Credit Hours-2-1
Course Content:
Semiconductor Basics: Intrinsic & Extrinsic Materials, n-type & p-type Materials,
Semiconductor Diode: Construction, Diode equivalent Circuits, Zener Diode, Diode Applications e.g. Clipper, Clampers, Rectifier (Half-Wave & Full-Wave).
Bipolar Junction Transistors (BJTs): Construction, Region of Operations, Different Configuration, Transistor Switching Networksalong with DC Biasing.
Field Effect Transistor (FET): Construction and Characteristics, Different Configurations along with DC Biasing.
BJT and FET Small Signal Equivalent Circuit: Modeling & Different Configurations.
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
DESCRIBE and explain the basic construction, operation and characteristics of semiconductor devices. |
Cognitive |
C2 |
1 |
2. |
Develop the understanding of elementary concepts required for the analysis and design of electronic circuits |
Cognitive |
C5 |
3 |
3. |
Analyze basic principles of digital logic systems and their different applications |
Cognitive |
C4 |
2 |
4. |
Demonstrate the basic architecture of microcontroller and microprocessor |
Cognitive |
C3 |
1 |
5. |
UNDERSTAND fundamental concepts of digital logic design including basic and universal gates, number systems, binary coded systems and basic components of combinational and sequential circuits. |
Cognitive |
C2 |
2 |
Recommended Books
1. Robert Boylestad and Louis Nashelsky, “Electronic Devices and Circuit Theory,” Ninth Edition, 2006, Prentice Hall.
2. Robert Paynter, “Introductory Electronic Devices and Circuits: Electron Flow Version,” Seventh Edition, 2006, Prentice Hall.
- Teacher: tayyabhassni hassni
Credit Hours-2-1
Course Content:
1. Fluid Properties
a. Definition of fluid and its classification b. Concept of continuum. c. Properties of the fluid.
2. Fluid Statics
a. Concept of Pressure and basic equations for compressible and incompressible b. Pressure measurements and devices. c. Hydrostatics forces on plane and curved surfaces. d. Buoyancy and Stability. e. Pressure variation in fluid with rigid body motion.
3. Fluid Kinematics
a. Flow characteristics, Descriptions of Velocity and acceleration field (Streamlines, streak lines and path lines). b. Control volume and representation of system. c. Reynolds transport theorem (RTT).
4. Fluid Dynamics
a. Application of Newton’s 2nd law in fluids. b. Total, stagnation and dynamic pressure. c. Deriving Bernoulli equation and its applications.
5. Integral Analysis of Fluid Flow
a. Continuity equation using RTT. b. Linear momentum equation using RTT. c. Moment of momentum equation using RTT.
6. Dimensional Analysis, Similitude and Modeling
a. Dimensional analysis b. Buckingham Pi theorem and determination of Pi terms
7. Flow in Pipes
a. Characteristics of pipe flow laminar and turbulent. b. Calculating friction factor and wall shear stresses. c. Solving pipe flow network problems
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
APPLY the basic concepts to hydrostatic fluid problems. |
Cognitive |
C1 |
1 |
2. |
Analyze the fluid kinematics and dynamics parameters using basic laws of mechanics.. |
Cognitive |
C3 |
2 |
4. |
Solve the pipe flow problems using Bernoulli and energy equation. |
Cognitive |
C3 |
2 |
5. |
Understand the concept of dimensional analysis |
Cognitive |
C3 |
1 |
Recommended Books
1. Munson, Young And 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, J. Wiley & Sons. 3. Frank M White, Fluid Mechanics. McGraw-Hill.
- Teacher: mushtaquerajput rajput
Credit Hours-2-1
Course Content:
1. Introduction and Basic Concepts
a. First law of thermodynamics and its applications b. System and boundary c. Specific volume, pressure and temperature
2. Energy, Energy Transfer, and General Energy Analysis
a. Equilibrium state, processes b. Methods to solve thermodynamics problems
3. Properties of Pure Substances
a. Phase change processes, P-v-T relation b. Property diagrams c. Equation of state, specific heats d. Compressibility polytropic process relation.
4. Energy Analysis of Closed Systems
a. Energy balance of closed system
5. Mass and Energy Analysis of Control Volumes
a. Energy analysis of power, refrigeration and heat pump cycles
6. The Second Law of Thermodynamics
a. Spontaneous and non-spontaneous processes b. Thermodynamic cycles, irreversible and reversible process, and Carnot cycle c. Clausius inequality.
