Power System and Mechanical Engineering Path: select only the Power System and Mechanical Engineering Path courses from the list of optional courses. Students interested in Communication Engineering Path: Select only the courses in Communication Engineering Path from the list of optional courses. Students interested in Electronics Engineering Path: Select only the courses in Electronics Engineering Path from the list of optional courses.

Students interested in common path: choose elective courses without following any path List of elective courses -1. It also provides understanding of methodologies for solving electrical circuits and having experience in analyzing electrical circuits. Both DC and AC circuit analysis methods are also presented to help the students solve any type of electrical circuits.

Electronic Devices and Circuit Theory (7th ed.) by R. The course provides students with the knowledge, skills and ability to: 1. Develop an understanding of power calculations in AC circuits.

Course Objectives

Expected Learning Outcomes

Course Contents

Mode of Evaluation

Textbook(s)

To impress upon the students the methods of measurement and necessary equipment of various electrical sizes and the operation of electrical measuring instruments and their constructional details. Suggest the kind of instruments to be used according to different scenarios and the methods to improve their performance (Outcome a1, b1, b2). Measuring instruments: -Classification - deflection, control and damping torques - Ammeters and voltmeters - PMMC, moving iron type instruments - expression of the deflection torque and control torque, extension of range using shunts and series resistance.

Energy measurement: -Single-phase energy meter of induction type – driving and braking torques – errors and compensations. Resistance measurements: Method for measuring low, medium and high resistance – Wheatstone bridge sensitivity – Carey Foster bridge, Kelvin's double bridge for measuring low resistance, high resistance measurement – ​​loss of charge method.

To inculcate in students testing, calibrating and extending the range of various measuring devices used for measuring electrical quantities. Test, calibrate and make measurements using measuring devices for measuring different electrical quantities such as voltage, current, power and energy (Outcome b2). Students will be able to understand and apply their knowledge in measuring resistance and inductance using different methods (Outcome b2, b3).

Calibration and testing of PMMC meters: ammeters and voltmeters, range extension using shunts and series resistance.

Teaching Methods

Define the following combinational circuits: buses, encoders/decoders, (de)multiplexers, exclusive ORs, comparators, arithmetic-logic units; and to be able to build simply. Develop an understanding of designing a digital logic circuit-based system to achieve a prescribed task (Outcome b3). 3) Course content. Introduction to number system, binary, octal, decimal and hexadecimal numbers and base conversions, complements, binary codes.

Focus especially on the topics and concepts taught as a co-requisite in logic design lab, 8. Students will learn programming terminology and will gain a good understanding of the basic mechanics of programming. Ability to write the formal report and to increase the self-confidence of the students (Outcome d1).

The main objective of the course is to acquire the basic concepts of operating systems analysis. 5 Ability to model a number of electrical, mechanical and electromechanical systems, and by studying the basic components of the control system, the course helps produce students with a strong foundation in electrical engineering (Outcome a2). 3) Course content 1 System representation,.

Course Contents 1 System representation,

3 How to apply design control techniques to continuous one-variable systems in the time and frequency domains (Outcome b1). 5 The ability to model a variety of electrical, mechanical and electromechanical systems, and by studying the basic components of the control system, the course helps to produce students of the department with a strong foundation in electrical engineering (Outcome a2). Apply design control techniques to continuous one-variable systems in the time and frequency domain.

Develop the mathematical formulas for handling the different types of direct current machines and transformers (Outcome b1). To develop an understanding of time and frequency domain signal analysis, analog modulation (AM) techniques and their performance in the presence of channel noise in addition to providing an experimental basis for AM's theoretical concepts. Highlight the concepts taught in the machine theory courses and prepare them to do experimental work in their graduation project when needed.

Ability to carry out tests for protective relays and the commissioning tests at the sites (Outcome b1). Ability to recognize various electrical machines taught in the electrical machinery courses and teach them to read the nameplate data of the machines and implement it (Outcome a2). Ability to carry out necessary tests after the manufacture of the machines or the commissioning tests at the sites (Outcome b1).

