC:Basics of Finite Element Analysis Lecture 12 - Functionals
Link NOC:Basics of Finite Element Analysis Lecture 13 - Variational Operator
Link NOC:Basics of Finite Element Analysis Lecture 14 - Weighted Integral and Weak Formulation
Link NOC:Basics of Finite Element Analysis Lecture 15 - Weak Formulation
Link NOC:Basics of Finite Element Analysis Lecture 16 - Weak Formulation and Weighted Integral : Principle of minimum potential energy
Link NOC:Basics of Finite Element Analysis Lecture 17 - Variational Methods : Rayleigh Ritz Method
Link NOC:Basics of Finite Element Analysis Lecture 18 - Rayleigh Ritz Method
Link NOC:Basics of Finite Element Analysis Lecture 19 - Method of Weighted Residuals
Link NOC:Basics of Finite Element Analysis Lecture 20 - Different types of Weighted Residual Methods - Part I
Link NOC:Basics of Finite Element Analysis Lecture 21 - Different types of Weighted Residual Methods - Part II
Link NOC:Basics of Finite Element Analysis Lecture 22 - FEA formulation for 2nd order BVP - Part I
Link NOC:Basics of Finite Element Analysis Lecture 23 - FEA formulation for 2nd order BVP - Part II
Link NOC:Basics of Finite Element Analysis Lecture 24 - Element Level Equations
Link NOC:Basics of Finite Element Analysis Lecture 25 - 2nd Order Boundary Value Problem
Link NOC:Basics of Finite Element Analysis Lecture 26 - Assembly of element equations
Link NOC:Basics of Finite Element Analysis Lecture 27 - Assembly of element equations and implementation of boundary conditions
Link NOC:Basics of Finite Element Analysis Lecture 28 - Assembly process and the connectivity matrix
Link NOC:Basics of Finite Element Analysis Lecture 29 - Radially Symmetric Problems
Link NOC:Basics of Finite Element Analysis Lecture 30 - One dimensional heat transfer
Link NOC:Basics of Finite Element Analysis Lecture 31 - 1D-Heat conduction with convective effects : examples
Link NOC:Basics of Finite Element Analysis Lecture 32 - Euler-Bernoulli beam
Link NOC:Basics of Finite Element Analysis Lecture 33 - Interpolation functions for Euler-Bernoulli beam
Link NOC:Basics of Finite Element Analysis Lecture 34 - Finite element equations for Euler-Bernoulli beam
Link NOC:Basics of Finite Element Analysis Lecture 35 - Assembly equations for Euler-Bernoulli beam
Link NOC:Basics of Finite Element Analysis Lecture 36 - Boundary conditions for Euler-Bernoulli beam
Link NOC:Basics of Finite Element Analysis Lecture 37 - Shear deformable beams
Link NOC:Basics of Finite Element Analysis Lecture 38 - Finite element formulation for shear deformable beams : Part - I
Link NOC:Basics of Finite Element Analysis Lecture 39 - Finite element formulation for shear deformable beams : Part - II
Link NOC:Basics of Finite Element Analysis Lecture 40 - Equal interpolation but reduced integration element
Link NOC:Basics of Finite Element Analysis Lecture 41 - Eigenvalue problems
Link NOC:Basics of Finite Element Analysis Lecture 42 - Eigenvalue problems : examples
Link NOC:Basics of Finite Element Analysis Lecture 43 - Introduction to time dependent problems
Link NOC:Basics of Finite Element Analysis Lecture 44 - Spatial approximation
Link NOC:Basics of Finite Element Analysis Lecture 45 - Temporal approximation for parabolic problems : Part - I
Link NOC:Basics of Finite Element Analysis Lecture 46 - Temporal approximation for parabolic problems : Part - II
Link NOC:Basics of Finite Element Analysis Lecture 47 - Temporal approximation for hyperbolic problems
Link NOC:Basics of Finite Element Analysis Lecture 48 - Explicit and implicit method, diagonalization of mass matrix, closure
Link NOC:Basics of Noise and Its Measurements Lecture 1 - Introduction
Link NOC:Basics of Noise and Its Measurements Lecture 2 - Vibration versus Waves
Link NOC:Basics of Noise and Its Measurements Lecture 3 - Nature of Sound
Link NOC:Basics of Noise and Its Measurements Lecture 4 - The Decibel Scale
Link NOC:Basics of Noise and Its Measurements Lecture 5 - Some Key Terms
Link NOC:Basics of Noise and Its Measurements Lecture 6 - Adding Decibels
Link NOC:Basics of Noise and Its Measurements Lecture 7 - Modeling Sound Propagation
Link NOC:Basics of Noise and Its Measurements Lecture 8 - The Momentum Equation
Link NOC:Basics of Noise and Its Measurements Lecture 9 - The Continuity Equation and The Gas Law
Link NOC:Basics of Noise and Its Measurements Lecture 10 - 1-D Wave Equation
Link NOC:Basics of Noise and Its Measurements Lecture 11 - General Solution for 1-D Wave Equation
Link NOC:Basics of Noise and Its Measurements Lecture 12 - Complex Time Signal and Transfer Functions
Link NOC:Basics of Noise and Its Measurements Lecture 13 - Transmission line equations
Link NOC:Basics of Noise and Its Measurements Lecture 14 - Planar Waves in Closed Tubes
Link NOC:Basics of Noise and Its Measurements Lecture 15 - Planar Waves in 1-D Open Tubes
Link NOC:Basics of Noise and Its Measurements Lecture 16 - A Semi-Infinite Tube and Overall Summary
Link NOC:Basics of Noise and Its Measurements Lecture 17 - 1-D Tubes with Imperfect Terminations
Link NOC:Basics of Noise and Its Measurements Lecture 18 - Measuring Impedance Through Kundt’s Apparatus
Link NOC:Basics of Noise and Its Measurements Lecture 19 - Classification of Microphones
Link NOC:Basics of Noise and Its Measurements Lecture 20 - Classification of Microphones - Continuation
Link NOC:Basics of Noise and Its Measurements Lecture 21 - Classification of Microphones by Application
Link NOC:Basics of Noise and Its Measurements Lecture 22 - Microphone Sensitivity
Link NOC:Basics of Noise and Its Measurements Lecture 23 - Microphone Sensitivity- Continuation
Link NOC:Basics of Noise and Its Measurements Lecture 24 - Selecting the Right Microphone
Link NOC:Basics of Noise and Its Measurements Lecture 25 - Fourier Series Expansion
Link NOC:Basics of Noise and Its Measurements Lecture 26 - Fourier Series Expansion - Continuation
Link NOC:Basics of Noise and Its Measurements Lecture 27 - Fourier Integral
Link NOC:Basics of Noise and Its Measurements Lecture 28 - Fourier Integral - Continuation
Link NOC:Basics of Noise and Its Measurements Lecture 29 - Fourier Transform
