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Course Criteria
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3.00 Credits
Students will complete a series of assigned design projects that rely on background in the areas microprocessors, electronics and signals and systems. Lecture will focus on various aspects of the design process as well as discussion of component characteristics. Prerequisites: EECE 252, EECE 301, and EECE 315. spring, 3 cr.
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3.00 Credits
Covers the general area of discrete-time signals and the analysis and design of discrete time systems. Topics include time domain analysis, solutions of difference equations, Z�transform analysis, sampling of continuous-time signals, discrete Fourier transforms, Fast Fourier Transforms, and spectral analysis. Processing of discrete-time signals using the DFT and FFT. Design and implementation of discrete-time filters. Extensive use of software simulations in a high-level language such as Matlab. Technical elective. Prerequisite: EECE 301. spring, 3 cr.
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3.00 Credits
Introduction to codes and ciphers, and information security. Cryptanalysis (code-breaking), modern block and stream ciphers, public-key cryptography, protocols, security engineering and threat management. Key exchange, digital cash, digital voting, anonymity protocols. Technical elective. Prerequisite: ISE 261 or MATH 327 and CS 211. fall, 3 cr.
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3.00 Credits
Active and passive circuits, bias point and small signal analysis. Frequency response and transient characteristics of electronic circuits. Feedback and stability. Electronic circuit design and system applications (multistage amplifiers, active filters, etc.), numerical simulations. Technical elective. Prerequisite: EECE 315. spring, 3 cr.
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3.00 Credits
Electronic processing of electrical energy. Overview of power electronics devices such as DMOSFET, IGBT and Thyristor. Power supply circuits from AC or DC sources as used in computers, inverters and variable-speed motor drives. Analytical and numerical techniques for simulation. Technical elective. Prerequisites: EECE 315 and EECE 361. fall, 3 cr.
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3.00 Credits
Overview of the components of system?on-a-chip (SOC) design from initial technology and architectural choices, to SOC implementation issues (e.g., performance, core selection, on-chip communication networks, power management, package constraints and cost). Also covered are SOC design and implementation processes (e.g., functional integration, simulation, clocking strategies, timing, design for test and debug strategies). Prerequisites: EECE 252 and EECE 315. spring, 3 cr.
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3.00 Credits
In this course we focus on the design and synthesis technologies using Verilog Hardware Description Language (HDL) at the Register-Transfer level (RTL). Verilog programming and simulation basics will be discussed, followed by advanced Verilog programming for synthesis. Principles of RTL synthesis will be introduced. The Design Compiler synthesis tool from Synopsys will be discussed in detail. In the final project, 3~4 person teams will be formed and work on the design and synthesis of a large-scale digital circuit using Design Compiler. The pre-synthesis and post-synthesis results will be verified by the ModelSim software. Prerequisite: EECE 351. fall, 3 cr.
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3.00 Credits
The topics include the principles of MOSFET transistors, characteristics of CMOS digital circuits, layout design and process, performance analysis of CMOS gates, circuit design styles using MOSFET, performance and area and power optimization of CMOS circuits. Commercial design and simulation tools will be used in the class. Laboratory assignments include design, layout, extraction and simulation. Prerequisite: EECE 351. fall, 3 cr.
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3.00 Credits
Introduction to security engineering, systemic analysis and common design principles. Cryptography, multilevel security, system evaluation, real-world vulnerabilities and attacks. Prerequisites: EECE 252 or CS 220, familiarity with C or C++ or similar programming language. spring, 3 cr.
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3.00 Credits
Introduces principles and practices in computer and communication networks. Emphasis is on the design, implementation and management of IP backbone networks (the Internet), wired/wireless LANs and mobile communication networks. Topics include: major network implementations, Internet protocols, LAN standards, network elements (switches, routers, bridges and gateway), EMS/NMS, network security and other current research topics. Prerequisites: EECE 301 and ISE 261. spring, 3 cr.
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