COMPUTER ENGINEERING - COURSE DESCRIPTIONS
ECE 160 Engineering Practice 0R-4L-2C F,W
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
An introduction to electrical and computer engineering, systems engineering design, programming, microcontrollers, soldering and circuit building. Students will work individually and on teams to complete projects and create a system for an end of term competition. Students will also learn about technical documentation and communication. Topics include functions, arrays, conditionals, loops, Boolean algebra, wireless communication, resistors, transistors, diodes motors, sensor, analog and digital inputs and outputs.
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
An introduction to electrical and computer engineering, systems engineering design, programming, microcontrollers, soldering and circuit building. Students will work individually and on teams to complete projects and create a system for an end of term competition. Students will also learn about technical documentation and communication. Topics include functions, arrays, conditionals, loops, Boolean algebra, wireless communication, resistors, transistors, diodes motors, sensor, analog and digital inputs and outputs.
ECE 180 Introduction to Signal Processing 3R-3L-4C F,W,S
Prerequisites: MA 112, and ECE 160 or CSSE 120 or ENGD 120 or ME 123 or prior programming experience
Corequisites: There are no corequisites for this course.
An introduction to discrete-time signal processing applied to audio, images, and video. Topics include phasor representation of sinusoidal signals, complex arithmetic, sampling, signal spectra, linear time-invariant systems, frequency response, convolution, filter implementation, and MATLAB programming. Integral laboratory.
Prerequisites: MA 112, and ECE 160 or CSSE 120 or ENGD 120 or ME 123 or prior programming experience
Corequisites: There are no corequisites for this course.
An introduction to discrete-time signal processing applied to audio, images, and video. Topics include phasor representation of sinusoidal signals, complex arithmetic, sampling, signal spectra, linear time-invariant systems, frequency response, convolution, filter implementation, and MATLAB programming. Integral laboratory.
ECE 199 Professional Experience 1R-0L-1C
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
The professional experiences course captures the practical work experiences related to the student鈥檚 academic discipline. Students are required to submit a formal document of their reflections, which communicates how their employment opportunity reinforced and enhanced their academic studies. The course will be graded as 鈥淪鈥 satisfactory, or 鈥淯鈥 unsatisfactory based on the written report of the professional experience.
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
The professional experiences course captures the practical work experiences related to the student鈥檚 academic discipline. Students are required to submit a formal document of their reflections, which communicates how their employment opportunity reinforced and enhanced their academic studies. The course will be graded as 鈥淪鈥 satisfactory, or 鈥淯鈥 unsatisfactory based on the written report of the professional experience.
ECE 203 DC Circuits 3R-3L-4C S, F
Prerequisites: MA 111, and PH 112
Corequisites: There are no corequisites for this course.
A review of the definition of voltage, current, energy and power. An introduction to Ohm鈥檚 Law, ideal DC independent and dependent voltage and current sources, resistors, inductors, capacitors, and operational amplifiers. Circuit analysis and simplification by using series, parallel, and Wye-Delta reduction, Kirchhoff鈥檚 laws, mesh and nodal analysis, Thevenin, Norton and Maximum Power Theorems, superposition, and source transformations. An integral laboratory to build electric circuits and measure voltage, current, resistance and power.
Prerequisites: MA 111, and PH 112
Corequisites: There are no corequisites for this course.
A review of the definition of voltage, current, energy and power. An introduction to Ohm鈥檚 Law, ideal DC independent and dependent voltage and current sources, resistors, inductors, capacitors, and operational amplifiers. Circuit analysis and simplification by using series, parallel, and Wye-Delta reduction, Kirchhoff鈥檚 laws, mesh and nodal analysis, Thevenin, Norton and Maximum Power Theorems, superposition, and source transformations. An integral laboratory to build electric circuits and measure voltage, current, resistance and power.
ECE 204 AC Circuits 3R-3L-4C F,W
Prerequisites: PH 113*, and either ECE 203** or ENGD 120** or BE 131**, or both ES 213**, and ES 213L** *Prerequisite or concurrent registration **with a grade of C or better
Corequisites: There are no corequisites for this course.
Capacitance, Self and Mutual Inductance. Root-mean-square values of waveforms. Application of phasors to sinusoidal steady-state. Impedance of circuit elements. Mesh and Nodal Analysis applied to ac circuits. Thevenin and Norton theorems applied to ac circuits. Single-phase ac power. Power factor correction. Voltage regulation and efficiency of feeders. Balanced three-phase systems. Ideal and non-ideal transformer models. Integral laboratory.
Prerequisites: PH 113*, and either ECE 203** or ENGD 120** or BE 131**, or both ES 213**, and ES 213L** *Prerequisite or concurrent registration **with a grade of C or better
Corequisites: There are no corequisites for this course.
Capacitance, Self and Mutual Inductance. Root-mean-square values of waveforms. Application of phasors to sinusoidal steady-state. Impedance of circuit elements. Mesh and Nodal Analysis applied to ac circuits. Thevenin and Norton theorems applied to ac circuits. Single-phase ac power. Power factor correction. Voltage regulation and efficiency of feeders. Balanced three-phase systems. Ideal and non-ideal transformer models. Integral laboratory.
ECE 205 Circuits & Systems 3R-3L-4C W,S
Prerequisites: ECE 180 or BE 321, and HUM H190, and MA 222, and either ECE 203* or ENGD 120*, or both ES 213*, and ES 213L* *with a grade of C or better; ** or concurrent registration
Corequisites: There are no corequisites for this course.
Introduction to 1st and 2nd order circuits and review of differential equations. Bode plots. System classification, impulse and step response, convolution. Laplace and inverse Laplace transforms, block and signal flow diagrams. Benefits of feedback. Modeling and simulating electrical systems. Matlab and Simulink. Integral laboratory.
Prerequisites: ECE 180 or BE 321, and HUM H190, and MA 222, and either ECE 203* or ENGD 120*, or both ES 213*, and ES 213L* *with a grade of C or better; ** or concurrent registration
Corequisites: There are no corequisites for this course.
Introduction to 1st and 2nd order circuits and review of differential equations. Bode plots. System classification, impulse and step response, convolution. Laplace and inverse Laplace transforms, block and signal flow diagrams. Benefits of feedback. Modeling and simulating electrical systems. Matlab and Simulink. Integral laboratory.
ECE 206 Elements of Electrical Engineering 4R-0L-4C W,S
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
A course designed for engineers (other than electrical or computer) covering analysis of passive circuits, introduction to op-amps, instrumentation, sinusoidal steady-state, a-c power, and induction motors. EE and CPE majors may not take this course.
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
A course designed for engineers (other than electrical or computer) covering analysis of passive circuits, introduction to op-amps, instrumentation, sinusoidal steady-state, a-c power, and induction motors. EE and CPE majors may not take this course.
ECE 230 Introduction to Embedded Systems 3R-3L-4C W,S
Prerequisites: ECE 233, CSSE 120, and ECE 160
Corequisites: There are no corequisites for this course.
Sensors and actuators. Input and output devices. Microcontroller architecture. Standard communications protocols. Interrupt generation and processing. Data representation and storage. Memory management. The C programming language and programming styles. Integral laboratory and a term project.
Prerequisites: ECE 233, CSSE 120, and ECE 160
Corequisites: There are no corequisites for this course.
Sensors and actuators. Input and output devices. Microcontroller architecture. Standard communications protocols. Interrupt generation and processing. Data representation and storage. Memory management. The C programming language and programming styles. Integral laboratory and a term project.
ECE 233 Introduction to Digital Systems 3R-3L-4C F, W, S
Prerequisites: CSSE 120 or ECE 160 or ENGD 120
Corequisites: There are no corequisites for this course.
Number systems, Binary arithmetic, logic gates, forming logic circuits. Boolean algebra, Karnaugh maps. Propagation delay, hazards, common Combinational logic circuits, structures, and design. Contraction, latches, flip-flops, finite state machines, counters, Sequential circuit timing, and designing Sequential circuits. Register design, control and datapath design. Basic computer architecture, including memory. Integral laboratory.
Prerequisites: CSSE 120 or ECE 160 or ENGD 120
Corequisites: There are no corequisites for this course.
