2. David Beazley and Brian K. Jones, Python Cookbook, 2017 19EE2006
Computer Simulation of Electrical Systems
L 1
T 0
P 4
C 3
Course Objectives 1. To provide students with a strong background on Matlab/PSPICE/Labview software. 2. To impart practical working knowledge of electrical and electronics simulation and analysis using simulation software 3. To prepare the students to use Matlab/Labview in their project work and in real time applications. Course Outcomes At the end of the course, the student will be able to 1. Understand the main features of the MATLAB programming environment. 2. Apply working knowledge of MATLAB package to simulate and solve electrical, electronic circuits and applications. 3. Solve, Simulate and Analyse various network theorems and electric circuits. 4. Identify & formulate solutions to problems relevant to power system using software tools. 5. Simulate various converter/inverter circuits. 6. Solve, Simulate and Analyse various Analog Electronic circuits. Module 1: Basic of MATLAB Module 2: Basics of MATLAB/SIMULINK Module 3: Electric Circuits and Network Theorems Module 4: Power System Blockset Module 5: Power Electronic Circuits Module 6: Analog and Digital Circuits-Introduction Software Tools: MATLAB/ SIMULINK SOFTWARE List of Experiments (Any twelve from the list) 1. Simulation of Transient response of RL and RC Circuit with step and sinusoidal input signals 2. Simulation of Transient response of RLC Circuit with Step and sinusoidal input signals 3. Verification of Network theorems (Superposition theorem, Thevenin’s theorem and Maximum power transfer theorem) 4. Load flow studies using MATLAB with Power system tool box (Power System load flow using Newton-Raphson Technique). 5. Fault analysis using MATLAB with Power system tool box (Balanced 3-φ fault, Single line to ground fault, Line to line fault, Double line to ground fault) 6. Plotting of Bode plots, Root Locus and Nyquist plots for the transfer functions of systems up to 5th order using MATLAB with Control system tool box software 7. Speed control of Separately excited DC motor 8. Simulation of Solar PV Model using Matlab / Simulink 9. Simulation of Single-Phase full converter using RLE loads 10. Simulation of Single-phase AC Voltage Controller using RL loads. 11. Simulation of Single-Phase Inverter with PWM control. 12. Simulation of Buck & Boost converters. 13. Modeling of Transformer and simulation of lossy transmission line 14. Simulation of Op-Amp based Differentiator and Integrator Circuit 19EE2007
Electrical Machine Design
Course Objectives 1. To gain knowledge on the design aspects of Electrical Machines. 2. To study the design procedure of DC and AC machines. 3. To know the analysis of electrical machines. ELECTRICAL AND ELECTRONICS ENGINEERING (2020)
L 3
T 0
P 0
C 3
