With lab. Electromagnetic theory applied to microwave propagation in waveguides, coaxial lines, microstrip lines, and striplines. Microwave circuit theory applied to matching networks and passive microwave devices. S-parameters, ABCD parameters, couplers, and equivalent circuits.

With lab. Electromagnetic theory applied to microwave propagation in waveguides, coaxial lines, microstrip lines, and striplines. Microwave circuit theory applied to matching networks and passive microwave devices. S-parameters, ABCD parameters, couplers, and equivalent circuits.

With lab. Electromagnetic theory applied to microwave propagation in waveguides, coaxial lines, microstrip lines, and striplines. Microwave circuit theory applied to matching networks and passive microwave devices. S-parameters, ABCD parameters, couplers, and equivalent circuits.

With lab. Electromagnetic theory applied to microwave propagation in waveguides, coaxial lines, microstrip lines, and striplines. Microwave circuit theory applied to matching networks and passive microwave devices. S-parameters, ABCD parameters, couplers, and equivalent circuits.

Time domain and frequency domain analysis and synthesis techniques for linear continuous-time feedback control systems. Topics include benefits and costs of feedback, modeling of dynamic systems,steady-state and transient performance, stability, PID control, root locus, frequency response, Nyquist stability cri-terion, and introduction to loop-shaping.

Introduction to fundamental biological neuron models, algorithms and techniques for learning spatiotemporal patterns, and software frameworks for implementing spike-based computation. Understanding of the hardware foundation for bio-inspired computation from transistors and emerging devices to neuromorphic circuits and systems. Investigation of low-power, low-latency applications of neuromorphic engineering in machine vision, robotics, autonomous vehicles, etc.

This course is the first introductory course in the field of photonics and introduces students to the fundamental operating principles of optical components and photonic devices. Three different descriptions of optical propagation and interaction (geometrical optics, wave optics, and electromagnetic optics) with increasing complexity and accuracy are presented. Physical phenomena and photonic devices whose operation can be described within the scope of each theory are introduced and discussed.

Quantitative study of pipelined processor architectures, memory hierarchy, cache memory, Input/Output, RISC processors and vector machines. Prerequisite: E&C-ENG 232.

The course presents a modern approach to logic design and verification of digital circuits. Topics in logic synthesis cover high-level and architectural synthesis, decision and word-level diagrams, combinational and sequential logic optimization. Topics in verification include: simulation-based validation and functional test generation; formal verification techniques; combinational and sequential equivalence checking; and Boolean satisfiability (SAT). Prerequisite: introductory digital circuits; hardware design and organization (undergraduate level). Open to senior undergraduate students.

The field of Image Processing is concerned with the study of computational approaches for the analysis, storage, and interpretation of digital content. In modern times, Image Processing applications have expanded to include an assortment of fields ranging from medical diagnostics to remote sensing to AI. This course introduces students to basic concepts and techniques in digital image processing. Topics covered will include characterization and representation of digital images, image enhancement, image restoration, image analysis, and image segmentation.