ut austin ece degree plan

Solid-state properties of metals, semiconductors, and ceramics; fundamental concepts needed for the description of these properties, using an introductory-level description of the electronic structure of solids. Andreas Gerstlauer, Office Home - University of Texas at Austin Topic 20: Plasma Processing of Semiconductors II. Only one of the following may be counted: Mechanical Engineering 386T (Topic 2), Electrical Engineering 396K (Topic 11), Electrical and Computer Engineering 396K (Topic 11). Three lecture hours a week for one semester. Electrical and Computer Engineering 383P (Topic 4) and Electrical Engineering 383P (Topic 4) may not both be counted. Electrical and Computer Engineering 396K (Topic 5) and Electrical Engineering 396K (Topic 5) may not both be counted. Prerequisite: Electrical and Computer Engineering 411 (or Electrical Engineering 411) or 411H, Mathematics 427J or 427K, Physics 303L, and Physics 105N or 103N with a grade of at least C- in each; and credit with a grade of at least C- or registration for Mathematics 427L. Topic 17: Biomedical Instrumentation II: Real-Time Computer-Based Systems. Electrical and Computer Engineering 374N and Electrical Engineering 379K (Topic: Neural Engineering) may not both be counted. Three lecture hours a week for one semester. Two lecture hours and three laboratory hours a week for one semester. Topic 7: Ultrasonics. Examine edge computing; Internet-of-Things (IoT); cyber-physical systems; energy-aware machine learning (ML); deep learning; model compression; knowledge distillation; federated learning; ML security; system optimization; model-architecture co-design; object detection; and social sensing. Basic principles of optical tomographic imaging of biological materials for diagnostic or therapeutic applications. May be repeated for credit when the topics vary. Review the most important materials families of solar cells including single crystal silicon; polysilicon; amorphous silicon; solar cells based on CdTe and copper indium diselenide and related compounds; and III-V compound semiconductor heterojunction solar cells including tandem cells and space-grade solar cells. Study approaches to design motor neuroprosthetics and sensory neuroprosthetics that restore lost functions. Examine principles and practices of guided-wave optical sensor technology. Explore commercial general-purpose processors, memory architecture, buses, storage devices, graphics subsystems, I/O devices and peripherals, audio subsystems, operating systems, benchmarking, manufacturing, and testing of personal computer systems. Explore design and development of at-scale software system using modern software development techniques, including re-usable front-end and back-end components, and cloud deployment. Undergraduate Degree Planning - University of Texas at Austin Electrical and Computer Engineering 382M (Topic 19) and Electrical Engineering 382M (Topic 19) may not both be counted. The equivalent of three lecture hours a week for two semesters. Prerequisite: Mathematics 408D or 408M with a grade of at least C-, and Physics 303L and 103N with a grade of at least C- in each. Only one of the following may be counted: Electrical and Computer Engineering 364D, 364E, Electrical Engineering 364D, 364E. Same as Mechanical Engineering 386R (Topic 2). Prerequisite: Graduate standing. This form must be submitted before 12 hours of graduate coursework are completed at UT Austin. The University of Texas at Austin offers state and Southern Association of Colleges and Schools (SACS) approved teacher preparation programs. Examine probability, random variables, statistics, and random processes, including counting, independence, conditioning, expectation, density functions, distributions, law of large numbers, central limit theorem, confidence intervals, hypothesis testing, statistical estimation, stationary processes, Markov chains, and ergodicity. Topic 20: Computer Architecture: Personal Computer Design. Additional prerequisite: Undergraduate course in semiconductor devices or the equivalent, or consent of instructor. Electrical and Computer Engineering 382P (Topic 1) and Electrical Engineering 382P (Topic 1) may not both be counted. Offered on the pass/fail basis only. Examine physical principles and operational characteristics of semiconductor devices. Explore the fundamentals of wireless communication from a digital signal processing perspective; linear modulation, demodulation, and orthogonal frequency division multiplexing; synchronization, channel estimation, and equalization; communication in fading channels; principles of multiple-input, multiple-output (MIMO) communication; and wireless standards. Explore digital and analog parametric testing of mixed-signal circuits and systems, including frequency