Number systems, Binary arithmetic, logic gates, forming logic circuits. Boolean algebra, Karnaugh maps. Propagation delay, hazards, common Combinational logic circuits, structures, and design. Contraction, latches, flip-flops, finite state machines, counters, Sequential circuit timing, and designing Sequential circuits. Register design, control and datapath design. Basic computer architecture, including memory. Integral laboratory.
ECE 250 Electronic Device Modeling 3R-3L-4C S,F
Prerequisites: ECE 204 or ECE 205, * with grade of B or better ES 213*, and ES 213L* * with grade of B or better
Corequisites: There are no corequisites for this course.
Modeling, analysis, and simulation of electronic circuits that contain two-terminal and threeterminal semiconductor devices. Large-signal, biasing, and small-signal analysis models. Introduction to wave shaping circuits, switching circuits, and amplifiers. Integral laboratory.
Prerequisites: ECE 204 or ECE 205, * with grade of B or better ES 213*, and ES 213L* * with grade of B or better
Corequisites: There are no corequisites for this course.
Modeling, analysis, and simulation of electronic circuits that contain two-terminal and threeterminal semiconductor devices. Large-signal, biasing, and small-signal analysis models. Introduction to wave shaping circuits, switching circuits, and amplifiers. Integral laboratory.
ECE 300 Continuous-Time Signals & Systems 3R-3L-4C F, S
Prerequisites: ECE 205, and MA 222, and MA 381* *Prerequisite or concurrent registration
Corequisites: There are no corequisites for this course.
Signal modeling. Fourier series and Fourier transforms. Response of systems to periodic and aperiodic signals. Filter characterization and design. Ideal and practical sampling. Use of numerical analysis software. Integral laboratory
Prerequisites: ECE 205, and MA 222, and MA 381* *Prerequisite or concurrent registration
Corequisites: There are no corequisites for this course.
Signal modeling. Fourier series and Fourier transforms. Response of systems to periodic and aperiodic signals. Filter characterization and design. Ideal and practical sampling. Use of numerical analysis software. Integral laboratory
ECE 310 Communication Systems 3R-3L-4C W, S
Prerequisites: ECE 380
Corequisites: There are no corequisites for this course.
Transmission of information over bandlimited, noisy communication channels. Line codes, probability of error, intersymbol interference. Modulation techniques, synchronization and frequency conversion. Integral laboratory.
Prerequisites: ECE 380
Corequisites: There are no corequisites for this course.
Transmission of information over bandlimited, noisy communication channels. Line codes, probability of error, intersymbol interference. Modulation techniques, synchronization and frequency conversion. Integral laboratory.
ECE 312 Communication Networks 4R-0L-4C F, W
Prerequisites: MA 381, and CSSE 120
Corequisites: There are no corequisites for this course.
Layered architectures. Circuit and packet switching. The ISO Reference Model. Point-to-point protocols, error control, framing. Accessing shared media, local area networks. Virtual circuits, datagrams, routing, congestion control. Queuing theory. Reliable message transport, internetworking.
Prerequisites: MA 381, and CSSE 120
Corequisites: There are no corequisites for this course.
Layered architectures. Circuit and packet switching. The ISO Reference Model. Point-to-point protocols, error control, framing. Accessing shared media, local area networks. Virtual circuits, datagrams, routing, congestion control. Queuing theory. Reliable message transport, internetworking.
ECE 320 Linear Control Systems 3R-3L-4C W,S
Prerequisites: ECE 300*, and ECE 230* or ME 430*
Corequisites: There are no corequisites for this course.
Analysis of linear control systems using classical and modern control theories in both continuous and discrete time. Plant representation, closed loop system representation, time response, frequency response, concept of stability. Root locus, Bode, and Nyquist methods. Computer modeling and simulation of feedback systems, implementation of discrete-time algorithims on microcontrollers.
Prerequisites: ECE 300*, and ECE 230* or ME 430*
Corequisites: There are no corequisites for this course.
Analysis of linear control systems using classical and modern control theories in both continuous and discrete time. Plant representation, closed loop system representation, time response, frequency response, concept of stability. Root locus, Bode, and Nyquist methods. Computer modeling and simulation of feedback systems, implementation of discrete-time algorithims on microcontrollers.
Prerequisite Notes:
ECE300 and either ECE230 or ME430
ECE 332 Computer Architecture II 4R-0L-4C W, S
Prerequisites: CSSE 232
Corequisites: There are no corequisites for this course.
Instruction-Level Parallelism. Pipelining. Data Hazards. Exceptions. Branch Prediction. Multilength Instructions. Loop Unrolling. TI C6000 Digital Signal Processor. Cache. Memory. MSP430 Microcontroller. PIC Microcontroller. Intel Itanium. Multiprocessors. Hardware Multithreading. Graphics Processors. Supercomputers.
Prerequisites: CSSE 232
Corequisites: There are no corequisites for this course.
Instruction-Level Parallelism. Pipelining. Data Hazards. Exceptions. Branch Prediction. Multilength Instructions. Loop Unrolling. TI C6000 Digital Signal Processor. Cache. Memory. MSP430 Microcontroller. PIC Microcontroller. Intel Itanium. Multiprocessors. Hardware Multithreading. Graphics Processors. Supercomputers.
ECE 340 Electromagnetic Fields 4R-0L-4C F,W
Prerequisites: ECE 204 , and MA 222
Corequisites: There are no corequisites for this course.
Static and dynamic fields. Electric and magnetic properties of materials. Energy, force and power. Resistors, capacitors, and inductors. Application in sensing and actuation. Maxwell鈥檚 equations. Introduction to electromagnetic waves. Use of vector calculus and numeric approximation. Technical reports and/or term papers.
Prerequisites: ECE 204 , and MA 222
Corequisites: There are no corequisites for this course.
Static and dynamic fields. Electric and magnetic properties of materials. Energy, force and power. Resistors, capacitors, and inductors. Application in sensing and actuation. Maxwell鈥檚 equations. Introduction to electromagnetic waves. Use of vector calculus and numeric approximation. Technical reports and/or term papers.
ECE 341 Electromagnetic Waves 4R-0L-4C W,S
Prerequisites: ECE 340
Corequisites: There are no corequisites for this course.
Wave propagation and reflection. Power and lossy materials. Quasistatic analysis. Steady-state and transient analysis of transmission lines. Application in high-speed systems. Introduction to antennas. Technical reports and/or term papers.
Prerequisites: ECE 340
Corequisites: There are no corequisites for this course.
Wave propagation and reflection. Power and lossy materials. Quasistatic analysis. Steady-state and transient analysis of transmission lines. Application in high-speed systems. Introduction to antennas. Technical reports and/or term papers.
ECE 342 Introduction to Electromagnetic Compatibility 3R-3L-4C F,S
Prerequisites: ECE 300 and Computer Engineering Major
Corequisites: There are no corequisites for this course.
Electromagnetic compatibility (EMC) regulations and measurement. Frequency behavior of passive components. Electromagnetic fields and waves. Transient behavior of transmission lines. Dipole and monopole antennas. Four coupling mechanisms: electrical and magnetic fields, common impedance, and electromagnetic wave. Conducted emissions. Radiated emissions. Electromagnetic shielding and grounding.
Prerequisites: ECE 300 and Computer Engineering Major
Corequisites: There are no corequisites for this course.
Electromagnetic compatibility (EMC) regulations and measurement. Frequency behavior of passive components. Electromagnetic fields and waves. Transient behavior of transmission lines. Dipole and monopole antennas. Four coupling mechanisms: electrical and magnetic fields, common impedance, and electromagnetic wave. Conducted emissions. Radiated emissions. Electromagnetic shielding and grounding.
ECE 343 High-Speed Digital Design 3R-3L-4C W,S
Prerequisites: ECE 300 and Computer Engineering Major
Corequisites: There are no corequisites for this course.
Signal path modeling through connecting lengths of transmission lines with lumped element models of discontinuities. Circuit parameters from geometries and material properties for resistance, capacitance, inductance and transmission line segments. Lossless and lossy transmission line circuit modeling. High-frequency and high-speed behavior of passive components. Frequency spectrum of digital signals. Digital device driver and receiver modeling. Transmission line impedance discontinuity and termination techniques. Electric and magnetic field coupling mechanisms for capacitive and inductive crosstalk. Ground noise, power plane noise and resonance. Signal and power integrity issues in high-speed digital systems at both the printed-circuit board and chip levels.
