30000

This course introduces the fundamental principles of electromagnetics, focusing on the behavior of electric and magnetic fields and their interactions. Topics include electrostatics, magnetostatics, Maxwell's equations, wave propagation, and the behavior of electromagnetic waves in various media. Students will learn about boundary conditions, transmission lines, waveguides, and the fundamentals of electromagnetic radiation.

This course builds upon the concepts introduced in Circuits I, focusing on more advanced topics in electrical circuits. Students will explore AC circuit analysis, including phasors, complex impedance, and the analysis of circuits with sinusoidal sources. Key topics include power analysis, and the use of Laplace transforms in circuit analysis. The course also covers complex power, three-phase power, resonance, two-port networks, frequency response, and Bode plots. Hands-on laboratory experiments will provide students with practical experience in analyzing circuits using oscilloscopes, function generators, and other electronic measurement tools to validate theoretical results.

This course introduces students to the fundamentals of electronic devices and circuits, focusing on semiconductor components and their applications in electronic systems. Topics include the characteristics and operation of diodes, bipolar junction transistors (BJTs), and field-effect transistors (FETs). The course covers key concepts in electronic circuit analysis, including biasing techniques, small-signal analysis, and the design and operation of basic amplifiers, rectifiers, and power supplies.

This course builds upon the concepts introduced in Electronics I, diving deeper into advanced analog and digital electronic circuits. Topics include the analysis and design of more complex amplifiers (e.g., differential, operational amplifier circuits), feedback systems, oscillators, and frequency response. Students will study the behavior of active devices, such as operational amplifiers (Op-Amps), and their applications in analog signal processing, including filters, integrators, and differentiators. The course also covers power amplifiers, transistor amplifier configurations, and feedback theory. Additionally, students will be introduced to digital electronics concepts, including logic gates, combinational circuits, and the basics of digital systems. Laboratory experiments will complement lectures, providing hands-on experience in building, testing, and analyzing analog and digital circuits.

This course introduces embedded systems, focusing on the design, programming, and application of microcontroller-based systems. Students will explore both hardware and software aspects of embedded computing, learning how to develop efficient, real-time, and resource-constrained systems used in modern engineering applications. The course covers microcontroller architecture, interfacing techniques, real-time operating systems (RTOS), and embedded C programming. Students will gain hands-on experience with embedded development tools, peripheral interfacing, and sensor integration.