response, harmonic and intermodulation, and noise behavior; use of system-level test equipment, including network analyzers, spectrum analyzers, and probe stations; coherent versus noncoherent measurements; and design for testability. Prerequisite: Electrical and Computer Engineering 312 (or Electrical Engineering 312) or 312H (or Electrical Engineering 312H) and 319K (or Electrical Engineering 319K) or 319H (or Electrical Engineering 319H) with a grade of at least C- in each; Biomedical Engineering 343, Electrical and Computer Engineering 313 (or Electrical Engineering 313), or 313H with a grade of at least C-; credit with a grade of at least C- or registration for Aerospace Engineering 333T, Biomedical Engineering 333T, Chemical Engineering 333T, Civil Engineering 333T, Electrical and Computer Engineering 333T (or Electrical Engineering 333T), Engineering Studies 333T, Mechanical Engineering 333T, or Petroleum and Geosystems Engineering 333T; and credit with a grade of at least C- or registration for Biomedical Engineering 335, Electrical and Computer Engineering 351K (or Electrical Engineering 351K), or 351H. Three lecture hours a week for one semester. Explore transceiver architectures. Introduction to network, software, and web security; risk assessments; data breach incident response; privacy laws and regulations. Only one of the following may be counted: Biomedical Engineering 384J (Topic 2), Electrical and Computer Engineering 385J (Topic 17), Electrical Engineering 385J (Topic 17). Offered on the credit/no credit basis only. Electrical and Computer Engineering 381K (Topic 8) and Electrical Engineering 381K (Topic 8) may not both be counted. May be repeated for credit when the topics vary. Deliver an oral presentation and write a thesis. Same as Biomedical Engineering 384J (Topic 6). Our mission is to create, maintain, certify, and protect University records of courses, degrees, and students. Prerequisite: Mathematics 427J or 427K with a grade of at least C-. For each semester hour of credit earned, the equivalent of one lecture hour a week for one semester. Same as Operations Research and Industrial Engineering 391Q (Topic 15). Same as Biomedical Engineering 381J (Topic 3). University credit is awarded for work in an exchange program; it may be counted as coursework taken in residence. Electrical and Computer Engineering 422C and Electrical Engineering 422C may not both be counted. Develop a completed company prospectus and seek venture funding for the project. The Master's Program in Early Childhood Education (ECE) focuses on important learning theories for young children and the curriculum that helps develop young learners. Examine semiconductor materials and nanomaterials growth. UT Mourns Lithium-Ion Battery Inventor and Nobel Prize Recipient John Goodenough. Hear presentations by speakers from industry, government, academia, and professional private practice. Electrical and Computer Engineering 380N (Topic 1) and Electrical Engineering 380N (Topic 1) may not both be counted. Early Childhood Education Master's Degree Program - UT Austin Electrical and Computer Engineering 362K and Electrical Engineering 362K may not both be counted. Topic 8: Optical Communications. Same as Mechanical Engineering 386T (Topic 4). Explore topologies, routing algorithms, permutations, resource allocations, performance evaluation, fault tolerance, VLSI design, parallel and distributed algorithms, languages for specifying protocols, and distributed operating systems. Topic 8: Theory Blockchains and Smart Contracts. May be repeated for credit when the topics vary. Examine content analysis; information retrieval, clustering, and hierarchical categorization of Web documents; web usage mining; and collaborative filtering and personalizing the Web. Examine network structure and dynamics, machine learning on real networks, clustering; network models, small worlds, scale free networks, preferential attachment, community structure, network-on-chip optimization and control, epidemics and rumors, human mobility, network embedding, deep learning on graphs, graph neural networks, and other networks. Only one of the following may be counted: Mechanical Engineering 384N (Topic 9), 397 (Topic: Acoustic Metamaterials), Electrical and Computer Engineering 384N (Topic 9). Same as Operations Research and Industrial Engineering 391Q (Topic 16). Three lecture hours and three laboratory hours a week for one semester. PDF Texas Early Childhood & Child Development Programs - TECPDS Topic 16: Software Testing. For each semester hour of credit earned, one lecture hour a week for one semester. Introduction to the electronic, magnetic, and optical properties of materials. Core Component Areas: 010 English Composition and Core Writing Flag; 020 Mathematics; 030 Natural Science and Technology, Part