Link NOC:Basics of Noise and Its Measurements Lecture 30 - Fourier Transform - Continuation
Link NOC:Basics of Noise and Its Measurements Lecture 31 - Discrete Fourier Transform (DFT)
Link NOC:Basics of Noise and Its Measurements Lecture 32 - Discrete Fourier Transform (DFT) - Continuation
Link NOC:Basics of Noise and Its Measurements Lecture 33 - DFT - Calculating Frequencies and Padding
Link NOC:Basics of Noise and Its Measurements Lecture 34 - DFT - Influence of Duration and Sampling frequency on resolution
Link NOC:Basics of Noise and Its Measurements Lecture 35 - FFT and Inverse FFT
Link NOC:Basics of Noise and Its Measurements Lecture 36 - Considerations while deciding instrumentation
Link NOC:Basics of Noise and Its Measurements Lecture 37 - Considerations while selecting instruments for noise measurements
Link NOC:Basics of Noise and Its Measurements Lecture 38 - Measuring impedance through two microphone method
Link NOC:Basics of Noise and Its Measurements Lecture 39 - Designing an impedance measurement tube
Link NOC:Basics of Noise and Its Measurements Lecture 40 - Octave band analysis
Link NOC:Basics of Noise and Its Measurements Lecture 41 - Calculating results in octave bands
Link NOC:Basics of Noise and Its Measurements Lecture 42 - Weighting
Link NOC:Basics of Noise and Its Measurements Lecture 43 - Short time Fourier transforms (STFT)
Link NOC:Basics of Noise and Its Measurements Lecture 44 - Spectrograms
Link NOC:Basics of Noise and Its Measurements Lecture 45 - Reverberation time
Link NOC:Basics of Noise and Its Measurements Lecture 46 - Anechoic rooms
Link NOC:Basics of Noise and Its Measurements Lecture 47 - STC, NRC and sound attenuation
Link NOC:Basics of Noise and Its Measurements Lecture 48 - Reverberant rooms
Link NOC:Manufacturing Process Technology - Part I Lecture 1 - Introduction to Manufacturing Process Tecnology
Link NOC:Manufacturing Process Technology - Part I Lecture 2 - Structure of Matter (Bonding of Solids,Crystal Structures)
Link NOC:Manufacturing Process Technology - Part I Lecture 3 - Brief introduction of non-conventional machining processes
Link NOC:Manufacturing Process Technology - Part I Lecture 4 - Structure of matters (bonding of solids, crystal structures)
Link NOC:Manufacturing Process Technology - Part I Lecture 5 - Elastic and Plastic Deformation
Link NOC:Manufacturing Process Technology - Part I Lecture 6 - Crystal imperfaction and dislocation
Link NOC:Manufacturing Process Technology - Part I Lecture 7 - Plastic Deformation
Link NOC:Manufacturing Process Technology - Part I Lecture 8 - Material Properties, Stress Strain Diagram for differnt types of materials
Link NOC:Manufacturing Process Technology - Part I Lecture 9 - Friction and Wear, Solid solutions
Link NOC:Manufacturing Process Technology - Part I Lecture 10 - Equilibrium Phase Diagram
Link NOC:Manufacturing Process Technology - Part I Lecture 11 - Iron-carbon equilibrium phase diagram
Link NOC:Manufacturing Process Technology - Part I Lecture 12 - Control of material properties (Alloying and heat treatment), Mechanical properties and Recrystallization
Link NOC:Manufacturing Process Technology - Part I Lecture 13 - Introduction To Casting Process
Link NOC:Manufacturing Process Technology - Part I Lecture 14 - Pattern and Mold Design
Link NOC:Manufacturing Process Technology - Part I Lecture 15 - Mold Making Procedures
Link NOC:Manufacturing Process Technology - Part I Lecture 16 - Fundamentals of Melting and Furnaces & Pouring and Gating Design
Link NOC:Manufacturing Process Technology - Part I Lecture 17 - Vertical and Bottom Gating Systems Edit Lesson
Link NOC:Manufacturing Process Technology - Part I Lecture 18 - Numerical Estimation To Find Mold Filling Time and Mold Design
Link NOC:Manufacturing Process Technology - Part I Lecture 19 - Effects of friction and velocity distribution in time of filling
Link NOC:Manufacturing Process Technology - Part I Lecture 20 - Numerical design of gating systems using frictional and bending losses
Link NOC:Manufacturing Process Technology - Part I Lecture 21 - Principle of cooling and solidification in single and multiphase systems
Link NOC:Manufacturing Process Technology - Part I Lecture 22 - Estimation of rate of solidification
Link NOC:Manufacturing Process Technology - Part I Lecture 23 - Principles of cooling and solidification of casting
Link NOC:Manufacturing Process Technology - Part I Lecture 24 - Modeling of Solidification Rates of Thin Casting in a Metal Mold
Link NOC:Manufacturing Process Technology - Part I Lecture 25 - Solidification with Predominant Interface Resistance
Link NOC:Manufacturing Process Technology - Part I Lecture 26 - Solidification with Constant Casting Surface Temperature
Link NOC:Manufacturing Process Technology - Part I Lecture 27 - Solidification of Casting with Predominant Resistance in Mold and Solidified Metal
Link NOC:Manufacturing Process Technology - Part I Lecture 28 - Solidification Time for Permanent Mold Casting
Link NOC:Manufacturing Process Technology - Part I Lecture 29 - Solidification with Constant Casting Surface
Link NOC:Manufacturing Process Technology - Part I Lecture 30 - Riser Design and Placement - Part 1
Link NOC:Manufacturing Process Technology - Part I Lecture 31 - Riser Design and Placement - Part 2
Link NOC:Manufacturing Process Technology - Part I Lecture 32 - Riser Design and Placement - Part 3
Link NOC:Manufacturing Process Technology - Part I Lecture 33 - Introduction of Machining Processes
Link NOC:Manufacturing Process Technology - Part I Lecture 34 - Review of Basic Machining Processes and the Mechanics of Chip Formation
Link NOC:Manufacturing Process Technology - Part I Lecture 35 - Estimation of Cutting Ratio and Shear Angle
Link NOC:Manufacturing Process Technology - Part I Lecture 36 - Merchant's Force Analysis
Link NOC:Manufacturing Process Technology - Part I Lecture 37 - Merchant Theory (Cutting Forces Analysis)
Link NOC:Manufacturing Process Technology - Part I Lecture 38 - Merchant Theory (Force analysis) Part-2
Link NOC:Manufacturing Process Technology - Part I Lecture 39 - Lee Shaffer's Solution
Link NOC:Manufacturing Process Technology - Part I Lecture 40 - Specific Energy Model for Cutting
