All COs of EE (UG)

All COs of EE (UG)

Course Outcomes (COs) for Electrical Engineering (UG)

1. Basic Electrical Engineering

• CO1: Understand the basic electrical quantities such as voltage, current, resistance, and power.
• CO2: Apply Kirchhoff’s laws to solve electrical circuits.
• CO3: Analyze series and parallel AC and DC circuits.
• CO4: Understand the working principles of basic electrical machines such as transformers and DC machines.

2. Electrical Circuits and Networks

• CO1: Analyze and simplify electrical networks using various theorems (Thevenin, Norton, Superposition, etc.).
• CO2: Perform transient analysis of RLC circuits.
• CO3: Apply mesh and nodal analysis for solving complex circuits.
• CO4: Model and solve electrical circuits using software tools (e.g., MATLAB, PSpice).

3. Electronic Devices and Circuits

• CO1: Understand the working principles of semiconductor devices such as diodes, transistors, and operational amplifiers.
• CO2: Design and analyze basic amplifier circuits using BJT and FET.
• CO3: Understand the characteristics and applications of oscillators and voltage regulators.
• CO4: Simulate and design simple analog circuits.

4. Electrical Machines I (DC Machines & Transformers)

• CO1: Analyze the construction and operation of DC machines.
• CO2: Understand the working principles and performance characteristics of transformers.
• CO3: Evaluate the efficiency and voltage regulation of DC motors and transformers.
• CO4: Perform experiments and determine machine parameters through testing.

5. Control Systems I

• CO1: Model dynamic systems using transfer functions and block diagrams.
• CO2: Analyze the time-domain response of first and second-order systems.
• CO3: Apply the concept of stability using Routh-Hurwitz and Nyquist criteria.
• CO4: Design compensators and controllers to improve system stability.

6. Signals and Systems

• CO1: Understand and apply the concepts of continuous-time and discrete-time signals.
• CO2: Analyze linear time-invariant systems using convolution and Laplace transforms.
• CO3: Apply Fourier transform and Z-transform techniques for signal analysis.
• CO4: Use software tools to simulate signals and systems.

7. Power Systems I (Generation, Transmission, and Distribution)

• CO1: Understand the basic structure of power systems, including generation, transmission, and distribution.
• CO2: Analyze power system components such as generators, transformers, and transmission lines.
• CO3: Calculate the power flow in a transmission network using mathematical models.
• CO4: Understand the economic aspects and efficiency considerations in power generation.

8. Power Electronics

• CO1: Understand the working of power electronic devices such as diodes, thyristors, and MOSFETs.
• CO2: Design and analyze power electronic circuits such as rectifiers, inverters, and DC-DC converters.
• CO3: Understand the role of power electronics in controlling electrical drives and renewable energy systems.
• CO4: Implement and simulate power electronics circuits using appropriate software tools.

9. Renewable Energy Systems

• CO1: Understand the principles of renewable energy sources such as solar, wind, and hydropower.
• CO2: Analyze the conversion of renewable energy to electrical power.
• CO3: Design and optimize renewable energy systems for grid integration.
• CO4: Evaluate the environmental and economic impacts of renewable energy solutions.

10. Electrical Machines II (AC Machines)

• CO1: Analyze the working principles and applications of three-phase induction motors and synchronous machines.
• CO2: Perform the testing and performance analysis of AC machines.
• CO3: Understand the starting and control methods of induction motors.
• CO4: Evaluate the power factor and efficiency of synchronous generators and motors.

11. Power Systems II (Operation and Protection)

• CO1: Analyze power system protection devices such as circuit breakers and relays.
• CO2: Understand fault analysis and protection schemes for power systems.
• CO3: Study the operation of power systems during fault conditions.
• CO4: Apply principles of system stability to ensure reliable power delivery.

12. Digital Logic Design

• CO1: Understand the basics of digital electronics, Boolean algebra, and logic gates.
• CO2: Design and simplify combinational and sequential circuits.
• CO3: Implement digital circuits using flip-flops, counters, and registers.
• CO4: Design and simulate digital circuits using hardware description languages (HDL).

13. Microprocessors and Microcontrollers

• CO1: Understand the architecture and functioning of microprocessors and microcontrollers.
• CO2: Develop assembly language programs to interface with microcontroller-based systems.
• CO3: Design and implement simple embedded systems using microcontrollers.
• CO4: Interface sensors and actuators for real-world applications in automation.

14. Control Systems II (Advanced Control Theory)

• CO1: Understand and apply the concepts of state-space modeling and control.
• CO2: Analyze stability and performance of control systems using root locus and frequency response techniques.
• CO3: Design state-feedback controllers and observers for system stabilization.
• CO4: Apply control techniques to real-world engineering problems.

15. High Voltage Engineering

• CO1: Understand the principles of high voltage generation, measurement, and testing.
• CO2: Analyze the electrical breakdown of materials and the design of high-voltage equipment.
• CO3: Apply the concept of insulation coordination in power systems.
• CO4: Perform insulation testing and high-voltage equipment design.