I; 040 Humanities; 050 Visual and Performing Arts; 060 U.S. History . Examine integrated circuit processing; crystal growth and wafer preparation; epitaxial growth; oxidation, diffusion, and ion implantation; thin-film deposition techniques; and lithography and etching. Electrical and Computer Engineering 396M (Topic 2) and Electrical Engineering 396V (Topic: Quantum Information Hardware) may not both be counted. A candidate for any degree must be enrolled at The University of Texas at Austin in the semester or summer session in which the degree is awarded. Electrical and Computer Engineering 396K (Topic 22) and Electrical Engineering 396K (Topic 22) may not both be counted. Examine distributed generation and microgrids elements; microsources; energy storage; power electronics interfaces; DC and AC architectures; economics, operation, stabilization, and control; reliability and availability aspects; interaction between microgrids and bulk power grids; and smart grids. Prerequisite: Computer Science 312, 312H, Electrical and Computer Engineering 312 (or Electrical Engineering 312) or 312H (or Electrical Engineering 312H) with a grade of at least C-. Electrical and Computer Engineering 380N (Topic 8) and Electrical Engineering 380N (Topic 8) may not both be counted. Electrical and Computer Engineering 396N (Topic 1) and Electrical Engineering 396N (Topic 1) may not both be counted. Topic 11: Advanced Power Electronics. Topic 21: Information and Cryptography. Learn More 14 Undergraduate and Graduate Programs Ranked in the Top 10 4 National Medal Winners 1 Nobel Prize Recipient Spotlights Happening now at Texas Engineering Description of electrons, from free atoms to crystals; band theory contrasted with crystal-field theory; evolution of electronic properties on passing from magnetic insulators to normal metals, from ionic to covalent solids, from single-valent compounds to mixed-valent systems; electron-lattice interactions and phase transitions; many examples. The equivalent of three lecture hours a week for one semester. Three lecture hours a week for one semester. Students in the ECB program must satisfy the university Core Curriculum and the combined degree requirements for a Bachelor of Science in Electrical and Computer Engineering with the ECE Honors . Electrical and Computer Engineering 394J (Topic 9) and Electrical Engineering 394J (Topic 9) may not both be counted. Electrical and Computer Engineering 370N and Electrical Engineering 370N may not both be counted. Suggested Arrangement of Courses, Electrical and - University Catalogs Electrical and Computer Engineering 381K (Topic 11) and Electrical Engineering 381K (Topic 11) may not both be counted. Topic 23: Software Evolution. Three lecture hours a week for one semester. Same as Mechanical Engineering 386R (Topic 1). Offered on the letter-grade basis only. Examine the development of several system families and follow common threads of identifying the intended users, system properties, and evaluation methodology. Explore the development of a specific technical skill. Only one of the following may be counted: Electrical and Computer Engineering 384N (Topic 3), Electrical Engineering 384N (Topic 3), Mechanical Engineering 384N (Topic 3). Electrical and Computer Engineering 338L and Electrical Engineering 338L may not both be counted. Electrical and Computer Engineering 461L and Electrical Engineering 461L may not both be counted. Topic 1: Metal Oxide Semiconductor Devices: Physics and Technology. Examine dynamic properties of semiconductor lasers; intensity, phase, and frequency noise; dynamic lasing spectra, chirp, and mode partition noise; injection locking and optical feedback; short pulse generation by mode-locking and gain switching; single-mode distributed feedback, distributed Bragg reflector (DBR), and coupled-cavity lasers; wavelength-tunable single-mode lasers; externally modulated lasers; coherent high-power laser arrays; quantum-dot lasers and amplifiers; vertical-cavity surface-emitting lasers; and integrated wavelength-division multiplexing (WDM) laser arrays and photonic integrated circuits. Explore the application of electrical engineering principles in the design of electronic instrumentation at the circuit-board level for the measurement of pressure, temperature, flow, and impedance. Prerequisite: Credit with a grade of at least C- or registration for Mathematics 408C or 408K. Three lecture hours a week for one semester. Restricted to students in the electrical and computer engineering honors program. Explore software design principles; program differencing techniques; program transformation languages and tools; and analysis, testing, debugging and visualization methods for evolving software. Only one of the following may be counted: Electrical and Computer Engineering 