Link NOC:Manufacturing Process Technology - Part I Lecture 41 - Modeling of Heat Generation and Cutting Tool Temperature
Link NOC:Manufacturing Process Technology - Part I Lecture 42 - Temperature in Cutting and Builtup Edge Formation
Link NOC:Manufacturing Process Technology - Part I Lecture 43 - Metal Cutting Operation
Link NOC:Manufacturing Process Technology - Part I Lecture 44 - Tool life and Tool wear
Link NOC:Manufacturing Process Technology - Part I Lecture 45 - Economics of Machining
Link NOC:Manufacturing Process Technology - Part I Lecture 46 - Joining Process
Link NOC:Manufacturing Process Technology - Part I Lecture 47 - Principle of Solid State Welding
Link NOC:Manufacturing Process Technology - Part I Lecture 48 - Numerical Design of Welding Power Sources in Arc Welding
Link Manufacturing Systems Technology - I and II Lecture 1 - Introduction to Manufacturing Process Tecnology
Link Manufacturing Systems Technology - I and II Lecture 2 - Structure of Matter (Bonding of Solids, Crystal Structures)
Link Manufacturing Systems Technology - I and II Lecture 3 - Brief introduction of non-conventional machining processes
Link Manufacturing Systems Technology - I and II Lecture 4 - Structure of matters (bonding of solids, crystal structures)
Link Manufacturing Systems Technology - I and II Lecture 5 - Elastic and Plastic Deformation
Link Manufacturing Systems Technology - I and II Lecture 6 - Crystal imperfaction and dislocation
Link Manufacturing Systems Technology - I and II Lecture 7 - Plastic Deformation
Link Manufacturing Systems Technology - I and II Lecture 8 - Material Properties, Stress Strain Diagram for differnt types of materials
Link Manufacturing Systems Technology - I and II Lecture 9 - Friction and Wear, Solid solutions
Link Manufacturing Systems Technology - I and II Lecture 10 - Equilibrium Phase Diagram
Link Manufacturing Systems Technology - I and II Lecture 11 - Iron-carbon equilibrium phase diagram
Link Manufacturing Systems Technology - I and II Lecture 12 - Control of material properties, Mechanical properties and Recrystallization
Link Manufacturing Systems Technology - I and II Lecture 13 - Introduction To Casting Process
Link Manufacturing Systems Technology - I and II Lecture 14 - Pattern and Mold Design
Link Manufacturing Systems Technology - I and II Lecture 15 - Mold Making Procedures
Link Manufacturing Systems Technology - I and II Lecture 16 - Fundamentals of Melting and Furnaces and Pouring and Gating Design
Link Manufacturing Systems Technology - I and II Lecture 17 - Vertical and Bottom Gating Systems Edit Lesson
Link Manufacturing Systems Technology - I and II Lecture 18 - Numerical Estimation To Find Mold Filling Time and Mold Design
Link Manufacturing Systems Technology - I and II Lecture 19 - Effects of friction and velocity distribution in time of filling
Link Manufacturing Systems Technology - I and II Lecture 20 - Numerical design of gating systems using frictional and bending losses
Link Manufacturing Systems Technology - I and II Lecture 21 - Principle of cooling and solidification in single and multiphase systems
Link Manufacturing Systems Technology - I and II Lecture 22 - Estimation of rate of solidification
Link Manufacturing Systems Technology - I and II Lecture 23 - Principles of cooling and solidification of casting
Link Manufacturing Systems Technology - I and II Lecture 24 - Modeling of Solidification Rates of Thin Casting in a Metal Mold
Link Manufacturing Systems Technology - I and II Lecture 25 - Solidification with Predominant Interface Resistance
Link Manufacturing Systems Technology - I and II Lecture 26 - Solidification with Constant Casting Surface Temperature
Link Manufacturing Systems Technology - I and II Lecture 27 - Solidification of Casting with Predominant Resistance in Mold and Solidified Metal
Link Manufacturing Systems Technology - I and II Lecture 28 - Solidification Time for Permanent Mold Casting
Link Manufacturing Systems Technology - I and II Lecture 29 - Solidification with Constant Casting Surface
Link Manufacturing Systems Technology - I and II Lecture 30 - Riser Design and Placement - Part 1
Link Manufacturing Systems Technology - I and II Lecture 31 - Riser Design and Placement - Part 2
Link Manufacturing Systems Technology - I and II Lecture 32 - Riser Design and Placement - Part 3
Link Manufacturing Systems Technology - I and II Lecture 33 - Introduction of Machining Processes
Link Manufacturing Systems Technology - I and II Lecture 34 - Review of Basic Machining Processes and the Mechanics of Chip Formation
Link Manufacturing Systems Technology - I and II Lecture 35 - Estimation of Cutting Ratio and Shear Angle
Link Manufacturing Systems Technology - I and II Lecture 36 - Merchant's Force Analysis
Link Manufacturing Systems Technology - I and II Lecture 37 - Merchant Theory (Cutting Forces Analysis)
Link Manufacturing Systems Technology - I and II Lecture 38 - Merchant Theory (Force analysis) - Part 2
Link Manufacturing Systems Technology - I and II Lecture 39 - Lee Shaffer's Solution
Link Manufacturing Systems Technology - I and II Lecture 40 - Specific Energy Model for Cutting
Link Manufacturing Systems Technology - I and II Lecture 41 - Modeling of Heat Generation and Cutting Tool Temperature
Link Manufacturing Systems Technology - I and II Lecture 42 - Temperature in Cutting and Builtup Edge Formation
Link Manufacturing Systems Technology - I and II Lecture 43 - Metal Cutting Operation
Link Manufacturing Systems Technology - I and II Lecture 44 - Tool life and Tool wear
Link Manufacturing Systems Technology - I and II Lecture 45 - Economics of Machining
Link Manufacturing Systems Technology - I and II Lecture 46 - Joining Process
Link Manufacturing Systems Technology - I and II Lecture 47 - Principle of Solid State Welding
Link Manufacturing Systems Technology - I and II Lecture 48 - Numerical Design of Welding Power Sources in Arc Welding
Link Manufacturing Systems Technology - I and II Lecture 49 - Modes of metal transfer in arc welding
Link Manufacturing Systems Technology - I and II Lecture 50 - Metal forming Processes Edit Lesson