7. Entropy
a. Entropy change, T-s diagram, entropy generation b. Increase of entropy principle, entropy rate balance of closed systems and control volumes c. isentropic efficiencies
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 basic concepts and practical role of thermodynamic properties of pure substance and different process on different diagrams. |
Cognitive |
C2 |
1 |
2. |
Apply the energy equation on thermodynamic open systems to analyze and apply energy and entropy balances for open and closed system |
Cognitive |
C3 |
1 |
3. |
To analyze the limitations and significance of second law of thermodynamics by applying fundamental knowledge of thermodynamics. |
Cognitive |
C4 |
2 |
Recommended Books
1. Yunus A. Cengel, Michael A., Thermodynamics: An Engineering Approach, McGraw-Hill.
2. M. J. Moran and H. O. Shapiro, Fundamentals of Engineering Thermodynamics, John Wiley & Sons.
3. Sonntang, Borgnakke, Van Wylen John, Fundamentals of Thermodynamics, Wiley & Sons.
4. T. D. Eastop and A. McConkey, Applied Thermodynamics for Engineering Technologists, Pearson.
- Teacher: engr_najeehullah baloch
Credit Hours-2-1
Course Content:
1. Mechanical properties of materials; tensile, compressive and shear stress & strain
2. Moment of inertia
3. Axial loading, Hooke’s law, stress strain relationship
4. Thermal stresses
5. Torsion of circular bars,
6. Pure bending of beams, shear stresses in beams
7. Shearing force and bending moment
8. Beam deflection using various methods
9. Residual stresses and stress concentration in various engineering applications
10. Analysis of statically indeterminate problems,
11. Thin and thick curved bars,
12. Thin walled pressure vessels.
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
Explain the accurate knowledge with the help of mathematically formulation used in material sciences and terminology used in this course. |
Cognitive |
C2 |
1 |
2. |
Define and proof the basic law’s that is used in mechanics of material and derive the equation from the basic knowledge and from the ideas in this course. |
Cognitive |
C2 |
2 |
3. |
The students will be able to apply this basic knowledge and concept into practical knowledge and have an ability to solve the complicated problems in this course. |
Psychomotor |
P3 |
2 |
4. |
The students will advance exact skills, capabilities, and thought processes enough to support further study or accurate work in material sciences or linked field in material sciences. |
Cognitive |
C3 |
2 |
5. |
Explain the findings of design project in the form of original report. |
Psychomotor |
P6 |
2 |
Recommended Books
1. James M. Gere, Barry J. Goodno, Mechanics of Materials
2. Ferdinand P. Beer & Russel Johnston Jr., Mechanics of Materials McGraw-Hill
3. R. C. Hibbeler, Mechanics of Materials
4. P. P. Benham& R. J. Crawford, Mechanics of Engineering Materials, Longman
5. Popov, Mechanics of Materials.
6. W. A. Nashi, Static and Mechanics of Materials, Schaum’s outline series New York.
- Teacher: m arif
Credit Hours-3-1
Course Content:
1. Introduction to subject and Basic Concepts
2. Kinematics of Particles a. Rectilinear Motion b. Plane Curvilinear Motion c. Space Curvilinear Motion d. Motion Relative to Trans Axes e. Constrained Motion of Connected Particles
3. Kinetics of Particles a. Second Law & Equation of Motion b. Work and Energy c. Linear Impulse and Momentum d. Impact e. Angular Momentum
4. Kinematics of Rigid Bodies a. Plane Motion b. Relative Velocity c. Relative Acceleration
5. Kinetics of Rigid Bodies a. Kinetics of Rigid Bodies
Course Learning Outcome:
Upon successful completion of the course, student will be able to:
S # |
CLO, Course Learning Outcome |
Domain |
Level |
PLO |
1. |
Comprehension The student will be able to comprehend the Kinetics & kinematics; Work-Energy principles and Impulse and Momentum Relationships applicable on bodies which may have Rectilinear motion, Plane curvilinear motion, and Space curvilinear motion. |
Cognitive |
C1 & C2 |
1 |
2. |
Analyze The student will be able to analyze a given problem and find a solution after its complete comprehension. |
Cognitive |
C4 |
2 |
3. |
Solve The student will be able to solve a given problem by applying the comprehended techniques and principles after complete analysis. |
Cognitive |
C5 |
3 |
Recommended Books
1. J L Meriam, L G Kraig. Engineering Mechanics (Dynamics): John Wiley & Sons Inc.
2. Beer & Johnston. Vector Mechanics for Engineers: Statics & Dynamics, McGraw-Hill
3. RC Hibbeler. Engineering Mechanics (Dynamics),13th Ed., Prentice Hall
4. Anthony M Bedford, Wallace Fowler. Engineering Mechanics (Dynamics), Prentice Hall
5. E. Nelson, Engineering Mechanics: Statics, Schaum’s outline series New York.
- Teacher: abdul hameed