351H, 351K, Electrical Engineering 351K. Topic 8: Ultra-Large-Scale Integration Techniques. May be repeated for credit. Topic 6: Magnetic Phenomena in Materials. Topic 29: Thin Film Transistors. Electrical and Computer Engineering 382P (Topic 8) and Electrical Engineering 382P (Topic 8) may not both be counted. Examine tracking dependency, mutex algorithms, snapshot algorithms, leader election, spanning tree, distributed algorithms, Map-Reduce, slicer, termination detection, message order, synchronizers, self-stabilization, knowledge, consensus, Byzantine agreement, fault-tolerance. Only one of following may be counted: Electrical and Computer Engineering 461P, Electrical Engineering 361M, 461P. Electrical and Computer Engineering 382C (Topic 3) and Electrical Engineering 382C (Topic 3) may not both be counted. Prerequisite: Electrical and Computer Engineering 325 (or Electrical Engineering 325) with a grade of at least C-. Prerequisite: Graduate standing. Electrical and Computer Engineering 361C and Electrical Engineering 361C may not both be counted. Explore the analysis and design of analog integrated circuits; transistor models; simple and advanced current mirrors; single-ended amplifiers; differential amplifiers; operational amplifiers; frequency response; feedback theory; stability analysis; circuit nonidealities and noise; output stages; and analog filters. Students can choose between an M.Ed. Examine dynamic programming in finite and infinite horizon, models with imperfect state information, ergodic control problems, and adaptive and risk-sensitive control. Additional prerequisite: Electrical and Computer Engineering 396K (Topic 16) or the equivalent. Analyze, design, and construct a solar-powered car for national competitions involving other universities. Only one of the following may be counted: Electrical and Computer Engineering 382C (Topic 12), Electrical Engineering 382C (Topic 12), 382V (Topic: Multicore Computing). Examine fundamentals of runtime systems; design, implementation, and optimization of emulation engines; interpreters; binary translators; dynamic binary optimization; high-level language virtual machines; co-designed virtual machines; system-level virtual machines; and processor virtualization. Three lecture hours a week for one semester. Electrical and Computer Engineering 380N (Topic 2) and Electrical Engineering 380N (Topic 2) may not both be counted. The PDF will include all information unique to this page. Explore methods and research issues in the performance evaluation and management of high-speed and mobile communication networks. Same as Biomedical Engineering 381J (Topic 2). Electrical and Computer Engineering 382N (Topic 11) and Electrical Engineering 382N (Topic 11) may not both be counted. Prerequisite: Electrical and Computer Engineering 460J (or Electrical Engineering 460J) or Computer Science 342 with a grade of at least C-. Electrical and Computer Engineering 325 and Electrical Engineering 325 may not both be counted. Examine the principles of compound semiconductor lasers and LEDs; bulk and quantum-well laser structures; radiative and nonradiative recombination processes; optical, electrical, and thermal properties of lasers; dynamic rate equations and modulation characteristics; lasing spectra, chirp, modal noise and linewidth; and edge-emitting and surface-emitting lasers. Only one of the following may be counted: Biomedical Engineering 384J (Topic 5), Electrical and Computer Engineering 385J (Topic 32), Electrical Engineering 385J (Topic 32). Prerequisite: Biomedical Engineering 306, Computer Science 429, Electrical and Computer Engineering 306 (or Electrical Engineering 306) or 306H (or Electrical Engineering 306H) with a grade of at least C-. Topic 6: Architectural Acoustics. Examine probability, random variables, statistics, and random processes, including counting, independence, conditioning, expectation, density functions, distributions, law of large numbers, central limit theorem, confidence intervals, hypothesis testing, statistical estimation, stationary processes, Markov chains, and ergodicity. Same as Mechanical Engineering 384N (Topic 6). Only one of the following may be counted: Electrical and Computer Engineering 379K (Topic 23), Electrical Engineering 379K (Topic: Software Evolution), 379K (Topic 23). Electrical and Computer Engineering 382M (Topic 14) and Electrical Engineering 382M (Topic 14) may not both be counted. Topic 16: Application-Specific Processing. Electrical and Computer Engineering 382N (Topic 20) and Electrical Engineering 382N (Topic 20) may not both be counted. Stephen F. Austin State University Nacogdoches B.S.I.S. Topic 7: Software Architectures. Three lecture hours a week for one semester. Explore market dispatch formulated as an optimization problem, unit commitment