Prerequisites: ECE 300 and Computer Engineering Major
Corequisites: There are no corequisites for this course.
Signal path modeling through connecting lengths of transmission lines with lumped element models of discontinuities. Circuit parameters from geometries and material properties for resistance, capacitance, inductance and transmission line segments. Lossless and lossy transmission line circuit modeling. High-frequency and high-speed behavior of passive components. Frequency spectrum of digital signals. Digital device driver and receiver modeling. Transmission line impedance discontinuity and termination techniques. Electric and magnetic field coupling mechanisms for capacitive and inductive crosstalk. Ground noise, power plane noise and resonance. Signal and power integrity issues in high-speed digital systems at both the printed-circuit board and chip levels.
ECE 351 Analog Electronics 3R-3L-4C F,W
Prerequisites: ECE 205, and ECE 250
Corequisites: There are no corequisites for this course.
Amplifier design and analysis including discrete and integrated circuit topologies. Cascaded amplifier, input and output stages, frequency response. Linear and non-linear op-amp circuits. Introduction to the non-ideal properties of op-amps. Integral laboratory.
Prerequisites: ECE 205, and ECE 250
Corequisites: There are no corequisites for this course.
Amplifier design and analysis including discrete and integrated circuit topologies. Cascaded amplifier, input and output stages, frequency response. Linear and non-linear op-amp circuits. Introduction to the non-ideal properties of op-amps. Integral laboratory.
ECE 362 Principles of Design 3R-0L-3C W,S
Prerequisites: ECE 204 , and ECE 205, ECE 230, and ECE 233, and ECE 250, and ECE 300
Corequisites: There are no corequisites for this course.
A formal design course that emphasizes the design process. Project management, project reporting and decision-making are learned by student teams as they carry a project through several stages of a formal design process.
Prerequisites: ECE 204 , and ECE 205, ECE 230, and ECE 233, and ECE 250, and ECE 300
Corequisites: There are no corequisites for this course.
A formal design course that emphasizes the design process. Project management, project reporting and decision-making are learned by student teams as they carry a project through several stages of a formal design process.
ECE 370 Electric Machinery 3R-3L-4C W,S
Prerequisites: ECE 204
Corequisites: There are no corequisites for this course.
An introduction to electric machinery fundamentals. Operating principles and detailed analysis of single-phase and three-phase transformers, power electronics in the context of generators and motors, synchronous generators and motors, induction motors and generators, and dc motors and generators. Integral laboratory.
Prerequisites: ECE 204
Corequisites: There are no corequisites for this course.
An introduction to electric machinery fundamentals. Operating principles and detailed analysis of single-phase and three-phase transformers, power electronics in the context of generators and motors, synchronous generators and motors, induction motors and generators, and dc motors and generators. Integral laboratory.
ECE 371 Conventional & Renewable Energy Systems 3R-3L-4C W
Prerequisites: ECE 204
Corequisites: There are no corequisites for this course.
Conventional and modern sources of energy for power generation in electric power industry with the imposed economic, regulatory, and environmental constraints. Wind, solar-photovoltaic, micro-hydropower, biomass, and fuel cell systems. Integral laboratory.
Prerequisites: ECE 204
Corequisites: There are no corequisites for this course.
Conventional and modern sources of energy for power generation in electric power industry with the imposed economic, regulatory, and environmental constraints. Wind, solar-photovoltaic, micro-hydropower, biomass, and fuel cell systems. Integral laboratory.
ECE 380 Discrete-Time Signals and Systems 4R-0L-4C F,W
Prerequisites: ECE 300, and MA 381
Corequisites: There are no corequisites for this course.
System properties: linearity and time-invariance. Sampling and reconstruction. Convolution in discrete-time systems. Z-transform, FIR and IIR filters. Discrete-time filter design. Discrete Fourier transform. Random Variables and Random Processes.
Prerequisites: ECE 300, and MA 381
Corequisites: There are no corequisites for this course.
System properties: linearity and time-invariance. Sampling and reconstruction. Convolution in discrete-time systems. Z-transform, FIR and IIR filters. Discrete-time filter design. Discrete Fourier transform. Random Variables and Random Processes.
ECE 398 Undergraduate Projects 1-4C
Prerequisites: Arranged Prereq: Consent of instructor
Corequisites: There are no corequisites for this course.
Special design or research projects. Students may take up to four credits in any given term. In contrast to ECE498, no public presentation of work is required. Students cannot use this class to satisfy ECE Area Elective credit.
Prerequisites: Arranged Prereq: Consent of instructor
Corequisites: There are no corequisites for this course.
Special design or research projects. Students may take up to four credits in any given term. In contrast to ECE498, no public presentation of work is required. Students cannot use this class to satisfy ECE Area Elective credit.
ECE 412 Software Defined Radio 4R-0L-4C See Dept Advising Site
Prerequisites: ECE 380
Corequisites: There are no corequisites for this course.
Essential concepts of wireless communications. Software defined radio (SDR) architecture. Analog and digital modulation formats. Transmitter and receiver system design and implementation methods. Synchronization techniques. Term project.
Prerequisites: ECE 380
Corequisites: There are no corequisites for this course.
Essential concepts of wireless communications. Software defined radio (SDR) architecture. Analog and digital modulation formats. Transmitter and receiver system design and implementation methods. Synchronization techniques. Term project.
ECE 414 Wireless Systems 4R-0L-4C W
Prerequisites: ECE 310
Corequisites: There are no corequisites for this course.
Introduction to wireless communications and networks. Wireless channel models, vector space, modulation and demodulation, optimal receiver design, equalization, channel capacity, multipleaccess techniques, spread spectrum, and multiple-antenna systems. Additional recommended prerequisite: MA371 or MA373 with a grade of B or higher.
Prerequisites: ECE 310
Corequisites: There are no corequisites for this course.
Introduction to wireless communications and networks. Wireless channel models, vector space, modulation and demodulation, optimal receiver design, equalization, channel capacity, multipleaccess techniques, spread spectrum, and multiple-antenna systems. Additional recommended prerequisite: MA371 or MA373 with a grade of B or higher.
ECE 415 Wireless Electronics 2R-6L-4C
Prerequisites: Consent of instructor
Corequisites: There are no corequisites for this course.
Design, fabrication, and testing of a high frequency transmitter-receiver system including but not limited to oscillators, mixers, filters, amplifiers, and matching networks. Integral laboratory.
Prerequisites: Consent of instructor
Corequisites: There are no corequisites for this course.
Design, fabrication, and testing of a high frequency transmitter-receiver system including but not limited to oscillators, mixers, filters, amplifiers, and matching networks. Integral laboratory.
ECE 416 Introduction to MEMS: Fabrication & Applications 3R-3L-4C S
Prerequisites: Junior or Senior standing
Corequisites: There are no corequisites for this course.
Properties of silicon wafers; wafer-level processes, surface and bulk micromachining, thin-film deposition, dry and wet etching, photolithography, process integration, simple actuators. Introduction to microfluidic systems. MEMS applications: capacitive accelerometer, cantilever and pressure sensor. Cross-listed with CHE 405, NE 410, and ME 416.
Prerequisites: Junior or Senior standing
Corequisites: There are no corequisites for this course.
Properties of silicon wafers; wafer-level processes, surface and bulk micromachining, thin-film deposition, dry and wet etching, photolithography, process integration, simple actuators. Introduction to microfluidic systems. MEMS applications: capacitive accelerometer, cantilever and pressure sensor. Cross-listed with CHE 405, NE 410, and ME 416.
ECE 418 Fiber Optic Systems 4R-0L-4C S
Prerequisites: ECE 310 Consent of instructor
Corequisites: There are no corequisites for this course.
Analysis and design of common photonic systems such as fiber optic communication links, optical sensing systems, and optical networks. Topics include basic architectures, component overview, system design, and expected degradations along with mitigation techniques. An oral presentation of a technical paper is required.
Prerequisites: ECE 310 Consent of instructor
Corequisites: There are no corequisites for this course.
Analysis and design of common photonic systems such as fiber optic communication links, optical sensing systems, and optical networks. Topics include basic architectures, component overview, system design, and expected degradations along with mitigation techniques. An oral presentation of a technical paper is required.
