Lecture 1 - Basic Concepts of Manufacturing Systems, Evolution of Manufacturing Systems
Lecture 2 - Types of Manufacturing Systems and Role of Automation
Lecture 3 - Product-Process-Flexibility Matrices, Four-Plane Concept of Manufacturing
Lecture 4 - Product Design and Manufacturing Systems
Lecture 5 - Definitions and Design Criteria for Production Systems
Lecture 6 - Manufacturing System Components - I
Lecture 7 - Manufacturing System Components - II
Lecture 8 - Industry 4.0
Lecture 9 - Automation Principles and Strategies for Process Improvement
Lecture 10 - Automated Production System Framework
Lecture 11 - Product Development Process: Approaches and stages
Lecture 12 - Mathematical Models for Interaction between Design and Manufacturing
Lecture 13 - Sequential and Concurrent Engineering Approaches for Product Development
Lecture 14 - Characterization of Concurrent Engineering Framework
Lecture 15 - Concurrent Engineering Techniques
Lecture 16 - Introduction to Concept and Application of Numerical Control (NC) Technology
Lecture 17 - Basic Concepts of an NC System
Lecture 18 - NC Coordinate System, NC Motion Control System
Lecture 19 - Features of CNC, Configuration of CNC Machine Control System
Lecture 20 - Numerical Examples
Lecture 21 - Distributed Numerical Control (DNC) and its Configuration
Lecture 22 - NC Part Programming-I (Manual, Computer-assisted)
Lecture 23 - NC Part Programming-II (CAD/CAM, MDI)
Lecture 24 - Interpolation and Part Programming
Lecture 25 - Numerical Examples
Lecture 26 - Group Technology (GT): Concept and Definition
Lecture 27 - Methods and Implementation of GT for Automation
Lecture 28 - Part Family Formation: Tools and Techniques
Lecture 29 - Numerical Examples on Part Family Formation
Lecture 30 - Application of GT for Designing Flexible and Programmable Automation
Lecture 31 - Concept and Definition of Cellular Manufacturing System (CMS)
Lecture 32 - Cell Formation Approaches - I
Lecture 33 - Cell Formation Approaches - II
Lecture 34 - Evaluation of Cell Design, Numerical Examples
Lecture 35 - Production Planning and Control in CMS, Assessment of Solution by Heuristics
Lecture 36 - Types and Definitions of of Flexibility in Manufacturing Systems
Lecture 37 - Volume-Variety Relationships in Production Systems, What is FMS?
Lecture 38 - Basic Features of FMS: PhysicalSsubsystems
Lecture 39 - Basic Features of FMS: Control Subsystems and Manufacturing Control Activities.
Lecture 40 - Types of Problems in FMS
Lecture 41 - Operational Problems in FMS: Tools and Techniques - 1, Problem Formulation
Lecture 42 - Operational Problems in FMS: Tools and Techniques - 2, Numerical Examples
Lecture 43 - Tool Allocation Policies in FMS, Numerical Examples
Lecture 44 - Fixture and Pallet Selection Problems: Numerical Examples
Lecture 45 - Types of FMS Layout, Relative Advantages
Lecture 46 - Fundamentals of Robotics and its Applications
Lecture 47 - Robot Movement and Precision
Lecture 48 - Robot Motion Analysis, Robotic Joints and Links
Lecture 49 - Robot Classification System, Industrial Robot Applications
Lecture 50 - Numerical Examples
Lecture 51 - Definition of Process Planning: Function of Process Plan
Lecture 52 - Basic Steps in Process Plan Development
Lecture 53 - Process Planning Approaches: Manual Experience-based Process Planning
Lecture 54 - Process Planning Approaches: Computer-aided Process Planning
Lecture 55 - CIN and CAPP, Process Optimization and CAPP
Lecture 56 - Process Optimization and CAPP
Lecture 57 - FMS and CAPP
Lecture 58 - Process Optimization and CAPP: Numerical Examples
Lecture 59 - Process Planning and Concurrent Engineering
Lecture 60 - Autonomation (and other TPS Areas and Approaches)