Link Manufacturing Systems Technology - I and II Lecture 51 - Yield Criterion used in Metal Forming Processes Edit Lesson
Link Manufacturing Systems Technology - I and II Lecture 52 - Concept of Principal stress, strain
Link Manufacturing Systems Technology - I and II Lecture 53 - Trescas' Yield criteria and Rolling Process
Link Manufacturing Systems Technology - I and II Lecture 54 - Rolling Processes - Part 1
Link Manufacturing Systems Technology - I and II Lecture 55 - Rolling Processes - Part 2
Link Manufacturing Systems Technology - I and II Lecture 56 - Introduction to Advanced Machining Processes
Link Manufacturing Systems Technology - I and II Lecture 57 - Classification of Machining Processes
Link Manufacturing Systems Technology - I and II Lecture 58 - Silicon growth and Crystallography
Link Manufacturing Systems Technology - I and II Lecture 59 - Micro Fabrication Technology
Link Manufacturing Systems Technology - I and II Lecture 60 - Photolithography
Link Manufacturing Systems Technology - I and II Lecture 61 - Soft Lithography
Link Manufacturing Systems Technology - I and II Lecture 62 - Introduction to Wet Etching Techniques
Link Manufacturing Systems Technology - I and II Lecture 63 - Introduction to Dry Etching Techniques
Link Manufacturing Systems Technology - I and II Lecture 64 - Introduction to Abrasive Jet Machining Process
Link Manufacturing Systems Technology - I and II Lecture 65 - Ultrasonic Machining Process
Link Manufacturing Systems Technology - I and II Lecture 66 - Determination of MRR of Ultrasonic Machining Process
Link Manufacturing Systems Technology - I and II Lecture 67 - Mechanics of Ultrasonic Machining (USM)
Link Manufacturing Systems Technology - I and II Lecture 68 - Effect of Process parameters of USM
Link Manufacturing Systems Technology - I and II Lecture 69 - Ultrasonic Machining Unit
Link Manufacturing Systems Technology - I and II Lecture 70 - Introductions of Electro-chemical Drilling Process
Link Manufacturing Systems Technology - I and II Lecture 71 - Electric Discharge Machining Process
Link Manufacturing Systems Technology - I and II Lecture 72 - EDM - Part 2
Link Manufacturing Systems Technology - I and II Lecture 73 - Effect of various process parameters on EDM process
Link Manufacturing Systems Technology - I and II Lecture 74 - Analysis of RC circuit for EDM
Link Manufacturing Systems Technology - I and II Lecture 75 - Electrodischarge machining sytem
Link Manufacturing Systems Technology - I and II Lecture 76 - Effect of various parameters on EDM Process
Link Manufacturing Systems Technology - I and II Lecture 77 - Tool Electrodes and Dielectric fluids and Electron Beam Machining
Link Manufacturing Systems Technology - I and II Lecture 78 - Introduction to Finishing Process
Link Manufacturing Systems Technology - I and II Lecture 79 - Electrochemical Machining Processes (ECM)
Link Manufacturing Systems Technology - I and II Lecture 80 - Material Removal Rate of ECM
Link Manufacturing Systems Technology - I and II Lecture 81 - Electrode Double Layer
Link Manufacturing Systems Technology - I and II Lecture 82 - Material removal rate of an alloy in ECM
Link Manufacturing Systems Technology - I and II Lecture 83 - Kinematics and Dynamics of ECM
Link Manufacturing Systems Technology - I and II Lecture 84 - Temperature and Pressure rise during ECM
Link Manufacturing Systems Technology - I and II Lecture 85 - Determination of Electrolyte flow velocity in ECM
Link Manufacturing Systems Technology - I and II Lecture 86 - Theoretical determination of Tool shape
Link Manufacturing Systems Technology - I and II Lecture 87 - Design for Electrolyte flow in ECM
Link Manufacturing Systems Technology - I and II Lecture 88 - Mechanics of Electron Beam Machining Process
Link Manufacturing Systems Technology - I and II Lecture 89 - Functional Characteristics of EBM Process Edit Lesson
Link Manufacturing Systems Technology - I and II Lecture 90 - Introduction of Laser Beam Machining Process
Link Manufacturing Systems Technology - I and II Lecture 91 - Material removal rate of LBM
Link Manufacturing Systems Technology - I and II Lecture 92 - Heat conduction and Temperature rise during LBM
Link Manufacturing Systems Technology - I and II Lecture 93 - Modelling of LBM processes
Link Manufacturing Systems Technology - I and II Lecture 94 - Introduction of Additive Techniques
Link Manufacturing Systems Technology - I and II Lecture 95 - Additive Manufacturing Processes
Link Manufacturing Systems Technology - I and II Lecture 96 - Fused Deposition Modeling Process
Link NOC:Nature and Property of Materials Lecture 1 - History and Evolution of Materials
Link NOC:Nature and Property of Materials Lecture 2 - Classification of Materials
Link NOC:Nature and Property of Materials Lecture 3 - Advanced and Exotic Materials
Link NOC:Nature and Property of Materials Lecture 4 - Mechanical Properties of Materials - I
Link NOC:Nature and Property of Materials Lecture 5 - Mechanical Properties of Materials - II
Link NOC:Nature and Property of Materials Lecture 6 - Mechanical Properties of Materials - III
Link NOC:Nature and Property of Materials Lecture 7 - Bonding between atoms
Link NOC:Nature and Property of Materials Lecture 8 - The Role of Crystal Structure - I
Link NOC:Nature and Property of Materials Lecture 9 - The Role of Crystal Structure - II
Link NOC:Nature and Property of Materials Lecture 10 - The Role of Crystal Structure - III
Link NOC:Nature and Property of Materials Lecture 11 - Metals - I (Ferrous alloys)
Link NOC:Nature and Property of Materials Lecture 12 - Metals - II (Non-Ferrous alloys)
Link NOC:Nature and Property of Materials Lecture 13 - Metals - III (Strengthening and Degradation)
Link NOC:Nature and Property of Materials Lecture 14 - Ceramics - I
Link NOC:Nature and Property of Materials Lecture 15 - Ceramics - II
Link NOC:Nature and Property of Materials Lecture 16 - Polymers : Introduction and Classification
Link NOC:Nature and Property of Materials Lecture 17 - Polymeric Structure
Link NOC:Nature and Property of Materials Lecture 18 - Effects of Glass transition temperature
Link NOC:Nature and Property of Materials Lecture 19 - Polymer Mechanical properties