ECE 419 Advanced MEMS: Modeling and Packaging 3R-3L-4C F
Prerequisites: NE 410 or equivalent course
Corequisites: There are no corequisites for this course.
Design process, modeling; analytical and numerical. Actuators; dynamics and thermal issues. Use of software for layout and simulation. Characterization and reliability of MEMS devices. Electrical interfacing and packaging of MEMS. Microsensors, microfluidic systems, applications in engineering, biology, chemistry, and physics. Cross-listed with NE 411, and CHE 419.
Prerequisites: NE 410 or equivalent course
Corequisites: There are no corequisites for this course.
Design process, modeling; analytical and numerical. Actuators; dynamics and thermal issues. Use of software for layout and simulation. Characterization and reliability of MEMS devices. Electrical interfacing and packaging of MEMS. Microsensors, microfluidic systems, applications in engineering, biology, chemistry, and physics. Cross-listed with NE 411, and CHE 419.
ECE 420 Discrete-Time Control Systems 4R-0L-4C See Dept Advising Site
Prerequisites: ECE 320
Corequisites: There are no corequisites for this course.
Sampled systems and z-transforms. Transfer function and state-variable models of systems. Discrete-time control of systems including state variable feedback and observer construction.
Prerequisites: ECE 320
Corequisites: There are no corequisites for this course.
Sampled systems and z-transforms. Transfer function and state-variable models of systems. Discrete-time control of systems including state variable feedback and observer construction.
ECE 425 Introduction to Mobile Robotics 3R-3L-4C W
Prerequisites: CSSE 120, and ECE 320 or ME 406 or BE 350 or CHE 340
Corequisites: There are no corequisites for this course.
This course will introduce the basic principles of mobile robotics history, theory, hardware and control. Topics will include robot components, effectors and actuators, locomotion, sensors, feedback control, control architectures, representation, localization and navigation. This is a project-oriented course and the student will have hands-on experience with a real mobile robot. The student will be required to complete several laboratory assignments and a multidisciplinary team design project.
Prerequisites: CSSE 120, and ECE 320 or ME 406 or BE 350 or CHE 340
Corequisites: There are no corequisites for this course.
This course will introduce the basic principles of mobile robotics history, theory, hardware and control. Topics will include robot components, effectors and actuators, locomotion, sensors, feedback control, control architectures, representation, localization and navigation. This is a project-oriented course and the student will have hands-on experience with a real mobile robot. The student will be required to complete several laboratory assignments and a multidisciplinary team design project.
ECE 430 Microcontroller-Based Systems 3R-3L-4C F
Prerequisites: ECE 250* *For ECE students, consent of instructor for other students.
Corequisites: There are no corequisites for this course.
Microcontroller register set, addressing modes and instruction set. Microcontroller peripheral support modules. Assembly language and C programming. Fundamental data structures. Interrupts. Real time programming. Data communications. Microcontroller interface to displays, digital and analog devices, sensors, and actuators. Embedded system design, implementation and applications. Integrated development environment. Formal final report and oral presentation. Integral laboratory. Credit cannot be obtained for both ECE 331 and ECE 430.
Prerequisites: ECE 250* *For ECE students, consent of instructor for other students.
Corequisites: There are no corequisites for this course.
Microcontroller register set, addressing modes and instruction set. Microcontroller peripheral support modules. Assembly language and C programming. Fundamental data structures. Interrupts. Real time programming. Data communications. Microcontroller interface to displays, digital and analog devices, sensors, and actuators. Embedded system design, implementation and applications. Integrated development environment. Formal final report and oral presentation. Integral laboratory. Credit cannot be obtained for both ECE 331 and ECE 430.
ECE 433 Advanced Digital System Design with Verilog 3R-3L-4C F
Prerequisites: ECE 233
Corequisites: There are no corequisites for this course.
Concepts and designs of combinational and sequential digital systems; Modern design methodology; ASM and ASMD charts for behavioral modeling; Synthesizable Verilog descriptions and synthesis techniques; Design verification and functional simulations; FPGA implementations of digital systems; Timing analysis and constraints; Storage devices; Implementation options; I/O clocking techniques; Synchronous and asynchronous designs; Complex digital systems; IP core applications. Integrated Development Environment. Integral laboratory.
Prerequisites: ECE 233
Corequisites: There are no corequisites for this course.
Concepts and designs of combinational and sequential digital systems; Modern design methodology; ASM and ASMD charts for behavioral modeling; Synthesizable Verilog descriptions and synthesis techniques; Design verification and functional simulations; FPGA implementations of digital systems; Timing analysis and constraints; Storage devices; Implementation options; I/O clocking techniques; Synchronous and asynchronous designs; Complex digital systems; IP core applications. Integrated Development Environment. Integral laboratory.
ECE 434 Embedded Linux 3R-3L-4C W
Prerequisites: CSSE 332 or ECE 230 with a grade of B or better; or graduate standing, Operating Systems and Linux experience.
Corequisites: There are no corequisites for this course.
Brief introduction to Linux on an embedded processor. Software development in various languages (C, shell scripts, Python, JavaScript, etc.). Hardware interfacing. Kernel development. Software tools (IDE, gcc, make, node.js, etc.)
Prerequisites: CSSE 332 or ECE 230 with a grade of B or better; or graduate standing, Operating Systems and Linux experience.
Corequisites: There are no corequisites for this course.
Brief introduction to Linux on an embedded processor. Software development in various languages (C, shell scripts, Python, JavaScript, etc.). Hardware interfacing. Kernel development. Software tools (IDE, gcc, make, node.js, etc.)
ECE 436 Internet of Things 4R-0L-4C S
Prerequisites: ECE 230 or CSSE 132, and ECE 312 or CSSE 432 or consent of instructor
Corequisites: There are no corequisites for this course.
Introduction to the design and development of an Internet of Things (IoT) solution. Provides breadth of knowledge on a broad range of topics, such as sensors, communication, power, cloud storage, data analysis, automation, privacy and security. Focuses on a team design project to provide a complete IoT solution for a real-world application. This is a required course for the minor in Internet of Things for students earning a primary or secondary major in EE, CPE, CS, or SE. Students cannot earn credit for both MDS210 and ECE436.
Prerequisites: ECE 230 or CSSE 132, and ECE 312 or CSSE 432 or consent of instructor
Corequisites: There are no corequisites for this course.
Introduction to the design and development of an Internet of Things (IoT) solution. Provides breadth of knowledge on a broad range of topics, such as sensors, communication, power, cloud storage, data analysis, automation, privacy and security. Focuses on a team design project to provide a complete IoT solution for a real-world application. This is a required course for the minor in Internet of Things for students earning a primary or secondary major in EE, CPE, CS, or SE. Students cannot earn credit for both MDS210 and ECE436.
ECE 452 Power Electronics 3R-3L-4C F
Prerequisites: ECE 250
Corequisites: There are no corequisites for this course.
Analysis and design of networks that use electronic devices as power switches. Silicon-controlled rectifiers, power transistors, power MOSFETS, and IGBTs are used to form phase-controlled rectifiers, AC voltage controllers, choppers, and inverters. Integral laboratory.
Prerequisites: ECE 250
Corequisites: There are no corequisites for this course.
Analysis and design of networks that use electronic devices as power switches. Silicon-controlled rectifiers, power transistors, power MOSFETS, and IGBTs are used to form phase-controlled rectifiers, AC voltage controllers, choppers, and inverters. Integral laboratory.
ECE 454 System Level Analog Electronics 3R-3L-4C W
Prerequisites: ECE 351
Corequisites: There are no corequisites for this course.
Analysis and design of Op-Amp circuits: wave shaping circuits, Schmitt triggers, power amplifiers, high power buffers, controlled current sources, peak detectors, sample and hold circuits. Precision Op-Amp Circuits. Non-ideal properties of Op-Amps. Integral laboratory.
Prerequisites: ECE 351
Corequisites: There are no corequisites for this course.
Analysis and design of Op-Amp circuits: wave shaping circuits, Schmitt triggers, power amplifiers, high power buffers, controlled current sources, peak detectors, sample and hold circuits. Precision Op-Amp Circuits. Non-ideal properties of Op-Amps. Integral laboratory.