The ability to choose the appropriate instruments and materials according to the assigned experimental objective (Outcome b1). Highlight the concepts taught in the theoretical courses and prepare them to carry out experimental work in their graduation project when necessary.

Course Contents 1. Orientation

The basic course in electrical engineering introduces the fundamental concepts, principles, and application of digital control system analysis. Topics cover classical control design methods as well as modern control design techniques.

Specialization (Power)

Improve the knowledge for the construction and working principle of the three-phase induction and synchronous machines. To obtain information about the equivalent circuit and various experimental tests of three-phase induction and synchronous machines. Help in dealing with the power ratio and characteristic curves of the three-phase induction and synchronous machines.

To provide an experimental basis for the theoretical concepts introduced in the Electromechanical Energy Conversion theoretical courses. Develop the mathematical formulas used in calculating the voltage regulation and efficiency of synchronous machines (result b1). This course is taught to clearly understand and understand the basic concepts of high voltage generation, measurement and testing techniques.

To provide an experimental basis for the theoretical concepts introduced in the high voltage engineering theory courses. Apply knowledge of mathematics and engineering, especially in the fields of high-voltage engineering, electromagnetics and power engineering (outcome b1). Understand high voltage measurement, direct high voltage measurement, electrostatic voltmeters and ball gaps (outcome a1).

To obtain the laboratory advantages of modeling the actual power system under different load conditions. To provide an experimental basis for theoretical concepts introduced in theoretical power electronics courses such as power converters and rectifier switches. Three-phase voltage converter - Step inverters - six-step converter - PWM converters 5. Current source converters.

Specialization (Communication)

Develop an understanding of digital communication systems and techniques used in digital communication. Knowledge and understanding of the effects of channel failures on digital transmission and the various techniques used to combat these failures (outcome b2). Understanding the trade-offs between data transfer rate and error probability in the design of digital communication systems (outcome b4).

Knowledge and understanding of the effects of channel impairments in digital transmission and the various techniques used to combat these impairments (Outcome b4). To emphasize the concepts of electromagnetics and field theory and to develop the ability to apply these concepts to transmission lines and antennas. Use their skills of various mathematical design techniques to understand the main subjects of electromagnetic wave propagation and antennas (Outcome a1).

Use knowledge of electromagnetic wave propagation and antennas to understand advanced concepts of electromagnetics in the real world (outcome b1). This course provides a comprehensive overview and advanced knowledge of modern cellular and wireless communication systems. The course also provides an understanding of the challenges and opportunities that the wireless medium brings in the design of current and future wireless communication systems and networks.

Based on the system parameters and properties of the wireless medium (result b3), determine the type and appropriate model of the wireless attenuation channel. Determine the appropriate transceiver design for multi-antenna systems and estimate the data rate performance (outcome b3). Understanding the basic principles of Gaussian noise processes and their use/applicability in the design of communication systems (outcome a1, b1).

An ability to design, build, test and analyze circuits and systems relevant to communications systems (outcome b2, b3). 3) Course content.

Specialization (Electronics)

Course Contents 1. Embedded systems,

Be able to apply mathematical methods and circuit analysis models to the analysis of CMOS digital electronics circuits, including logic components and their interconnection (Outcome a1). Apply CMOS technology-specific layout rules when placing and routing transistors and interconnects, and to verify functionality, timing, power and parasitic effects (Outcome b1, b3). Understand the characteristics of CMOS circuit design and compare different state-of-the-art CMOS technologies and processes (Outcome a1).

Be able to complete a significant VLSI design project with a set of objective criteria and design constraints (Outcome b3). Through this course, students will gain awareness of the relevance of PV systems as an alternative energy source. Knowledge of modelling, analysis, design and application of solar cell systems will also be acquired.

Knowledge of Fundamental principles of semiconductor physics related to solar cells and photovoltaic generation (Outcome a1). To apply the knowledge of the modelling, analysis, design and application of photovoltaic systems (Outcome b1).