Link NOC:Nature and Property of Materials Lecture 20 - Composites - I
Link NOC:Nature and Property of Materials Lecture 21 - Composites - II
Link NOC:Nature and Property of Materials Lecture 22 - Composites - III
Link NOC:Nature and Property of Materials Lecture 23 - Smart Materials - I (Introduction)
Link NOC:Nature and Property of Materials Lecture 24 - Smart Materials - II (Piezoelectricity)
Link NOC:Nature and Property of Materials Lecture 25 - Smart Materials - III (Magnetostriction)
Link NOC:Nature and Property of Materials Lecture 26 - Smart Materials - IV (Smart Polymers)
Link NOC:Nature and Property of Materials Lecture 27 - Smart Materials - V (SMA)
Link NOC:Nature and Property of Materials Lecture 28 - Materials Selection in Engineering Design
Link NOC:Nature and Property of Materials Lecture 29 - Numerical: Cantilever beam (High stiffness and light weight)
Link NOC:Nature and Property of Materials Lecture 30 - Numerical: Cantilever beam (High strength and light weight)
Link NOC:Nature and Property of Materials Lecture 31 - Numerical: Connecting rod
Link NOC:Nature and Property of Materials Lecture 32 - Numerical: Probe for scanning probe microscope
Link NOC:Nature and Property of Materials Lecture 33 - Optical Properties
Link NOC:Nature and Property of Materials Lecture 34 - Optical Fiber
Link NOC:Nature and Property of Materials Lecture 35 - Thermal Properties
Link NOC:Nature and Property of Materials Lecture 36 - Numerical: Material selection for Heat exchanger
Link NOC:Nature and Property of Materials Lecture 37 - Electric Properties - I
Link NOC:Nature and Property of Materials Lecture 38 - Electric Properties - II
Link NOC:Nature and Property of Materials Lecture 39 - Magnetic Properties
Link NOC:Nature and Property of Materials Lecture 40 - Laboratory demonstration
Link NOC:Manufacturing Process Technology - Part II Lecture 1 - Introduction to Advanced Machining Processes
Link NOC:Manufacturing Process Technology - Part II Lecture 2 - Classification of Machining Processes
Link NOC:Manufacturing Process Technology - Part II Lecture 3 - Silicon growth and Crystallography
Link NOC:Manufacturing Process Technology - Part II Lecture 4 - Micro Fabrication Technology
Link NOC:Manufacturing Process Technology - Part II Lecture 5 - Photolithography
Link NOC:Manufacturing Process Technology - Part II Lecture 6 - Soft Lithography
Link NOC:Manufacturing Process Technology - Part II Lecture 7 - Introduction to Wet Etching Techniques
Link NOC:Manufacturing Process Technology - Part II Lecture 8 - Introduction to Dry Etching Techniques
Link NOC:Manufacturing Process Technology - Part II Lecture 9 - Introduction of Additive Techniques
Link NOC:Manufacturing Process Technology - Part II Lecture 10 - Introduction to Abrasive Jet Machining Process
Link NOC:Manufacturing Process Technology - Part II Lecture 11 - Ultrasonic Machining Process
Link NOC:Manufacturing Process Technology - Part II Lecture 12 - Determination of MRR of Ultrasonic Machining Process
Link NOC:Manufacturing Process Technology - Part II Lecture 13 - Mechanics of Ultrasonic Machining (USM)
Link NOC:Manufacturing Process Technology - Part II Lecture 14 - Effect of Process parameters of USM
Link NOC:Manufacturing Process Technology - Part II Lecture 15 - Ultrasonic Machining Unit
Link NOC:Manufacturing Process Technology - Part II Lecture 16 - Electrochemical Machining Processes (ECM)
Link NOC:Manufacturing Process Technology - Part II Lecture 17 - Material Removal Rate of ECM
Link NOC:Manufacturing Process Technology - Part II Lecture 18 - Electrode Double Layer
Link NOC:Manufacturing Process Technology - Part II Lecture 19 - Material removal rate of an alloy in ECM
Link NOC:Manufacturing Process Technology - Part II Lecture 20 - Kinematics and Dynamics of ECM
Link NOC:Manufacturing Process Technology - Part II Lecture 21 - Temperature and Pressure rise during ECM
Link NOC:Manufacturing Process Technology - Part II Lecture 22 - Determination of Electrolyte flow velocity in ECM
Link NOC:Manufacturing Process Technology - Part II Lecture 23 - Effect of heat and Hydrogen bubble generation during ECM Process
Link NOC:Manufacturing Process Technology - Part II Lecture 24 - Theoretical determination of Tool shape
Link NOC:Manufacturing Process Technology - Part II Lecture 25 - Design for Electrolyte flow in ECM
Link NOC:Manufacturing Process Technology - Part II Lecture 26 - Introductions of Electro-chemical Drilling Process
Link NOC:Manufacturing Process Technology - Part II Lecture 27 - Introduction to Finishing Process
Link NOC:Manufacturing Process Technology - Part II Lecture 28 - Electric Discharge Machining Process
Link NOC:Manufacturing Process Technology - Part II Lecture 29 - EDM part-2
Link NOC:Manufacturing Process Technology - Part II Lecture 30 - Effect of various process parameters on EDM process
Link NOC:Manufacturing Process Technology - Part II Lecture 31 - Analysis of RC circuit for EDM
Link NOC:Manufacturing Process Technology - Part II Lecture 32 - Electrodischarge machining sytem
Link NOC:Manufacturing Process Technology - Part II Lecture 33 - Effect of various parameters on EDM Process
Link NOC:Manufacturing Process Technology - Part II Lecture 34 - Tool Electrodes and Dielectric fluids and Electron Beam Machining
Link NOC:Manufacturing Process Technology - Part II Lecture 35 - Mechanics of Electron Beam Machining Process
Link NOC:Manufacturing Process Technology - Part II Lecture 36 - Functional Characteristics of EBM Process Edit Lesson
Link NOC:Manufacturing Process Technology - Part II Lecture 37 - Introduction of Laser Beam Machining Process
Link NOC:Manufacturing Process Technology - Part II Lecture 38 - Material removal rate of LBM
Link NOC:Manufacturing Process Technology - Part II Lecture 39 - Heat conduction and Temperature rise during LBM
Link NOC:Manufacturing Process Technology - Part II Lecture 40 - Modelling of LBM processes
Link NOC:Manufacturing Process Technology - Part II Lecture 41 - Metal forming Processes Edit Lesson
Link NOC:Manufacturing Process Technology - Part II Lecture 42 - Yield Criterion used in Metal Forming Processes Edit Lesson