ECE 460 Engineering Design I 1R-6L-3C F
Prerequisites: ECE 362, and either ECE 230*, and ECE 310*, and ECE 320*, and ECE 341*, and ECE 351*, and ECE 370* or ECE 371*, and ECE 380* or CSSE 332**, and CSSE 230**, and ECE 250**, and ECE 230**, and ECE 312**, and ECE 332**, and ECE 343**, and either ECE 380** or ECE 320** *For EE: Prereq or concurrent registration in the remainder of course. **For CPE: Prereq or concurrent registration in the remainder of course.
Corequisites: There are no corequisites for this course.
A continuation of a sequence of formal design courses that emphasizes completion of a client-driven project using a formal design process. Student teams carry a project from inception to completion to satisfy the need of a client. Integral laboratory.
Prerequisites: ECE 362, and either ECE 230*, and ECE 310*, and ECE 320*, and ECE 341*, and ECE 351*, and ECE 370* or ECE 371*, and ECE 380* or CSSE 332**, and CSSE 230**, and ECE 250**, and ECE 230**, and ECE 312**, and ECE 332**, and ECE 343**, and either ECE 380** or ECE 320** *For EE: Prereq or concurrent registration in the remainder of course. **For CPE: Prereq or concurrent registration in the remainder of course.
Corequisites: There are no corequisites for this course.
A continuation of a sequence of formal design courses that emphasizes completion of a client-driven project using a formal design process. Student teams carry a project from inception to completion to satisfy the need of a client. Integral laboratory.
ECE 461 Engineering Design II 1R-9L-4C W
Prerequisites: ECE 460
Corequisites: There are no corequisites for this course.
Continuation of the design project from ECE460. Integral laboratory.
Prerequisites: ECE 460
Corequisites: There are no corequisites for this course.
Continuation of the design project from ECE460. Integral laboratory.
ECE 462 Engineering Design III 1R-3L-2C W,S
Prerequisites: ECE 461
Corequisites: There are no corequisites for this course.
Completion of the design project from ECE 460 and ECE 461. Integral laboratory.
Prerequisites: ECE 461
Corequisites: There are no corequisites for this course.
Completion of the design project from ECE 460 and ECE 461. Integral laboratory.
ECE 470 Power Systems Analysis I 3R-3L-4C F
Prerequisites: ECE 370
Corequisites: There are no corequisites for this course.
Modeling of power system components that encompass transmission lines, power transformers, synchronous generators, and loads for power system representation and per unit analysis. Formulation of power system representation in the context of power flow analysis. The industry standard Siemens-PTI PSS/E software package will be used for solutions of the large-scale power flow. Economic dispatch by optimum allocation of generation, control of system voltage profile, and real and reactive power flow control by tap-changing transformers. Integral laboratory.
Prerequisites: ECE 370
Corequisites: There are no corequisites for this course.
Modeling of power system components that encompass transmission lines, power transformers, synchronous generators, and loads for power system representation and per unit analysis. Formulation of power system representation in the context of power flow analysis. The industry standard Siemens-PTI PSS/E software package will be used for solutions of the large-scale power flow. Economic dispatch by optimum allocation of generation, control of system voltage profile, and real and reactive power flow control by tap-changing transformers. Integral laboratory.
ECE 471 Power Systems Analysis II 4R-0L-4C W
Prerequisites: ECE 470
Corequisites: There are no corequisites for this course.
Modeling of power system components that encompass transmission lines, power transformers, synchronous generators for analysis of power systems during balanced and unbalanced faults/short-circuits with symmetrical components. The industry standard ASPEN One-Liner software package will be used for simulation of large-scale faulted systems. Power system grounding and its impact on fault levels. Power system stability and generator rotor dynamics phenomenon with use of equal-area criterion. Modern approaches to power system stability analysis are introduced. Integral laboratory.
Prerequisites: ECE 470
Corequisites: There are no corequisites for this course.
Modeling of power system components that encompass transmission lines, power transformers, synchronous generators for analysis of power systems during balanced and unbalanced faults/short-circuits with symmetrical components. The industry standard ASPEN One-Liner software package will be used for simulation of large-scale faulted systems. Power system grounding and its impact on fault levels. Power system stability and generator rotor dynamics phenomenon with use of equal-area criterion. Modern approaches to power system stability analysis are introduced. Integral laboratory.
ECE 472 Power Systems Protection 3R-3L-4C S
Prerequisites: ECE 470, and ECE 471
Corequisites: There are no corequisites for this course.
Design and application of relaying schemes for protection of transformers, buses, distribution lines, transmission lines, generators, motors, capacitors, and reactors. Integral laboratory.
Prerequisites: ECE 470, and ECE 471
Corequisites: There are no corequisites for this course.
Design and application of relaying schemes for protection of transformers, buses, distribution lines, transmission lines, generators, motors, capacitors, and reactors. Integral laboratory.
ECE 473 Control of Power Systems 3R-3L-4C W
Prerequisites: Senior standing or consent of instructor
Corequisites: There are no corequisites for this course.
Principles of interconnected operation of power systems. Optimum scheduling of generation using economic dispatch and unit commitment. Primary and secondary load-frequency control. Voltage and reactive-power flow control. Principles of state estimation. Integral laboratory.
Prerequisites: Senior standing or consent of instructor
Corequisites: There are no corequisites for this course.
Principles of interconnected operation of power systems. Optimum scheduling of generation using economic dispatch and unit commitment. Primary and secondary load-frequency control. Voltage and reactive-power flow control. Principles of state estimation. Integral laboratory.
ECE 480 Introduction to Image Processing 3R-3L-4C W
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
Basic techniques of image processing. Discrete and continuous two dimensional transforms such as Fourier and Hotelling. Image enhancement through filtering and histogram modification. Image restoration through inverse filtering. Image segmentation including edge detection and thresholding. Introduction to image encoding. Relevant laboratory experiments.
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
Basic techniques of image processing. Discrete and continuous two dimensional transforms such as Fourier and Hotelling. Image enhancement through filtering and histogram modification. Image restoration through inverse filtering. Image segmentation including edge detection and thresholding. Introduction to image encoding. Relevant laboratory experiments.
ECE 481 Electronic Music Synthesis 4R-0L-4C S
Prerequisites: ECE 380
Corequisites: There are no corequisites for this course.
Analog synthesis techniques. Instrument control using MIDI. FM, additive and subtractive synthesis. Physical modeling and sound spatialization. Course project.
Prerequisites: ECE 380
Corequisites: There are no corequisites for this course.
Analog synthesis techniques. Instrument control using MIDI. FM, additive and subtractive synthesis. Physical modeling and sound spatialization. Course project.
ECE 483 DSP System Design 3R-3L-4C F
Prerequisites: ECE 380, and MA 381
Corequisites: There are no corequisites for this course.
Study of finite word length effects in DSP systems. Cascaded filter structures. Coefficient quantization, roundoff noise, scaling for overflow prevention. Discrete-time noise, filtering noise, power spectral density. Polyphase filtering, interpolation and decimation. Implementation and system design and test issues for a SSB communication system. Integral laboratory based on a fixed point programming project.
Prerequisites: ECE 380, and MA 381
Corequisites: There are no corequisites for this course.
Study of finite word length effects in DSP systems. Cascaded filter structures. Coefficient quantization, roundoff noise, scaling for overflow prevention. Discrete-time noise, filtering noise, power spectral density. Polyphase filtering, interpolation and decimation. Implementation and system design and test issues for a SSB communication system. Integral laboratory based on a fixed point programming project.
ECE 497 Special Topics in Electrical Engineering 1-4C
Prerequisites: Arranged prerequisite consent of instructor and department head
Corequisites: There are no corequisites for this course.
Topics of current interest to undergraduate students.
Prerequisites: Arranged prerequisite consent of instructor and department head
Corequisites: There are no corequisites for this course.
Topics of current interest to undergraduate students.
ECE 498 Undergraduate Projects 1-4C
Prerequisites: Arranged prerequisite consent of instructor
Corequisites: There are no corequisites for this course.
Special design or research projects. Students may take up to four credits in any given term. Level and rigor of work should be consistent with other 400-level ECE elective courses. Work must be presented publicly at the end of term. Up to four credits of ECE498 can count towards ECE Area Elective credit. Students not wishing to give a public presentation of their work should take ECE398.
