Electrical and Computer Engineering (ECE)

101. Introduction to Electrical and Computer Engineering. (1)


131L. Programming Fundamentals. (4)


203. Circuit Analysis I. (3)


206L. Instrumentation. (2)


213. Circuit Analysis II. (3)


231L. Intermediate Programming and Engineering Problem Solving. (4)


238L. Computer Logic Design. (4)


300. Advanced Engineering Mathematics. (4)


**314L. Signals and Systems. (4)


**321L. Electronics I. (4)


**322L. Electronics II. (4)


330. Software Design. (3)


**331. Data Structures and Algorithms. (3)


**335. Integrated Software Systems. (3)


**338. Intermediate Logic Design. (3)


**340. Probabilistic Methods in Engineering. (3)


341. Introduction to Communication Systems. (3)


**344L. Microprocessors. (4)


345. Introduction to Control Systems. (3)


360. Electromagnetic Fields and Waves. (4)


**371. Materials and Devices. (3)


381. Introduction to Electric Power Systems. (3)


412. Introduction to Computer Graphics: Scanline Algorithms. (3)


419. Senior Design I. (3)


420. Senior Design II. (3)


421 / 523. Analog Electronics. (3)


424 / 520. VLSI Design. (3)


*435. Software Engineering. (3)


*437. Computer Operating Systems. (3)


*438. Design of Computers. (3)


*439. Introduction to Digital Signal Processing. (3)


*440. Introduction to Computer Networks. (3)


*442. Introduction to Wireless Communications. (3)


445 / 545. Introduction to Quantum Information Science. (3, may be repeated one time Δ)


*446. Design of Feedback Control Systems. (3)


460 / 560. Introduction to Microwave Engineering. (3)


*463. Advanced Optics I. (3)


*464. Laser Physics. (3)


469 / 569. Antennas for Wireless Communication Systems. (3)


*471. Materials and Devices II. (3)


474L / 574L. Microelectronics Processing. (3)


*475. Introduction to Electro-Optics and Opto-Electronics. (3)


482 / 582. Electric Drives and Transformers. (3)


483 / 583. Power Electronics I. (3)


484 / 584. Photovoltaics. (3)


488 / 588. Smart Grid Technologies. (3)


489 / 589. Power Electronics II. (3)


490. Internship. (3)


491. Undergraduate Problems. (1-6 to a maximum of 6 Δ)


493. Honors Seminar. (1-3)


494. Honors Individual Study. (1-6)


495 / 595. Special Topics. (1-4 to a maximum of 9, 1-4 to a maximum of 15 Δ)


500. Theory of Linear Systems. (3)


506. Optimization Theory. (3)


510. Medical Imaging. (3)


512. Introduction to Computer Graphics. (3)


514. Nonlinear and Adaptive Control. (3)


516. Computer Vision. (3)


517. Machine Learning. (3)


520 / 424. VLSI Design. (3)


522. Hardware Software Codesign with FPGAs. (3, may be repeated once Δ)


523 / 421. Analog Electronics. (3)


524. Network Economics. (3)


525. Hardware-Oriented Security and Trust. (3, may be repeated once Δ)


529. Introduction to Technical Cybersecurity. (3)


530. Cloud Computing. (3)


531. Introduction to the Internet of Things. (3)


533. Digital Image Processing. (3)


534. Plasma Physics I. (3)


535. Satellite Communications. (3)


537. Foundations of Computing. (3)


538. Advanced Computer Architecture. (3)


539. Digital Signal Processing. (3)


540. Advanced Networking Topics. (3)


541. Probability Theory and Stochastic Processes. (3)


542. Digital Communication Theory. (3)


545/445. Introduction to Quantum Information Science. (3, may be repeated one time Δ)


546. Multivariable Control Theory. (3)


549. Information Theory and Coding. (3)


551. Problems. (1-6 to a maximum of 9 Δ)


554. Advanced Optics II. (3)


555. Foundations of Engineering Electromagnetics. (3)


557. Pulsed Power and Charged Particle Acceleration. (3)


558. Charged Particle Beams and High Power Microwaves. (3)


559. Internship in Optical Science and Engineering. (3)


560 / 460. Introduction to Microwave Engineering. (3)


561. Engineering Electromagnetics. (3)


562. Electronics RF Design. (3)


563. Computational Methods for Electromagnetics. (3)


564. Guided Wave Optics. (3)


565. Optical Communication Components and Subsystems. (3)


567. IR Detectors. (3)


569 / 469. Antennas for Wireless Communications Systems. (3)


570. Optoelectronic Semiconductor Materials and Devices. (3)


572. Semiconductor Physics. (3)


574L / 474L. Microelectronics Processing. (3)


576. Modern VLSI Devices. (3)


577. Fundamentals of Semiconductor LEDs and Lasers. (3)


581. Colloidal Nanocrystals for Biomedical Applications. (3)


582 / 482. Electric Drives and Transformers. (3)


583 / 483. Power Electronics I. (3)


584 / 484. Photovoltaics. (3)


588 / 488. Smart Grid Technologies. (3)


589 / 489. Power Electronics II. (3)


590. Graduate Seminar. (1, may be repeated once Δ)


594. Complex Systems Theory. (3)


595 / 495. Special Topics. (1-4 to a maximum of 15, 1-4 to a maximum of 9 Δ)


599. Master's Thesis. (1-6, no limit Δ)


620. Topics in Interdisciplinary Biological and Biomedical Sciences. (3, no limit Δ)


637. Topics in Algorithms. (3, may be repeated twice Δ)


638. Topics in Architecture and Systems. (3, may be repeated twice Δ)


642. Detection and Estimation Theory. (3)


649. Topics in Control Systems. (3, may be repeated twice Δ)


651. Problems. (1-6 to a maximum of 9 Δ)


661. Topics in Electromagnetics. (3, may be repeated twice Δ)


699. Dissertation. (3-12, no limit Δ)


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MSC11 6325
1 University of New Mexico
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