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characteristics of a series of analog sensors and digital transducers are studied. Finally, the stepper motors as well as continuous-drive actuators (DC and AC motors) are covered. GECE 531 Electronic Systems Design & Integration 3 credits This is a hands-on laboratory-based course with emphasis on design and integration of electronic systems. Industry-standard tools such as the circuit simulation software (e.g. Orcad Capture CIS, PSpice), the Printed Circuit Board (PCB) design software (e.g. Cadence Layout Plus), PCB maker (e.g. LPKF ProtoMat), and its related software (e.g. CircuitCam) will provide the platform to build, test, and validate systems/subsystems, such as basic OP-AMP circuits, analog computer, traffic light control, power subsystems, bridge driver subsystem, and driver system integration. Electronic systems design and integration will be emphasized through laboratory projects. GECE 537 Advanced Computer Architecture 3 credits Focuses on the design and implementation of the instruction-set architecture. Performance measures, ALU design, data and control path design, evolving into custom high performance processor design using VHDL, pipelining, memory hierarchy design, cache memory and advanced topics. GECE 545 Advanced Digital Design 2 credits* GECE 546 Advanced Digital Design Lab 1 credit* GECE 547 Embedded Systems Design 2 credits* GECE 548 Embedded Systems Design Laboratory 1 credit* GECE 549 VHDL 3 credits* GECE 552 Data Integrity on Computer Networks 3 credits This course provides the concepts, theory (algorithms) and techniques (protocols/standard) to delivery data integrity on computer networking. Topics include Data Integrity on data communication (i.e., Transmission Media, and Transmission and Multiplexing) and on computer network (i.e., Data Security, Flow Control, Wire/Wireless network, and Internet Protocols/ Applications/Programming). Students perform Data Integrity on data communication (1/2) and on computer network (1/2). GECE 556 RF Circuit Integration 3 credits Application of concepts from Circuits, Electronics and Fields to
radio frequency design techniques as applied to state-of-the-art electronic devices. GECE 565 Power Electronics 3 credits This course introduces the basic concepts of various topologies (acdc, dc-dc, dc-ac, ac-ac, etc.) of power converters. The fundamental principles of switching components are discussed first prior to introduction of the design and application of the converters. Emphases are on the design issues associated with the converters and the computer techniques (PSpice) used for the performance evaluation and analysis. Experiments are part of the course. GECE 566 Modeling and Analysis of Electric Drives 3 credits This course introduces the issues on modeling and analysis of electrical drives. Basic concepts of electromechanical energy conversion will be presented prior to the detailed modeling of the dynamical aspects of both the DC and AC machines. Dynamic behavior of the machines and their computer simulation will be examined. Numerical schemes for simulation, singular perturbation technique, linearization technique, etc. are parts of the analysis tools. In addition, modeling of switching power conversion will be studied as it pertains to drive application. If time permits, some other practical aspects of drives will be examined, too. GECE 567 Integration of Renewable Energy into Electric Power System 3 credits This course is designed to provide general technical education in all major electricity generating with renewable energy sources and their integration in electric power systems. Different types of renewable energy resources will be studied for the following aspects: the available form, the feature of electricity generation, how to integrate into electric power system, and the impact on the electric power system, etc. The course also stresses the importance of power electronics technology in the process of power conditioning and controlling. The decentralized electric power system concept will be introduced. The future development of renewable energy technologies and the way that power systems may evolve to accommodate them will be discussed. GECE 572 Digital Signal Processing 3 credits This course emphasizes the fundamental principles of signal and systems, sampling theorem, discrete-time Fourier transform, power spectrum, z-transform, discrete Fourier transform (DFT) and the FFT algorithm, digital filter design and implementation. GECE 573 Introduction to Neural Networks 3 credits Data management, pattern recognition and classification, neural networks models, learning schemes, genetic algorithms, applications of neural networks.