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Course Criteria
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3.00 Credits
Description: Advanced topics in conbinational logic circuits and synchronous and asynchronous sequential circuits. Topics: functional decomposition, fault detection, machine minimization, state assignment techniques, machine structure, machine testing, and finite state recognizers. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Specialized and advanced topics in computational intelligence. The course will vary and includes fuzzy systems, advanced neural networks, genetic algorithmns, cognitive maps, or chaos theory. This course may be repeated for credit with prior permission. Prerequisite: Permission of instructor. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Hardware system design and modeling including synchronous design techniques, modeling of systems and subsystems at various levels of detail, and the use of hardware descriptive languages. Presentation of a schematic capture tool, VHDL modeling and simulation, and SPICE simulation. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Classification of machines, memory management, caches, buses, pipelining, language directed architecture, RISC architecture, data flow architectures. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8405 Minimum Grade of C and Graduate Engineering level ECE 8440 Minimum Grade of C
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3.00 Credits
Description: In-depth coverage of the advanced architectural features of current and next-generation high-performance computer processors. Topics include superscalar and VLIW design, out-of-order execution, register renaming, caching, value prediction, confidence levels, branch prediction, predication, control speculation, multithreading, compiler optimizations, trace-drive simulator development and case studies of existing processors. A project involves writing a simulator to evaluate the performance of a microprocessor component. Prerequisites: ECE 3445 and C or C++, or permission of the instructor. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Issues associated with embedded system design, focusing on processors and memory hierarchy. The influence of cost, energy consumption, execution time analyzability on processor instruction sets, microarchitecture, and system structure is studied. Requirements: Understanding of processor architecture on the level of ECE 3445 and understanding of system architecture on the level of ECE 8405. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Digital system design concepts with emphasis on high reliability, real-time applications. Hardware/software tradeoffs, programmable logic implementation, single-board and multi-board computer systems designs. Use of CAE techniques, testing and troubleshooting. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8405 Minimum Grade of C and Graduate Engineering level ECE 8425 Minimum Grade of C
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3.00 Credits
Description: Understanding and working knowledge of field programmable logic device structure and architecture. Topics: history of the technology; programmable logic device structure and architecture (for SPLDs, CPLDs and FPGAs); tools for design and simulation; and application to real world problems. Hands-on experience is gained via implementation of a student project. Prerequisite: Fundamentals in logic design. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering
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3.00 Credits
Description: Study of the architecture of various DSP chips and circuits necessary for the implementation of real-time signal processors and digital filters. Case studies and a student design project are taken from the areas of speech processing, image processihng and communiation signal processing. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 8231 Minimum Grade of C and Graduate Engineering level ECE 8425 Minimum Grade of C
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3.00 Credits
Description: Design introduction to concepts of NMOS and CMOS VLSI design. Design and layout concepts, testability, PLA's, scaling, and simulation. Emphasis is on silicon system design and layout with some analysis. CAD tools are introduced and used throughout the course. A project is required. Prerequisite: Permission of instructor. Design introduction to concepts of CMOS VlSI design. Design and layout concepts, properties of digitial circuits, scaling, and simulation. Emphasis is on deep submicron silicon system design and layout with circuit analysis. CAD tools are introduced and used throughout the course. A project is required. 3.00credit(s) Restrictions: Must be enrolled in one of the following Levels: Graduate Engineering Prerequisites: Graduate Engineering level ECE 7500 Minimum Grade of C
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