Faculty : Faculty of Engineering and Applied Sciences

School : Mechatronics and Robotics Engineering

Course Description :

Introduction to control systems and feedback - Mathematical modeling of feedback control systems - Transfer function - Block Diagrams -State variable models - Transient response - Steady state response - Steady state error - Routh stability criterion - Root locus method - Performance criteria - Frequency response (Polar plot - Bode plot) - Nyquist Stability criterion - Gain margin and phase margin - Design and Compensation of Control Systems: Design in the Time-Domain and in the Frequency Domain, PID, Phase-Lead, Phase-Lag Controllers, Case studies using MATLAB software package.

Faculty : Faculty of Engineering and Applied Sciences

School : Mechatronics and Robotics Engineering

Course Description :

Time and frequency response of DC servo motor - Position and Speed control of DC servo motor - PID control design of DC servo motor - System modeling and system identification of Magnetic levitation system - PID control design of Magnetic levitation system - Time and frequency response of Digital Pendulum - Modeling and PID control of Digital Pendulum - Measurement of system dynamics of Ball & Beam apparatus by transient and closed loop methods - Design of analogue phase - lead compensators for Ball & Beam apparatus - Applications of MATLAB to Control Systems analysis and design.

Faculty : Faculty of Engineering and Applied Sciences

School : Electronics and Communications Engineering

Course Description :

Introduction to information theory, review of noise, probability of error, entropy, Shannon's channel capacity, compression theory and examples of compression algorithms. Introduction to channel coding theory and error correcting codes: block codes and convolutional codes. Exposure to advanced error control coding techniques. Examples of applications of error correcting codes in communication systems.

Faculty : Faculty of Engineering and Applied Sciences

School : Electronics and Communications Engineering

Course Description :

Hands on experience using software and hardware in topics related to: probability of error, entropy, Shannon's channel capacity, compression theory and examples of compression algorithms. Introduction to channel coding theory and error correcting codes: block codes and convolutional codes. Exposure to advanced error control coding techniques. Examples of applications of error correcting codes in communication systems. The Lab may include tutorials and exercises

Faculty : Faculty of Engineering and Applied Sciences

School : Electronics and Communications Engineering

Course Description :

Introduction to radio communication systems. Frequency selective circuits and transformers; Parallel resonant circuits including transformers; Double-tuned circuits; Impedance matching. Oscillators. Conditions for oscillation; Amplitude limitation mechanisms; Phase stability; Crystal oscillators; Mixers; Diode-ring mixers; Square-law mixers; BJT mixers; Intermodulation distortion; Modulators and demodulators; Broadband techniques; Neutralization; Phase-lock loops; Phase detectors; Voltage-controlled oscillators; Loop filters; Phase-locked loop applications; Power amplifiers. Laboratory include testing of: RF Amplifier, Local OSC & Mixer, BPF, IF Amp, FM Detector, Power Amp.