Course Content:
Introductory Concepts
· Introduction to Complex Number System
· Argand diagram
· De Moivre’s theorem and its Application Problem Solving Techniques
Analyticity of Functions
· Typecasting
· Memory Allocation (Static vs. Dynamic)
· Array of Pointers vs. Pointer of Arrays
· User-defined Data Types
Singularities
Laplace transform
· Laplace transform definition,
· Laplace transforms of elementary functions
· Properties of Laplace transform, Periodic functions and their Laplace transforms,
· Inverse Laplace transform and its properties,
· Convolution theorem,
· Inverse Laplace transform by integral and partial fraction methods,
· Heaviside expansion formula,
· Solutions of ordinary differential equations by Laplace transform,
· Applications of Laplace transforms
Fourier series and Transform
- Fourier theorem and coefficients in Fourier series,
- Even and odd functions,
- Complex form of Fourier series,
- Fourier transform definition,
- Fourier transforms of simple functions,
- Magnitude and phase spectra,
- Fourier transform theorems,
- Inverse Fourier transform,
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
Define the complex number system, complex functions and integrals of complex functions |
Cognitive |
C1 |
1 |
2. |
Explain the concept of limit, continuity, differentiability of complex valued functions |
Cognitive |
C2 |
1 |
3. |
Apply the results/theorems in complex analysis to complex valued functions |
Cognitive |
C3 |
1 |
4. |
Explain the concept of integral transforms, e.g., Laplace, Fourier transforms and the related inverse transforms by using the following Partial fractions method, Tables, Convolution theorems and apply these transformation for engineering problems |
Cognitive |
C3 |
1 |
Recommended Books
Complex Variables & Applications, By J. W. Brown & R. V. Churchill
Complex Analysis For Mathematics & Engineering, By J. H. Mathew & Howells,
Basic Complex Analysis, by J. E. Marsden
Analytic Function Theory, By E. Hille 1974
- Teacher: Dr. jamshaid ul rahman
Course Content:
1. Analysis of stress and strain in two and three dimensions
2. Principal stresses and strains
3. Mohr’s circle for stress and strain
4. Thick walled pressure vessels
5. Symmetrical and asymmetrical loading
6. Introduction to fracture mechanics
7. Impact loading
8. Fatigue and creep
9. Virtual work
10. Theories of elastic failure
11. Theory of columns
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
Analyze stresses and strains for two- and three-dimensional cases using and various technique. |
Cognitive |
C3 |
2 |
2. |
Understand theory of failure of materials |
Cognitive |
C1 |
1 |
3. |
Solve problems related to early failure of materials under special conditions like fatigue, creep etc |
Cognitive |
C2 |
2 |
4. |
Analyze stresses in thick walled cylinders and columns. |
Cognitive |
C4 |
2 |
5. |
Understand Virtual Work and Fracture Mechanics |
Cognitive |
C1 |
1 |
Recommended Books
1. E J Hearn, Mechanics of Materials Volume 1 & 2
2. Ferdinand P. Beer & Russel Johnston Jr., Mechanics of Materials, McGraw-Hill
3. Popov, Mechanics of Materials
4. P. P. Benham & R. J. Crawford, Mechanics of Engineering Materials, Longman Sci & Tech
5. Boresi, Arthur P., Schmidt, Richard J. Sidebottom, Omar M., Advanced Mechanics of Materials
6. R. C. Hibbeler, Mechanics of Materials
7. Andrew Pytel and F. L. Singer, Strength of Materials
8. W. F. Riley, L. D. Sturges and D. H. Morris, Mechanics of Materials.
9. W. A. Nashi, Statics and Mechanics of Materials, Schaum’s outline series New York
- Teacher: shahzaibiqbal iqbal
Course Content: (Machine Design I)
Introduction
1. Design philosophy
2. Types of design
Mechanical behavior of materials
1. Concepts of stress and strain
2. Different types of stress and strain in a machine element
3. Stress-strain diagram
4. Actual and permissible stresses
5. Factor of safety
Design of keys and coupling
1. Basic concepts
2. Methodology
Design of Riveted joint, Welded joints, Bolted joints
1. Basic concepts
2. Methodology
Design of springs, Shafts
1. Basic concepts
2. Methodology
Metal fits and tolerances and Design Standards
1. Basic concepts of tolerance
2. Types of fits
3. ISO standard fits charts
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
Understand the application of design standards and the importance of dimensional parameters in manufacturing aspects of mechanical design. |
Cognitive |
C2 |
1 |
2. |
Classify the different types of joints using in mechanical structure |
Cognitive |
C2 |
1 |
3. |
To analyze the Mechanical Springs / Shafts / Clutches / Brakes using standards and Present the design aspects of basic machine design theory. |
Cognitive |
C5 |
3 |
Recommended Books
1. Robert L. Mott ,Machine Elements in Mechanical Design
2. Robert L. Norton, Design of Machinery
3. R. S. Khurmi & J. K. Gupta, A Textbook of Machine Design
4. Joseph E. Shigley, Theory of Machines & Mechanisms
Course Content: (CAD-I)
1. Introduction to CAD
2. 2D Drafting
3. 3D Modeling of Machine Elements (Part and Assembly)
4. Mechanisms and assembly
Practical:
· Select a machine and study its operation and machine elements detail.