Link NOC:Manufacturing Process Technology - Part II Lecture 43 - Concept of Principal stress, strain
Link NOC:Manufacturing Process Technology - Part II Lecture 44 - Trescas' Yield criteria and Rolling Process
Link NOC:Manufacturing Process Technology - Part II Lecture 45 - Rolling Processes - Part 1
Link NOC:Manufacturing Process Technology - Part II Lecture 46 - Rolling Processes - Part 2
Link NOC:Manufacturing Process Technology - Part II Lecture 47 - Additive Manufacturing Processes
Link NOC:Manufacturing Process Technology - Part II Lecture 48 - Fused Deposition Modeling Process
Link NOC:Basics of Finite Element Analysis - II Lecture 1 - Overview of the Course
Link NOC:Basics of Finite Element Analysis - II Lecture 2 - Fundamental principles
Link NOC:Basics of Finite Element Analysis - II Lecture 3 - Steps followed in FEA
Link NOC:Basics of Finite Element Analysis - II Lecture 4 - Weak Formulation
Link NOC:Basics of Finite Element Analysis - II Lecture 5 - Weak Formulation : Example Problem
Link NOC:Basics of Finite Element Analysis - II Lecture 6 - Assembling element level equations
Link NOC:Basics of Finite Element Analysis - II Lecture 7 - Errors in FEA Solution
Link NOC:Basics of Finite Element Analysis - II Lecture 8 - Measures of Errors in FEA Solution
Link NOC:Basics of Finite Element Analysis - II Lecture 9 - Convergence and Accuracy of Solution - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 10 - Convergence and Accuracy of Solution - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 11 - Convergence - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 12 - Convergence - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 13 - Numerical Integration Schemes - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 14 - Numerical Integration Schemes - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 15 - Approximations - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 16 - Approximations - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 17 - Approximations - Part III
Link NOC:Basics of Finite Element Analysis - II Lecture 18 - Gauss Quadrature
Link NOC:Basics of Finite Element Analysis - II Lecture 19 - Gaussian Quadrature review
Link NOC:Basics of Finite Element Analysis - II Lecture 20 - Gaussian Quadrature - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 21 - Gaussian Quadrature - Part III
Link NOC:Basics of Finite Element Analysis - II Lecture 22 - Newton-Cotes Quadrature
Link NOC:Basics of Finite Element Analysis - II Lecture 23 - Two dimensional FEM problem
Link NOC:Basics of Finite Element Analysis - II Lecture 24 - Two dimensional one variable FEM problem
Link NOC:Basics of Finite Element Analysis - II Lecture 25 - 2D Finite element problems with single variable (Model equation)
Link NOC:Basics of Finite Element Analysis - II Lecture 26 - 2D Finite element problems with single variable (Weak formulation)
Link NOC:Basics of Finite Element Analysis - II Lecture 27 - Elemental level 2D finite element equations
Link NOC:Basics of Finite Element Analysis - II Lecture 28 - Interpolation functions for 2D finite element problems
Link NOC:Basics of Finite Element Analysis - II Lecture 29 - Interpolation functions for linear triangular elements - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 30 - Interpolation functions for linear triangular elements - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 31 - Interpolation functions for Triangular and Rectangular elements
Link NOC:Basics of Finite Element Analysis - II Lecture 32 - Evaluation of Stiffness and Force matrices
Link NOC:Basics of Finite Element Analysis - II Lecture 33 - Stiffness and Force matrices for Triangular element
Link NOC:Basics of Finite Element Analysis - II Lecture 34 - Stiffness and Force matrices for Rectangular element
Link NOC:Basics of Finite Element Analysis - II Lecture 35 - Boundary elements for Finite element Equations
Link NOC:Basics of Finite Element Analysis - II Lecture 36 - Boundary integrals for Triangular element
Link NOC:Basics of Finite Element Analysis - II Lecture 37 - Assembly of 2-D finite elements - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 38 - Assembly of 2-D finite elements - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 39 - 2-D Heat transfer problems - Part I
Link NOC:Basics of Finite Element Analysis - II Lecture 40 - 2-D Heat transfer problems - Part II
Link NOC:Basics of Finite Element Analysis - II Lecture 41 - Numerical integration schemes for 2-D problems
Link NOC:Basics of Finite Element Analysis - II Lecture 42 - Jacobian and transformation matrix for 2-D problems
Link NOC:Basics of Finite Element Analysis - II Lecture 43 - Numerical Integration Schemes for 2-D Problems : Closure
Link NOC:Basics of Finite Element Analysis - II Lecture 44 - Post-processing
Link NOC:Basics of Finite Element Analysis - II Lecture 45 - Plane Elasticity Problems
Link NOC:Basics of Finite Element Analysis - II Lecture 46 - Plane Elasticity Problems : Development of Weak form
Link NOC:Basics of Finite Element Analysis - II Lecture 47 - Plane Elasticity Problems : Element level equations
Link NOC:Basics of Finite Element Analysis - II Lecture 48 - Plane Elasticity Problems : Closure
Link NOC:Principles of Vibration Control Lecture 1 - Introduction to Vibration control
Link NOC:Principles of Vibration Control Lecture 2 - Strategies and Steps in Vibration Control
Link NOC:Principles of Vibration Control Lecture 3 - Strategies, Active control, Detuning and Decoupling
Link NOC:Principles of Vibration Control Lecture 4 - Viscous damping model
Link NOC:Principles of Vibration Control Lecture 5 - Coulomb and Hysteretic damping model
Link NOC:Principles of Vibration Control Lecture 6 - Energy Dissipation in Structural Materials
Link NOC:Principles of Vibration Control Lecture 7 - Material Selection Criterion against Damping
Link NOC:Principles of Vibration Control Lecture 8 - Design for Enhanced Material Damping
Link NOC:Principles of Vibration Control Lecture 9 - Linear Viscoelastic Materials and Models
Link NOC:Principles of Vibration Control Lecture 10 - Maxwell and 3-Parameter Models
