1 | 1. INTRODUCTION
• Simple Mathematical Model
• Principles of Engineering Design
• Workable Systems
• Optimum Systems
• Packages and Modular Programming
• Case Studies |
2 | 1. INTRODUCTION
• Simple Mathematical Model
• Principles of Engineering Design
• Workable Systems
• Optimum Systems
• Packages and Modular Programming
• Case Studies |
3 | 1. INTRODUCTION
• Simple Mathematical Model
• Principles of Engineering Design
• Workable Systems
• Optimum Systems
• Packages and Modular Programming
• Case Studies |
4 | 2. REVIEW OF BASIC ENGINEERING FUNDAMENTALS
• Fluid Mechanics – Mass Balances
• Thermodynamics – Energy Balances
• Thermal Systems and Design
• Basic Electronics |
5 | 2. REVIEW OF BASIC ENGINEERING FUNDAMENTALS
• Fluid Mechanics – Mass Balances
• Thermodynamics – Energy Balances
• Thermal Systems and Design
• Basic Electronics |
6 | 2. REVIEW OF BASIC ENGINEERING FUNDAMENTALS
• Fluid Mechanics – Mass Balances
• Thermodynamics – Energy Balances
• Thermal Systems and Design
• Basic Electronics |
7 | 3. MODELLING AND EQUATION FITTING
• Matrices and System of Simultaneous Equations
• Polynomial Representation
• Lagrange Interpolation
• Functions of Two Variables
• Least Squares Regression – Linear, Polynomial, Non-Linear
• Curve Fitting |
8 | 3. MODELLING AND EQUATION FITTING
• Matrices and System of Simultaneous Equations
• Polynomial Representation
• Lagrange Interpolation
• Functions of Two Variables
• Least Squares Regression – Linear, Polynomial, Non-Linear
• Curve Fitting |
9 | 3. MODELLING AND EQUATION FITTING
• Matrices and System of Simultaneous Equations
• Polynomial Representation
• Lagrange Interpolation
• Functions of Two Variables
• Least Squares Regression – Linear, Polynomial, Non-Linear
• Curve Fitting |
10 | 3. MODELLING AND EQUATION FITTING
• Matrices and System of Simultaneous Equations
• Polynomial Representation
• Lagrange Interpolation
• Functions of Two Variables
• Least Squares Regression – Linear, Polynomial, Non-Linear
• Curve Fitting |
11 | 4. SYSTEM SIMULATION
• Description, Uses and Classes
• Information Flow Diagrams
• Successive Substitution, Pitfalls
• Taylor Series and Newton/Raphson Technique
• Case Studies
• Engineering Applications |
12 | 4. SYSTEM SIMULATION
• Description, Uses and Classes
• Information Flow Diagrams
• Successive Substitution, Pitfalls
• Taylor Series and Newton/Raphson Technique
• Case Studies
• Engineering Applications |
13 | 4. SYSTEM SIMULATION
• Description, Uses and Classes
• Information Flow Diagrams
• Successive Substitution, Pitfalls
• Taylor Series and Newton/Raphson Technique
• Case Studies
• Engineering Applications |
14 | 4. SYSTEM SIMULATION
• Description, Uses and Classes
• Information Flow Diagrams
• Successive Substitution, Pitfalls
• Taylor Series and Newton/Raphson Technique
• Case Studies
• Engineering Applications |