
Discover the basics of MATLAB and Simulink, building models with library blocks and scopes. Learn to simulate electrical, mechanical, and power electronics systems using common blocks and sources.
Explore single-phase full-wave bridge rectifiers, from uncontrolled four-diode bridges to fully and semi controlled designs using firing angle alpha, and examine current paths and output voltage.
Explore simulating a three-phase half-wave rectifier in MATLAB/Simulink, comparing uncontrolled and fully controlled configurations, using a three-phase source, an RLC load, measurements, and pulse-generator firing angles.
This lecture reviews three-phase full-wave rectifiers, comparing uncontrolled six-diode bridge circuits with controlled thyristor bridges, explains conduction sequences and firing angles, and discusses output voltage in MATLAB simulations.
Simulate a single-phase ac voltage controller with a resistive load in unidirectional and bidirectional modes using back-to-back switching in Simulink, and observe output voltage and current with measurements and oscilloscope.
Simulate a simple DC chopper circuit in MATLAB/Simulink to observe voltage and current. Adjust duty cycle with a pulse generator to see voltage regulation and discuss buck and boost converters.
Generate a duty cycle for power electronics in MATLAB Simulink by comparing a reference signal with a sawtooth carrier, producing pulses with D = Vref/Vpeak.
Simulate a boost converter in MATLAB Simulink, converting 20 V to 100 V at 5 kHz, and examine inductance and capacitance effects on continuous vs discontinuous current.
Construct and simulate a push-pull converter in Simulink, adjusting midpoint transformers and turns ratios to achieve 200 V dc output with an LC filter at 5 kHz and 50% duty.
Simulate a 1-phase bridge inverter with an R-load in Simulink using mosfets, pwm pulses, and voltage and current measurements. Compare two configurations: two dc sources or a split capacitor supply.
Explore how to apply Fourier transform analysis in MATLAB/Simulink to decompose inverter output voltage and current into fundamental and harmonic components, compute harmonic factors and total harmonic distortion.
Apply phase shift modulation to a single-phase full-bridge inverter in MATLAB Simulink to adjust the output voltage by shifting Q2's gate signal by an angle alpha.
Describe unipolar sinusoidal PWM for a single-phase bridge inverter, generating individual gating signals for Q1–Q4 via carrier triangle and reference sine, and simulating the scheme in MATLAB Simulink.
Design a three-phase inverter using sinusoidal PWM in MATLAB/Simulink to generate pure sinusoidal three-phase voltages, with LC filters, phase shifting, and measurement of voltages before and after filtering.
Simulate an RC circuit in MATLAB/Simulink, building a model with a controlled voltage source, resistor, and capacitor, and observe outputs with a scope while experimenting with pulse and square-wave signals.
Hi my friend!
This course is designed to provide a complete step by step MATLAB simulations for various electrical engineering disciplines in ONE course so that it will be a comprehensive guide for you to build and design your own models.
In this course, you are going to learn MATLAB/Simulink for:
Power Electronics Simulations
Simulations of 1-phase rectifiers (controlled, uncontrolled, HWR and FWR)
Simulations of 3-phase rectifiers
Complete Simulations of AC voltage controllers ( 1-ph & 3-ph)
How to apply closed loop control of AC voltage controllers in MATLABl/Simulink
Complete MATLAB simulations of DC-DC converters
Apply PID controller to DC-DC converters in MATLAB/Simulink
Apply Hysteresis controller to DC-DC converters in MATLAB/Simulink
Design different DC Regulators in MATLAB/Simulink
Simulations of 1-ph inverter circuits (half bridge and full bridge)
Apply pulse width modulation (PWM) techniques in MATLAB/Simulink
Simulations of 3-ph inverter circuits
Electrical Circuits Simulations
Simulations of DC transient circuits
Simulations of R-L , R-C , R-L-C circuits
Applying forced and free response in transient circuits in Simulink
Simulations of the Electric Resonance in MATLAB/Simulink
Electrical Machines Simulations
Complete MATLAB Simulations of DC motors (shunt, series and separately excited)
Speed control of DC motors in MATLAB/Simulink
Starting of DC motors using starters in MATLAB/Simulink
Simulations of DC generators
Complete simulations of Induction motors
Speed control and starting of induction motors in MATLAB/Simulink
Apply VFD with induction motors in MATLAB/Simulink
Perform different induction motor tests in MATLAB/Simulink
Complete simulations of Induction generators
Complete MATLAB simulations of synchronous machines
Apply voltage and frequency control of synchronous generator in Simulink
Simulations of synchronous generator connected with grid
Simulation of permanent magnet synchronous motors (PMSM)
Simulations of transformers (1-ph & 3-ph) in MATLAB/Simulink
Efficiency, losses and voltage regulation of transformer in Simulink
Open circuit and short circuit tests of transformers in MATLAB/Simulink
Power Systems Simulations
Modelling and design of transmission lines in MATLAB/Simulink
load flow analysis in MATLAB/Simulink
Symmetrical and unsymmetrical fault analysis in MATLAB/Simulink
Logic design of overcurrent relay in MATLAB/Simulink
Apply overcurrent protection against power system faults in MATLAB/Simulink
Solar Energy Simulations
Step by step modelling and design of solar panels in Simulink
Obtain I-V and P-V characteristics of solar panel in MATLAB
Effect of irradiation and temperature on PV cell characteristics in MATLAB
How to simulate solar panel using MATLAB Simscape library
Wind Energy Simulations
Step by step Wind turbine modelling and design in MATLAB/Simulink
Design of 5KW wind turbine in MATLAB/Simulink
Effect of wind turbine parameters on turbine power in MATLAB/Simulink
By the end of this course, you will be specialized in dealing with MATLAB/Simulink related to various
electrical engineering branches.
I thank you very much for taking the time to check the course content.
See you in the course !