Link NOC:Principles of Vibration Control Lecture 11 - Complex modulus and Applications of VEM
Link NOC:Principles of Vibration Control Lecture 12 - Basics of Dynamic Vibration Absorber
Link NOC:Principles of Vibration Control Lecture 13 - Modelling of Dynamic Vibration Absorber
Link NOC:Principles of Vibration Control Lecture 14 - Proof mass Actuator
Link NOC:Principles of Vibration Control Lecture 15 - Springs for Vibration Isolation
Link NOC:Principles of Vibration Control Lecture 16 - Introduction to Active Vibration Control
Link NOC:Principles of Vibration Control Lecture 17 - Basics of Classical Control System
Link NOC:Principles of Vibration Control Lecture 18 - Basics of State Space Control
Link NOC:Principles of Vibration Control Lecture 19 - Controllability and Observability of System
Link NOC:Principles of Vibration Control Lecture 20 - Full State Feedback Control
Link NOC:Principles of Vibration Control Lecture 21 - SMSS Laboratory Demonstration
Link NOC:Fundamentals of Acoustics Lecture 1 - Lesson 1 - Course Overview
Link NOC:Fundamentals of Acoustics Lecture 2 - Lesson 2 - Introduction
Link NOC:Fundamentals of Acoustics Lecture 3 - Lesson 3 - Nature Of Sound
Link NOC:Fundamentals of Acoustics Lecture 4 - Lesson 4 - The Decibel scale
Link NOC:Fundamentals of Acoustics Lecture 5 - Lesson 5 - Key Terms In Acoustics
Link NOC:Fundamentals of Acoustics Lecture 6 - Lesson 6 - Adding Decibels
Link NOC:Fundamentals of Acoustics Lecture 7 - Lesson 1 - Important Mathematical Concepts-Complex Algebra
Link NOC:Fundamentals of Acoustics Lecture 8 - Lesson 2 - Important Mathematical Concepts-Complex Time Signals
Link NOC:Fundamentals of Acoustics Lecture 9 - Lesson 3 - Important Mathematical Concepts-Transfer Function
Link NOC:Fundamentals of Acoustics Lecture 10 - Lesson 4 - Important Mathematical Concepts-Pole Zero Plot
Link NOC:Fundamentals of Acoustics Lecture 11 - Lesson 5 - Important Mathematical Concepts - Bode Plot For Simple Pole
Link NOC:Fundamentals of Acoustics Lecture 12 - Lesson 6 - Important Mathematical Concepts - Bode Plot For Simple Zero
Link NOC:Fundamentals of Acoustics Lecture 13 - Lesson 1 - Bode Plots (Magnitude) for Complex Transfer Functions
Link NOC:Fundamentals of Acoustics Lecture 14 - Lesson 2 - Momentum Equation for 1-D Sound Propagation
Link NOC:Fundamentals of Acoustics Lecture 15 - Lesson 3 - Continuity Equation for 1-D Sound Propagation
Link NOC:Fundamentals of Acoustics Lecture 16 - Lesson 4 - Gas Law for 1-D Sound Propagation
Link NOC:Fundamentals of Acoustics Lecture 17 - Lesson 5 - 1-D Wave Equation
Link NOC:Fundamentals of Acoustics Lecture 18 - Lesson 6 - Solution for 1-D Wave Equation
Link NOC:Fundamentals of Acoustics Lecture 19 - Lesson 1 - Waveguide
Link NOC:Fundamentals of Acoustics Lecture 20 - Lesson 2 - Transmission Line Equations - Part I
Link NOC:Fundamentals of Acoustics Lecture 21 - Lesson 3 - Transmission Line Equations - Part II
Link NOC:Fundamentals of Acoustics Lecture 22 - Lesson 4 - Transmission Line Equations - Part III
Link NOC:Fundamentals of Acoustics Lecture 23 - Lesson 5 - Transmission Line Equations - Part IV
Link NOC:Fundamentals of Acoustics Lecture 24 - Lesson 6 - Transmission Line Equations - Part V
Link NOC:Fundamentals of Acoustics Lecture 25 - Lesson 1 - Instantaneous Power
Link NOC:Fundamentals of Acoustics Lecture 26 - Lesson 2 - Instantaneous Power in a L-R Circuit
Link NOC:Fundamentals of Acoustics Lecture 27 - Lesson 3 - Power Factor, and Acoustic Power
Link NOC:Fundamentals of Acoustics Lecture 28 - Lesson 4 - Power Flow into an Infinitely Long Tube
Link NOC:Fundamentals of Acoustics Lecture 29 - Lesson 5 - Point Sources of Sound
Link NOC:Fundamentals of Acoustics Lecture 30 - Lesson 6 - Relations for Outward Travelling Spherical Acoustic Wave
Link NOC:Fundamentals of Acoustics Lecture 31 - Lesson 1 - Specific Acoustic Impedance for a Closed Tube
Link NOC:Fundamentals of Acoustics Lecture 32 - Lesson 2 - Specific Acoustic Impedance for an Open Tube and an Infinitely Long Tube
Link NOC:Fundamentals of Acoustics Lecture 33 - Lesson 3 - Specific Acoustic Impedance for a Tube with Imperfect Termination
Link NOC:Fundamentals of Acoustics Lecture 34 - Lesson 4 - Kundt’s Tube
Link NOC:Fundamentals of Acoustics Lecture 35 - Lesson 5 - Volume Velocity
Link NOC:Fundamentals of Acoustics Lecture 36 - Lesson 6 - Comparison of Impedances for a Radially Propagating Wave and a Planar Wave
Link NOC:Fundamentals of Acoustics Lecture 37 - Lesson 1 - Interference of sound sources - Part I
Link NOC:Fundamentals of Acoustics Lecture 38 - Lesson 2 - Interference of sound sources - Part II
Link NOC:Fundamentals of Acoustics Lecture 39 - Lesson 3 - Interference of sound sources - Part III
Link NOC:Fundamentals of Acoustics Lecture 40 - Lesson 4 - Interference of sound sources - Part IV
Link NOC:Fundamentals of Acoustics Lecture 41 - Lesson 5 - Directivity
Link NOC:Fundamentals of Acoustics Lecture 42 - Lesson 6 - Complex power, pressure and velocity for a spherical source
Link NOC:Fundamentals of Acoustics Lecture 43 - Lesson 1 - Noise reduction - Mass Attenuation Method
Link NOC:Fundamentals of Acoustics Lecture 44 - Lesson 2 - Noise Reduction - Pressure Ratio
Link NOC:Fundamentals of Acoustics Lecture 45 - Lesson 3 - Noise Reduction - Velocity of Wall
Link NOC:Fundamentals of Acoustics Lecture 46 - Lesson 4 - 3 Media Problem - Introduction
Link NOC:Fundamentals of Acoustics Lecture 47 - Lesson 5 - 3 Media Problem - Apply Boundary Conditions
Link NOC:Fundamentals of Acoustics Lecture 48 - Lesson 6 - 3 Media Problem - Special cases
Link NOC:Fundamentals of Acoustics Lecture 49 - Lesson 1 - Mufflers
Link NOC:Fundamentals of Acoustics Lecture 50 - Lesson 2 - Designing of Reactive Mufflers
Link NOC:Fundamentals of Acoustics Lecture 51 - Lesson 3 - Designing of Dissipative Mufflers
Link NOC:Fundamentals of Acoustics Lecture 52 - Lesson 4 - Time and Frequency Domain Representation of a Signal
Link NOC:Fundamentals of Acoustics Lecture 53 - Lesson 5 - Fourier Series
Link NOC:Fundamentals of Acoustics Lecture 54 - Lesson 6 - Fourier Series
Link NOC:Fundamentals of Acoustics Lecture 55 - Lesson 1 - Fourier Transform