· Draw the 3D model of the machine element and draw 2D drawings
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
ACQUIRE the basic knowledge of CAD drawing tools. |
Cognitive |
C1 |
1 |
2. |
DEVELOP different multi-views of an object. |
Psychomotor |
P2 |
2 |
3. |
DEMONSTRATE the 3D model of the machine elements. |
Psychomotor |
P3 |
3 |
Recommended Books
1. R. Lal, R. Rana, A Textbook of Engineering Drawing: Along with an Introduction to AutoCAD.
2. T. Jeyapoovan, Engineering Drawing and Graphics Using AutoCAD.
3. Z. A. Siddiqui, M. Ashraf and S. A. Siddiqui. Basics of Engineering Drawing
4. D. A. Jolhe, Engineering Drawing with an introduction to AutoCAD
- Teacher: Faisal Maqbool
Course Content:
1. Differential Analysis of Fluid Flow
a. Deriving continuity equation by applying conservation of mass principle.
b. Evaluating velocity and acceleration field using material derivative.
c. Deriving Navier-Stokes equation and some simple analytical solution
2. Potential flow theory
a. Concept of vorticity, Circulation, Inviscid and Irrotational flow field
b. Basic velocity potential function and its superposition.
c. Prediction of Lift and drag using potential flow theory
3. Flow over immersed bodies
a. Boundary layer theory and its thicknesses.
b. Concept of local and average drag coefficient.
c. Calculating drag and lift forces due to pressure and velocity field.
4. Introduction to Computational Fluid Dynamics
a. Finite difference formulation
b. Solving basic fluid flow problems using available CFD code.
5. Compressible Flows
a. Mach number and speed of sound
b. Isentropic flow of an ideal gas
c. Convergent divergent Nozzle
6. Turbomachinery
a. Fans, Pumps, turbines and other flow devices.
b. Deriving Euler’s equation and solving of turbo-machine problems using velocity triangle
c. Pump and turbine performance characteristic curves.
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
APPLY governing equations to incompressible and compressible fluid flows. |
Cognitive |
C3 |
2 |
2. |
CALCULATE the lift and drag forces for various objects. |
Cognitive |
C3 |
2 |
3. |
CALCULATE fluid flow parameters for various geometries. |
Cognitive |
C3 |
2 |
Recommended Books
1. Munson, Young, Okiishi, HT John, Fundamentals Of Fluid Mechanics, J. Wiley & Sons.
2. Philip J. Pritchard and John C. Leylegian, Fox And McDonald's Introduction To Fluid Mechanics, Wiley & Sons.
3. Frank M White, Fluid Mechanics, Mc-Graw Hill
- Teacher: Asif Mehmood
1. Review of Thermodynamics I
a. Energetics b. Efficiency
2. Exergy
a. Exergy balance
b. Exergetic efficiency
3. Gas Power Cycles
a. Air-Standard-Otto cycle
b. Diesel cycle,
c. Dual and Brayton cycle
d. Regenerative gas turbines with reheat & inter cooling
e. Combined cycles
4. Vapor and Combined Power Cycles
a. Modeling and analyzing
b. Superheat and Reheat vapor power cycles
c. Regenerative vapor power cycles
d. Other vapor cycle aspects
5. Refrigeration Cycles
a. Vapor compression refrigeration systems
b. Cascade and Multistage systems
c. Absorption refrigeration, Heat pump, and Gas refrigeration systems
6. Thermodynamic Property Relations and Gas Mixtures
a. Mixture composition
b. P-v-T relations for gas mixtures
c. U, H, S and specific heats for gas mixtures.
7. Chemical Reactions
a. Combustion process and conservation of energy in reacting systems
b. Importance of mathematical relations
8. Chemical and Phase Equilibrium
a. Equilibrium fundamentals
b. Chemical potential and equilibrium.
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
Analyse thermodynamics cycles of power, refrigeration, and air-conditioning using energy and exergy principles. |
Cognitive |
C4 |
2 |
2. |
UNDERSTAND working principles of boilers, nozzles, compressor and steam turbines |
Cognitive |
C2 |
1 |
3. |
UNDERSTAND the classification and thermodynamics of psychometric process |
Cognitive |
C2 |
1 |
4. |
Apply the laws of thermodynamics to the chemical and phase equilibrium problems. |
Cognitive |
C3 |
2 |
5. |
Understand the implications of thermodynamics power, refrigeration, and air-conditioning systems on the environmental and future sustainability. |
Cognitive |
C2 |
7 |
Recommended Books
1. Yunus A. Cengel and Michael A. Boles, Thermodynamics, An Engineering Approach, McGraw-Hill.
2. M. J. Moran and H. O. Shapiro, Fundamentals of Engineering Thermodynamics, John Wiley & Sons.
3. Sonntang, Borgnakke, and Van Wylen, Fundamentals of Thermodynamics, John Wiley & Sons.
4. Ibrahim Dincer and Marc A. Rosen, Exergy: Energy, Environment, and Sustainable Development, Springer.
T.D. Eastop and A. McConkey, Applied Thermodynamics for Engineering Technologists, Pearson.- Teacher: mishaq ishaq