Prerequisites: Arranged prerequisite consent of instructor
Corequisites: There are no corequisites for this course.
Special design or research projects. Students may take up to four credits in any given term. Level and rigor of work should be consistent with other 400-level ECE elective courses. Work must be presented publicly at the end of term. Up to four credits of ECE498 can count towards ECE Area Elective credit. Students not wishing to give a public presentation of their work should take ECE398.
ECE 510 Error Correcting Codes 4R-0L-4C F (odd years)
Prerequisites: ECE 310* *Graduate standing or with a grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Coding for reliable digital communication. Topics to be chosen from: Hamming and BCH codes, Reed-Solomon codes, convolutional codes, Viterbi decoding, turbo codes, and recent developments, depending on interests of class and instructor. Mathematical background will be developed as needed.
Prerequisites: ECE 310* *Graduate standing or with a grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Coding for reliable digital communication. Topics to be chosen from: Hamming and BCH codes, Reed-Solomon codes, convolutional codes, Viterbi decoding, turbo codes, and recent developments, depending on interests of class and instructor. Mathematical background will be developed as needed.
ECE 511 Data Communications 4R-0L-4C F (even years)
Prerequisites: ECE 310*, and MA 381* or ECE 310**, and MA 381** *Graduate standing **with a grade of B or better in both courses, or consent of instructor
Corequisites: There are no corequisites for this course.
Design of digital communication systems. Autocorrelation function and power spectrum, vector space models of signals and noise, optimal receiver structures and performance, bandlimited channels and equalization, convolutional coding.
Prerequisites: ECE 310*, and MA 381* or ECE 310**, and MA 381** *Graduate standing **with a grade of B or better in both courses, or consent of instructor
Corequisites: There are no corequisites for this course.
Design of digital communication systems. Autocorrelation function and power spectrum, vector space models of signals and noise, optimal receiver structures and performance, bandlimited channels and equalization, convolutional coding.
ECE 512 Probability, Random Processes, and Estimation 4R-0L-4C W
Prerequisites: MA 381, and ECE 380
Corequisites: There are no corequisites for this course.
Review of probability and random variables, random vectors, topics in estimation and detection theory, linear and nonlinear estimation, orthogonality principle, hypothesis testing, random processes, stationarity, correlation functions, and spectra. Additional topics chosen from Wiener and Kalman filtering, and Markov chains.
Prerequisites: MA 381, and ECE 380
Corequisites: There are no corequisites for this course.
Review of probability and random variables, random vectors, topics in estimation and detection theory, linear and nonlinear estimation, orthogonality principle, hypothesis testing, random processes, stationarity, correlation functions, and spectra. Additional topics chosen from Wiener and Kalman filtering, and Markov chains.
ECE 516 Introduction to MEMS: Fabrication & Applications 3R-3L-4C S
Prerequisites: Junior or Senior class standing
Corequisites: There are no corequisites for this course.
Properties of silicon wafers; wafer-level processes, surface and bulk micromachining, thin-film deposition, dry and wet etching, photolithography, process integration, simple actuators. Introduction to microfluidic systems. MEMS applications: capacitive accelerometer, cantilever and pressure sensor. Cross-listed with BE 516, CHE 505, NE 510, and ME 516.
Prerequisites: Junior or Senior class standing
Corequisites: There are no corequisites for this course.
Properties of silicon wafers; wafer-level processes, surface and bulk micromachining, thin-film deposition, dry and wet etching, photolithography, process integration, simple actuators. Introduction to microfluidic systems. MEMS applications: capacitive accelerometer, cantilever and pressure sensor. Cross-listed with BE 516, CHE 505, NE 510, and ME 516.
ECE 519 Advanced MEMS: Modeling & Packaging 3R-3L-4C F
Prerequisites: NE 410 or equivalent course
Corequisites: There are no corequisites for this course.
Design process, modeling; analytical and numerical. Actuators; dynamics and thermal issues. Use of software for layout and simulation. Characterization and reliability of MEMS devices. Electrical interfacing and packaging of MEMS. Microsensors, microfluidic systems, applications in engineering, biology, chemistry, and physics. Cross-listed with ME 519, NE 511, and CHE 519.
Prerequisites: NE 410 or equivalent course
Corequisites: There are no corequisites for this course.
Design process, modeling; analytical and numerical. Actuators; dynamics and thermal issues. Use of software for layout and simulation. Characterization and reliability of MEMS devices. Electrical interfacing and packaging of MEMS. Microsensors, microfluidic systems, applications in engineering, biology, chemistry, and physics. Cross-listed with ME 519, NE 511, and CHE 519.
ECE 530 Advanced Microcomputers 3R-3L-4C S
Prerequisites: *Graduate standing; or with a grade of B or better; or consent of instructor ECE 230* *Graduate standing; or with a grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
32-bit microcontroller architecture. Software development in both assembly language and C language. Hardware interfacing. Use of a real-time-operating system (RTOS). System-on-a-chip (SOC) hardware/software design using a field programmable gate array (FPGA) chip containing an embedded microcontroller cores. Software debugging tools. Integral laboratory.
Prerequisites: *Graduate standing; or with a grade of B or better; or consent of instructor ECE 230* *Graduate standing; or with a grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
32-bit microcontroller architecture. Software development in both assembly language and C language. Hardware interfacing. Use of a real-time-operating system (RTOS). System-on-a-chip (SOC) hardware/software design using a field programmable gate array (FPGA) chip containing an embedded microcontroller cores. Software debugging tools. Integral laboratory.
ECE 531 Digital Test & Product Engineering 3R-3L-4C S
Prerequisites: ECE 230*, and ECE 233*, and ECE 250* *Graduate standing; or with grades of B or better in all three courses; or consent of instructor.
Corequisites: There are no corequisites for this course.
Industrial testing techniques for microcontrollers and other digital integrated circuits. Includes common digital system fault modeling, test generation, and design for testability in addition to memory testing strategies. Integral labs using an industrial grade automatic test environment (ATE).
Prerequisites: ECE 230*, and ECE 233*, and ECE 250* *Graduate standing; or with grades of B or better in all three courses; or consent of instructor.
Corequisites: There are no corequisites for this course.
Industrial testing techniques for microcontrollers and other digital integrated circuits. Includes common digital system fault modeling, test generation, and design for testability in addition to memory testing strategies. Integral labs using an industrial grade automatic test environment (ATE).
ECE 532 Advanced Topics in Computer Architecture 4R-0L-4C W
Prerequisites: ECE 332 with a B or better.
Corequisites: There are no corequisites for this course.
Superscalar processors. Out-of-Order Execution. Register Renaming. Dynamic Random Access Memory (DRAM). Prefetching. Trace Cache. Victim Cache. 3D DRAM. Multithreading. Multicore. Cache Coherence. Transactional Memory. Performance Modeling. Power Modeling. Intel Pentium Pro Architecture. Transmeta Crusoe Architecture. Code Morphing. ARMv7 Architecture. Nvidia G80 Architecture.
Prerequisites: ECE 332 with a B or better.
Corequisites: There are no corequisites for this course.
Superscalar processors. Out-of-Order Execution. Register Renaming. Dynamic Random Access Memory (DRAM). Prefetching. Trace Cache. Victim Cache. 3D DRAM. Multithreading. Multicore. Cache Coherence. Transactional Memory. Performance Modeling. Power Modeling. Intel Pentium Pro Architecture. Transmeta Crusoe Architecture. Code Morphing. ARMv7 Architecture. Nvidia G80 Architecture.
ECE 534 Advanced Signal & Power Integrity 4R-0L-4C W
Prerequisites: ECE 341*, and ECE 342* or ECE 343* *Graduate standing; or all courses with a grade of B or better; or ECE342 with a grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Signal and power integrity modeling and measurement in high-speed digital systems at IC, PCB, and chassis levels. High-frequency behavior of passive components and packages. Behavior and SPICE models of drivers and receivers. Lossy transmission lines and discontinuity characterization. Mixedmode s-parameters and other network parameters. Frequency and time-domain modeling of capacitive and inductive crosstalk. Differential signaling techniques; timing conventions. Synchronization. Signal equalization. Power plane noise and resonance. High-speed PCB design guidelines. Measurement techniques including time-domain reflectometry, vector network analyzer and impedance analyzer. PCB simulation. Full-wave simulations.