Link NOC:Fundamentals of Acoustics Lecture 56 - Lesson 2 - Fourier Transform
Link NOC:Fundamentals of Acoustics Lecture 57 - Lesson 3 - Fourier Transform
Link NOC:Fundamentals of Acoustics Lecture 58 - Lesson 4 - Discrete Fourier Transform (DFT)
Link NOC:Fundamentals of Acoustics Lecture 59 - Lesson 5 - Discrete Fourier Transform (DFT)
Link NOC:Fundamentals of Acoustics Lecture 60 - Lesson 6 - Discrete Fourier Transform (DFT)
Link NOC:Fundamentals of Acoustics Lecture 61 - Lesson 1 - Measuring Sound Signals
Link NOC:Fundamentals of Acoustics Lecture 62 - Lesson 2 - Microphones
Link NOC:Fundamentals of Acoustics Lecture 63 - Lesson 3 - Microphones
Link NOC:Fundamentals of Acoustics Lecture 64 - Lesson 4 - Weighting
Link NOC:Fundamentals of Acoustics Lecture 65 - Lesson 5 - Loudness
Link NOC:Fundamentals of Acoustics Lecture 66 - Lesson 6 - Loudness
Link NOC:Fundamentals of Acoustics Lecture 67 - Lesson 1 - Octave Band Analysis - Part I
Link NOC:Fundamentals of Acoustics Lecture 68 - Lesson 2 - Octave Band Analysis – Part II
Link NOC:Fundamentals of Acoustics Lecture 69 - Lesson 3 - Octave Band Analysis – Part III
Link NOC:Fundamentals of Acoustics Lecture 70 - Lesson 4 - Reverberation Time
Link NOC:Fundamentals of Acoustics Lecture 71 - Lesson 5 - Calculation of Reverberation Time and Sound Transmission Class (STC)
Link NOC:Fundamentals of Acoustics Lecture 72 - Lesson 6 - Noise Reduction Coefficient (NRC)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 1 - Recap - I
Link NOC:Heat Treatment and Surface Hardening - II Lecture 2 - Recap - II
Link NOC:Heat Treatment and Surface Hardening - II Lecture 3 - Recap - III
Link NOC:Heat Treatment and Surface Hardening - II Lecture 4 - Determination of Phase Diagram (Experimentally) - I
Link NOC:Heat Treatment and Surface Hardening - II Lecture 5 - Determination of Phase Diagram (Experimentally) - II
Link NOC:Heat Treatment and Surface Hardening - II Lecture 6 - Determination of Phase Diagram (Thermodynamically)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 7 - Effect of pressure on phase transformation temperature and concept of equilibrium between condensed and vapor phase
Link NOC:Heat Treatment and Surface Hardening - II Lecture 8 - Effect of different parameters on heat treatment and concept of saturation vapor pressure with examples
Link NOC:Heat Treatment and Surface Hardening - II Lecture 9 - Title: Formation of ideal solid or liquid solution and (G-X) diagrams for ideal solutions (Part-I)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 10 - G-X diagrams (Part- II) and concept of chemical potential (Micro Sign) from G-X diagrams.
Link NOC:Heat Treatment and Surface Hardening - II Lecture 11 - Concept of common tangent for equilibrium between two phases
Link NOC:Heat Treatment and Surface Hardening - II Lecture 12 - Expressions for equilibrium of two phases - I
Link NOC:Heat Treatment and Surface Hardening - II Lecture 13 - Expressions for equilibrium of two phases - II
Link NOC:Heat Treatment and Surface Hardening - II Lecture 14 - Expressions for equilibrium of two phases - III
Link NOC:Heat Treatment and Surface Hardening - II Lecture 15 - Determining nucleation of phases using G-X plot
Link NOC:Heat Treatment and Surface Hardening - II Lecture 16 - ΔG for nucleation and overall transformation, concepts of solid state transformation including precipitation and Quasi-Chemical Model (QCM)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 17 - Introduction to real solutions and expression of ΔHmix based on the Quasi-Chemical Model (QCM)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 18 - Expression for ΔHmix as a function of interaction energy and mole fraction, based on the QCM - Part I
Link NOC:Heat Treatment and Surface Hardening - II Lecture 19 - Expression for ΔHmix as a function of interaction energy and mole fraction, based on the QCM - Part II
Link NOC:Heat Treatment and Surface Hardening - II Lecture 20 - Graphical representation of ΔGmix, ΔHmix, and -TΔSmix for real solutions and evolution of eutectic phase diagram from the G-X plots
Link NOC:Heat Treatment and Surface Hardening - II Lecture 21 - Effect of ΔHmix on determination of phase diagrams (same crystal structure)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 22 - Effect of ΔHmix on determination of phase diagrams (Continued...)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 23 - Importance of phase diagrams
Link NOC:Heat Treatment and Surface Hardening - II Lecture 24 - Effect of heat treatment on microstructure evolution in steel - I
Link NOC:Heat Treatment and Surface Hardening - II Lecture 25 - Effect of heat treatment on microstructure evolution in steel - II
Link NOC:Heat Treatment and Surface Hardening - II Lecture 26 - Recap of homogeneous and heterogeneous nucleation for solid to solid transformation
Link NOC:Heat Treatment and Surface Hardening - II Lecture 27 - Nucleation rate and its dependence on T (temp. of interest), ΔT, ΔG v and ΔG* and, introduction to growth kinetics
Link NOC:Heat Treatment and Surface Hardening - II Lecture 28 - Growth kinetics (Continued...)
Link NOC:Heat Treatment and Surface Hardening - II Lecture 29 - Growth rate variation with undercooling and kinetics of overall phase transformation
Link NOC:Heat Treatment and Surface Hardening - II Lecture 30 - Implication of Avrami’s equation with example on excel spreadsheet
Link NOC:Heat Treatment and Surface Hardening - II Lecture 31 - Experimental verification of Avrami Equation
Link NOC:Heat Treatment and Surface Hardening - II Lecture 32 - Linear regression (least squares) method to find the value of n and k in Avrami equation
Link NOC:Heat Treatment and Surface Hardening - II Lecture 33 - In this lecture, method to determine the goodness of fit has been explained. Procedure to estimate the values of n and k from experimental data have also been discussed.
Link NOC:Heat Treatment and Surface Hardening - II Lecture 34 - Stereology and quantitative metallography - I
Link NOC:Heat Treatment and Surface Hardening - II Lecture 35 - Stereology and quantitative metallography - II
Link NOC:Heat Treatment and Surface Hardening - II Lecture 36 - Grain size measurements methods