issues, and pricing rules and incentives in markets; energy- price and transmission-price risk hedging and energy network models; and revenue adequacy of financial transmission rights, a mixed-integer programming approach to unit commitment, the representation of voltage constraints into market models, and the design of electricity markets to mitigate market power. The equivalent of three lecture hours a week for one semester. Topic 9: Power Quality. Prerequisite: Electrical and Computer Engineering 364D (or Electrical Engineering 364D) with a grade of at least C-, and one of the following with a grade of at least C-: Electrical and Computer Engineering 438 (or Electrical Engineering 438), 440 (or Electrical Engineering 440), 445L (or EE445L), 445S (or Electrical Engineering 445S), 460J (or Electrical Engineering 460J), 461L (or Electrical Engineering 461L), 462L (or Electrical Engineering 462L), 468L, 471C (or Electrical Engineering 471C). Examine quantum mechanical principles as applied to electron devices, lasers, and electro-optics; material properties and interaction of radiation and material. Topic 23: Embedded System Design and Modeling. Same as Biomedical Engineering 384J (Topic 1). Learn principles of deep brain stimulation, neuromodulation, and brain plasticity. Educator Programs and Certification Overview - UT Austin Topic 1: Power System Engineering I. Prerequisite: Upper-division standing; Electrical and Computer Engineering 351M (or Electrical Engineering 351M) or 445S (or Electrical Engineering 351M); Electrical and Computer Engineering 461P (or Electrical Engineering 461P) or 460J (or Electrical Engineering 460J); and consent of the instructor. Three lecture hours a week for one semester. Topic 9: Fundamentals of Robotics and Mechatronics. Electrical and Computer Engineering 396K (Topic 23) and Electrical Engineering 396K (Topic 23) may not both be counted. Prerequisite: Credit with a grade of at least C- or registration for Mathematics 408D. Degree requirements for each plan can vary greatly by catalog year. Additional prerequisite: Biomedical Engineering 384J (Topic 1) or Electrical and Computer Engineering 385J (Topic 31) (or Electrical Engineering 385J (Topic 31)). UT Cockrell School of Engineering Participate in an individual laboratory. in Curriculum and Instruction, 2018, Assistant Professor of Bilingual Bicultural Education, Texas State University Currently enrolled students should meet with their academic advisor. Explore architecture development for mixed-signal integrated circuits. Prerequisite: Graduate standing and Electrical and Computer Engineering 381J (or Electrical Engineering 381J). Explore fundamental principles in computer architecture focusing on the hardware and the compiler, as well as developing an understanding of their interplay with each other and with usage and programming models. Credit is recorded as assigned by the study abroad advisor in the Department of Electrical and Computer Engineering. Only one of the following may be counted: Electrical and Computer Engineering 302, 302H, Electrical Engineering 302, 302H. Additional prerequisite: Consent of instructor. Additional prerequisite: Consent of instructor. Electrical and Computer Engineering 382C (Topic 1) and Electrical Engineering 382C (Topic 1) may not both be counted. MSE Degree Requirements - ECE Graduate Program Handbook - UT Austin Wikis Texas A&M president Katherine Banks resigns | The Texas Tribune Examine renewable energy sources and their integration into power systems. Topic 6: Estimation Theory. Examine automatic verification of digital systems; formal models and specifications, equivalence checking, design verification, temporal logic, binary decision diagrams (BDDs), logical foundations, automata theory, recent developments. Only one of the following may be counted Electrical and Computer Engineering 384N (Topic 8), Electrical Engineering 384N (Topic 8), Mechanical Engineering 384N (Topic 8), 397 (Topic: Wave Phenomena). Option III (Non-Formula-Funded) Graduate Programs Electrical and Computer Engineering 472L and Electrical Engineering 372L may not both be counted. Explore behavioral-level design of a microarchitecture in a laboratory setting. Offered on the letter-grade basis only. Explore the definitions, motivations, and utility of software system architectures from a technical and business perspective; derivation, specification, and analysis of architectural views in support of different phases in the system engineering lifecycle; methods to judge architectural quality; and communication of architectural views to a wide range of system stakeholders. Additional prerequisite: Knowledge in probability and random processes, digital signal processing, and matrices and matrix calculations.
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