Prerequisites: ECE 341*, and ECE 342* or ECE 343* *Graduate standing; or all courses with a grade of B or better; or ECE342 with a grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Signal and power integrity modeling and measurement in high-speed digital systems at IC, PCB, and chassis levels. High-frequency behavior of passive components and packages. Behavior and SPICE models of drivers and receivers. Lossy transmission lines and discontinuity characterization. Mixedmode s-parameters and other network parameters. Frequency and time-domain modeling of capacitive and inductive crosstalk. Differential signaling techniques; timing conventions. Synchronization. Signal equalization. Power plane noise and resonance. High-speed PCB design guidelines. Measurement techniques including time-domain reflectometry, vector network analyzer and impedance analyzer. PCB simulation. Full-wave simulations.
ECE 540 Antenna Engineering 3R-3L-4C W
Prerequisites: ECE 341* Graduate standing (course not required); *or with a grade of B or better; or consent of instructor.
Corequisites: There are no corequisites for this course.
Electromagnetic radiation, antenna terminology and characteristics, dipole antennas, arrays, aperture antennas, measurements, computer-aided analysis, design projects and reports.
Prerequisites: ECE 341* Graduate standing (course not required); *or with a grade of B or better; or consent of instructor.
Corequisites: There are no corequisites for this course.
Electromagnetic radiation, antenna terminology and characteristics, dipole antennas, arrays, aperture antennas, measurements, computer-aided analysis, design projects and reports.
ECE 541 Microwave/Millimeter-Wave Engineering 4R-0L-4C S
Prerequisites: ECE 341 Graduate standing; or with grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Wave-guiding structures, microwave network analysis, scattering parameters, Z, Y and ABCD parameters, passive devices and components, design, fabrication, simulation and measurement of microwave devices and components, matching strategies, multi-conductor transmission lines and crosstalk.
Prerequisites: ECE 341 Graduate standing; or with grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Wave-guiding structures, microwave network analysis, scattering parameters, Z, Y and ABCD parameters, passive devices and components, design, fabrication, simulation and measurement of microwave devices and components, matching strategies, multi-conductor transmission lines and crosstalk.
ECE 542 Advanced Electromagnetics 4R-0L-4C F
Prerequisites: ECE 341 and Graduate standing; or with grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Maxwell鈥檚 equations, EM field theorems, potential functions, power and energy, material properties, wave propagation, reflection and transmission, radiation, scattering, Green's functions, metamaterials and metamaterial-inspired structures, modeling & simulation, measurement technique.
Prerequisites: ECE 341 and Graduate standing; or with grade of B or better, or consent of instructor
Corequisites: There are no corequisites for this course.
Maxwell鈥檚 equations, EM field theorems, potential functions, power and energy, material properties, wave propagation, reflection and transmission, radiation, scattering, Green's functions, metamaterials and metamaterial-inspired structures, modeling & simulation, measurement technique.
ECE 543 Electromagnetic Metamaterials 4R-0L-4C
Prerequisites: ECE 341* Graduate standing (course not required) *or with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Electromagnetic fundamentals, control of permittivity and permeability, dispersion, causality, double-negative materials, epsilon near-zero materials, transmission line-based metamaterials, composite right/left handed wave-guiding structures, even/odd mode analysis, differential signaling, electromagnetic bandgap structures, phase control, dual band devices, enhanced bandwidth devices, zeroth-order resonators, full wave simulation, device fabrication and laboratory measurement.
Prerequisites: ECE 341* Graduate standing (course not required) *or with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Electromagnetic fundamentals, control of permittivity and permeability, dispersion, causality, double-negative materials, epsilon near-zero materials, transmission line-based metamaterials, composite right/left handed wave-guiding structures, even/odd mode analysis, differential signaling, electromagnetic bandgap structures, phase control, dual band devices, enhanced bandwidth devices, zeroth-order resonators, full wave simulation, device fabrication and laboratory measurement.
ECE 551 Digital Integrated Circuit Design 3R-3L-4C F
Prerequisites: ECE 250, and ECE 233 both with a grade of B or better; or graduate standing.
Corequisites: There are no corequisites for this course.
Design, performance analysis, and physical layout of CMOS logic. Custom and standard cell methodologies. Use of commercial CAD tools. Design issues such as interconnect, timing, and testing methods. Integral laboratory and project.
Prerequisites: ECE 250, and ECE 233 both with a grade of B or better; or graduate standing.
Corequisites: There are no corequisites for this course.
Design, performance analysis, and physical layout of CMOS logic. Custom and standard cell methodologies. Use of commercial CAD tools. Design issues such as interconnect, timing, and testing methods. Integral laboratory and project.
ECE 552 Analog Integrated Circuit Design 3R-3L-4C W
Prerequisites: ECE 351, and ECE 380 Graduate standing; or with a grade of B or better in both courses; or consent of instructor
Corequisites: There are no corequisites for this course.
Design, performance analysis, and physical layout of analog integrated circuits. Focus on operational amplifier design and op-amp circuits. Introduction to mixed-signal circuit design such as switch-capacitors, A/D, or D/A systems. Integral laboratory and design project.
Prerequisites: ECE 351, and ECE 380 Graduate standing; or with a grade of B or better in both courses; or consent of instructor
Corequisites: There are no corequisites for this course.
Design, performance analysis, and physical layout of analog integrated circuits. Focus on operational amplifier design and op-amp circuits. Introduction to mixed-signal circuit design such as switch-capacitors, A/D, or D/A systems. Integral laboratory and design project.
ECE 553 Radio-Frequency Integrated Circuit Design 3R-3L-4C S
Prerequisites: ECE 310, and ECE 351 Graduate standing (courses not required); or with a grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Design, analysis, and physical layout of high-frequency analog integrated-circuits for modern RF transceivers. Circuit design for each primary transceiver component. General issues such as impedance matching and design of inductors on integrated circuits. Integral laboratory and design project.
Prerequisites: ECE 310, and ECE 351 Graduate standing (courses not required); or with a grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Design, analysis, and physical layout of high-frequency analog integrated-circuits for modern RF transceivers. Circuit design for each primary transceiver component. General issues such as impedance matching and design of inductors on integrated circuits. Integral laboratory and design project.
ECE 554 Instrumentation 4R-0L-4C S
Prerequisites: ECE 351 Graduate standing; or with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Transducers and their applications. Analog signal processing techniques using operational amplifiers. A/D and D/A converters. Protection from electric shock. Measurement of biological potential waveforms (ECG, EMG, EEG, ENG, EOG, ERG). Ultrasound techniques and instrumentation. X-ray CAT techniques. No laboratory, but many in-class demonstrations and emphasis on circuit simulation.
Prerequisites: ECE 351 Graduate standing; or with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Transducers and their applications. Analog signal processing techniques using operational amplifiers. A/D and D/A converters. Protection from electric shock. Measurement of biological potential waveforms (ECG, EMG, EEG, ENG, EOG, ERG). Ultrasound techniques and instrumentation. X-ray CAT techniques. No laboratory, but many in-class demonstrations and emphasis on circuit simulation.
ECE 556 Power Electronics: DC Power Supplies 3R-3L-4C S
Prerequisites: ECE 351 Graduate standing; or with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Analysis and design of AC-DC and DC-DC converters. Linear, basic switching, charge-pump, and fly-back topologies. Introduction to devices used in a power switching supplies. Thermal management. Integral laboratory.
Prerequisites: ECE 351 Graduate standing; or with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Analysis and design of AC-DC and DC-DC converters. Linear, basic switching, charge-pump, and fly-back topologies. Introduction to devices used in a power switching supplies. Thermal management. Integral laboratory.
ECE 557 Analog Test & Product Engineering 3R-3L-4C F
Prerequisites: ECE 300, and ECE 351 Graduate standing; or with a grade of B or better in both courses, or consent of instructor
Corequisites: There are no corequisites for this course.
Fundamental skills necessary to be an industrial integrated circuit test engineer or product engineer. Includes the economics associated with testing, impact of fabrication variation on devices, instrumentation associated with industrial testing, turning a data sheet into a test plan, industrial testing techniques for analog circuits, trade-offs between test time and test accuracy, statistical analysis of the data and statistical process control, the use of device interface boards necessary to control device loading for different tests. Integral labs with an industrial grade automatic tester (ATE).
Prerequisites: ECE 300, and ECE 351 Graduate standing; or with a grade of B or better in both courses, or consent of instructor
Corequisites: There are no corequisites for this course.
Fundamental skills necessary to be an industrial integrated circuit test engineer or product engineer. Includes the economics associated with testing, impact of fabrication variation on devices, instrumentation associated with industrial testing, turning a data sheet into a test plan, industrial testing techniques for analog circuits, trade-offs between test time and test accuracy, statistical analysis of the data and statistical process control, the use of device interface boards necessary to control device loading for different tests. Integral labs with an industrial grade automatic tester (ATE).
ECE 558 Mixed-Signal Test & Product Engineering 3R-3L-4C W
Prerequisites: ECE 300, and ECE 233, and ECE 351 Graduate standing; or with grades of B or better in all three courses; or consent of instructor.
Corequisites: There are no corequisites for this course.
Industrial testing techniques for AC and DC tests of mixed-signal integrated circuits using an automatic test environment (ATE). Includes the structure and operation of comparators and standard data converters (DACs, ADCs), common data converter datasheet specifications, impact of data converter design on testing strategies, and statistical analysis of accuracy-time trade-offs. Integral labs using an industrial grade ATE.
Prerequisites: ECE 300, and ECE 233, and ECE 351 Graduate standing; or with grades of B or better in all three courses; or consent of instructor.
Corequisites: There are no corequisites for this course.
Industrial testing techniques for AC and DC tests of mixed-signal integrated circuits using an automatic test environment (ATE). Includes the structure and operation of comparators and standard data converters (DACs, ADCs), common data converter datasheet specifications, impact of data converter design on testing strategies, and statistical analysis of accuracy-time trade-offs. Integral labs using an industrial grade ATE.
ECE 580 Digital Signal Processing 4R-0L-4C W
Prerequisites: ECE 380, and MA 381 *Graduate standing (courses not required); or with grade of B or better in both courses; or consent of instructor. MA367 with a grade of B or higher recommended.
Corequisites: There are no corequisites for this course.
Digital filters. Fundamental concepts of digital signal processing. Analysis of discrete-time systems. Sampling and reconstruction. Theory and application of z-transforms. Design of recursive and nonrecursive digital filters. Window functions. Discrete Fourier transforms and FFT algorithm.
Prerequisites: ECE 380, and MA 381 *Graduate standing (courses not required); or with grade of B or better in both courses; or consent of instructor. MA367 with a grade of B or higher recommended.
Corequisites: There are no corequisites for this course.
Digital filters. Fundamental concepts of digital signal processing. Analysis of discrete-time systems. Sampling and reconstruction. Theory and application of z-transforms. Design of recursive and nonrecursive digital filters. Window functions. Discrete Fourier transforms and FFT algorithm.
ECE 581 Digital Signal Processing Projects 2R-2L-2 or 4C
Prerequisites: ECE 580 concurrent registration
Corequisites: There are no corequisites for this course.
Computer-aided design of digital filters and other DSP modules. Software and hardware realization using modern DSP chips. DSP chip architectures, C-language programming, and interfacing techniques. Optional advanced project may be done to earn four credit hours; otherwise two credit hours are given. Integral laboratory.
Prerequisites: ECE 580 concurrent registration
Corequisites: There are no corequisites for this course.
Computer-aided design of digital filters and other DSP modules. Software and hardware realization using modern DSP chips. DSP chip architectures, C-language programming, and interfacing techniques. Optional advanced project may be done to earn four credit hours; otherwise two credit hours are given. Integral laboratory.
ECE 582 Advanced Image Processing 3R-3L-4C S
Prerequisites: CSSE 120 or Senior standing or Graduate standing
Corequisites: There are no corequisites for this course.
Introduction to image segmentation and recognition. Use of neural networks, fuzzy logic and morphological methods for feature extraction. Advanced segmentation, detection, recognition and interpretation. Relevant laboratory experiments and required project. Cross-listed with OE 537.
Prerequisites: CSSE 120 or Senior standing or Graduate standing
Corequisites: There are no corequisites for this course.
Introduction to image segmentation and recognition. Use of neural networks, fuzzy logic and morphological methods for feature extraction. Advanced segmentation, detection, recognition and interpretation. Relevant laboratory experiments and required project. Cross-listed with OE 537.
ECE 584 Medical Imaging Systems 4R-0L-4C
Prerequisites: ECE 300* or BE 321 or OE 392 *Graduate standing; or ECE300 with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Engineering principles of major imaging techniques/modalities for biomedical applications and health care including diagnostic x-ray, computed tomography, nuclear techniques, ultrasound, and magnetic resonance imaging. Topics include general characteristics of medical images; physical principles, signal processing to generate an image, and instrumentation of imaging modalities. Clinical applications of these technologies are also discussed. Cross-listed with BE541 and OE584.
Prerequisites: ECE 300* or BE 321 or OE 392 *Graduate standing; or ECE300 with grade of B or better; or consent of instructor
Corequisites: There are no corequisites for this course.
Engineering principles of major imaging techniques/modalities for biomedical applications and health care including diagnostic x-ray, computed tomography, nuclear techniques, ultrasound, and magnetic resonance imaging. Topics include general characteristics of medical images; physical principles, signal processing to generate an image, and instrumentation of imaging modalities. Clinical applications of these technologies are also discussed. Cross-listed with BE541 and OE584.
Prerequisite Notes:
Prerequisites - Clarification:
ECE 300 - Continuous-Time Signals & Systems and Graduate standing;
or ECE 300 Continuous-Time Signals & Systems with a grade of B or better
or BE 340 – Biomedical Signal Processing
or OE 392 – Linear Optical Systems with a grade of B or better;
or consent of instructor
ECE 596 Independent Study in Electrical Engineering 1C-4C
Prerequisites: Consent of instructor
Corequisites: There are no corequisites for this course.
Special research or project based work that is done in consultation with a faculty member. Participation in these projects should require a graduate level of involvement and expectations, otherwise ECE498 Undergraduate Projects should be used. No more than 8 credit hours of ECE596 can be counted towards a graduate degree in the ECE Department without ECE Department Head Approval.
Prerequisites: Consent of instructor
Corequisites: There are no corequisites for this course.
Special research or project based work that is done in consultation with a faculty member. Participation in these projects should require a graduate level of involvement and expectations, otherwise ECE498 Undergraduate Projects should be used. No more than 8 credit hours of ECE596 can be counted towards a graduate degree in the ECE Department without ECE Department Head Approval.
ECE 597 Special Topics in Electrical Engineering 4C
Prerequisites: Consent of instructor
Corequisites: There are no corequisites for this course.
Special topics of current interest to graduate students and senior undergraduates.
Prerequisites: Consent of instructor
Corequisites: There are no corequisites for this course.
Special topics of current interest to graduate students and senior undergraduates.
ECE 598 Thesis Research 1-4C
Prerequisites: Arranged
Corequisites: There are no corequisites for this course.
Thesis topic selected in consultation with adviser. Graduate students only.
Prerequisites: Arranged
Corequisites: There are no corequisites for this course.
Thesis topic selected in consultation with adviser. Graduate students only.
ECE 699 Professional Experience 1R-0L-1C
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
The professional experiences course captures the practical work experiences related to the student鈥檚 academic discipline. Students are required to submit a formal document of their reflections, which communicates how their employment opportunity reinforced and enhanced their academic studies. The work experiences should be informative or integral to the advancement or completion of the student鈥檚 program requirements. The course will be graded as 鈥淪鈥 satisfactory, or 鈥淯鈥 unsatisfactory based on the written report of the professional experience.
Prerequisites: There are no prerequisites for this course.
Corequisites: There are no corequisites for this course.
The professional experiences course captures the practical work experiences related to the student鈥檚 academic discipline. Students are required to submit a formal document of their reflections, which communicates how their employment opportunity reinforced and enhanced their academic studies. The work experiences should be informative or integral to the advancement or completion of the student鈥檚 program requirements. The course will be graded as 鈥淪鈥 satisfactory, or 鈥淯鈥 unsatisfactory based on the written report of the professional experience.