3 Units. Radar remote sensing, radar image characteristics, viewing geometry, range coding, synthetic aperture processing, correlation, range migration, range/Doppler algorithms, wave domain algorithms, polar algorithm, polarimetric processing, interferometric measurements. One course, see Basic Requirement 4 in the School of Engineering section. Students must receive at least a 2.0 grade point average (GPA) in courses taken for the EE major; all classes, except for classes taken from Spring 2019-2020 to Summer 2020-2021, must be taken for a letter grade. See ee264.stanford.edu for more information. EE 191. They inform students and advisors about university and department requirements, procedures, and opportunities, and they maintain the official records of advising assignments and approvals. Same as: CS 250. Detail view of "Squared [Mini]", an interactive light sculpture by Charles Gadeken, "McWay Falls", black & white photo by Dashiell Corbett [partial image]. Generalization from stability. 3-4 Units. 3 Units. EE 284A. To see them all, click the links below and scroll. EE 104. EE 64SI. Existing blockchains like Bitcoin and Ethereum have an excellent track record in operating securely in such a challenging environment but suffer from several significant drawbacks. As an example, the design of a convolutional neural network (CNN) for basic image recognition illustrates the interaction between hardware and software for machine learning. Applications of optical cavities, including low-threshold lasers, optical modulators, quantum information processing devices, and bio-chemical sensors. Only after receiving department approval of the Application for Candidacy does the student become a candidate for the Ph.D. degree. Prerequisite: EE 284 or CS 144. WDM systems, crosstalk. Syllabus topics will be determined by the needs of the enrolled students and projects. Contributions made to the business world by engineering graduates. It will also teach students to debug their own mechanical designs, and interface them with other components (such as store-bought parts). Any EE majors who must enroll in Autumn are invited to contact the instructor. 3 Units. See the EE Graduate Handbook for more information about the joint degree programs. The information theoretic way of thinking. Linear models; regularization and shrinkage; dimensionality reduction; streaming algorithms; sketching; clustering, search in high dimension; low-rank models; principal component analysis. Topics include: OpenGL, real-time rendering, 3D display systems, display optics & electronics, IMUs and sensors, tracking, haptics, rendering pipeline, multimodal human perception and depth perception, stereo rendering, presence. Pre-requisites: none. Individual or team activities may involve lab experimentation, design of devices or systems, or directed reading. Numerical algorithms for smooth and equality constrained problems; interior-point methods for inequality constrained problems. 3 Units. The department’s student services office is also an important part of the master’s advising team. Engineering Electromagnetics. Continuing education, professional societies, intellectual property and patents, ethics, entrepreneurial engineering, and engineering management. A student currently enrolled in either the Department of Electrical Engineering or the School of Law may apply for admission to the other academic unit and for joint degree status after commencing study in that unit. EE 185C. This course examines this technology and uses green-tech examples to teach the engineering principles of modeling, optimization, analysis, simulation, and design. Distinguished speakers from industry, government, and academia. EE 216. 3 Units. In this class, students will learn about how to build an networked embedded system from the ground up. Applications in areas such as control, circuit design, signal processing, and communications. EE 400. Analytical and approximate treatments of noise and distortion; analysis and design of feedback circuits. Practical aspects of circuit implementations are developed; labs involve building and characterization of subsystems as well as integration of a complete radio system and a final project. Seminar. 3 Units. EE 26N. Functions of random variables. Chirped pulse propagation in dispersive media and its connection to Gaussian beam propagation. Time, subcarrier, code and polarization-division multiplexing. EE 21N. a final course project and written report in lieu of the final assignment. Design, testing, and applications of Radio Frequency (RF) electronics: Amplitude Modulation (AM), Frequency Modulation (FM) and concepts of Software Define Radio (SDR) systems. Prerequisite: 101B. SmartGrids and Advanced Power Systems Seminar. Special Studies and Reports in Electrical Engineering. Same as: CME 107. Prerequisites: EE278 and EE263 or equivalent. Information theory forms the basis for the design of all modern day communication systems. Fano, Assouad,nand Le Cam methods for optimality guarantees in estimation. degree. EE 185A/B/C is a full-year sequence that teaches all of the concepts, knowledge, skills, and techniques to engineer all aspects of a smart object. For EE majors who need work experience as part of their program of study. When most effective, this advising relationship entails collaborative engagement by both the advisor and the advisee. What is Nanotechnology?. 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B. Miller, Subhasish Mitra, Andrea Montanari, Boris Murmann, Dwight G. Nishimura, Oyekunle Olukotun, Brad G. Osgood, John M. Pauly, James D. Plummer, Eric Pop, Balaji Prabhakar, Mendel Rosenblum, Krishna Saraswat, Krishna V. Shenoy, H. Tom Soh, Olav Solgaard, Fouad A. Tobagi, David Tse, Benjamin Van Roy, Jelena Vuckovic, Shan X. Wang, Tsachy Weissman, Jennifer Widom, H. S. Philip Wong, S. Simon Wong, Howard Zebker, Associate Professors: Amin Arbabian, Srabanti Chowdhury, Dawson Engler, Sachin Katti, Philip Levis, Ayfer Ozgur Aydin, Ada Poon, Juan Rivas-Davila, Assistant Professors: Daniel Congreve, John Duchi, Jonathan Fan, Chelsea Finn, Mert Pilanci, Priyanka Raina, Dorsa Sadigh, Caroline Trippel, Gordon Wetzstein, Mary Wootters, Professors (Research): William J. Dally, Butrus Khuri-Yakub, Piero Pianetta, Courtesy Professors: Maneesh Agrawala, Stacey Bent, Kim Butts-Pauly, Emmanuel Candes, E.J. Advanced energy conversion concepts like photon up-conversion, quantum dot solar cells. EE 290D. Most students find an advisor from among the primary faculty members of the department. Prerequisites: Advanced undergraduate or basic graduate level knowledge of electromagnetics, quantum. We will also explore embedded system design and the impact of design decisions by redesigning the electronics from EE 185A to meet low power specifications. ), laser cutters, and 3D printers to demonstrate their ability to build it right the first time. Same as: EE 255. EE 214B. You can now take Master’s degree courses in EE from the Stanford School of Engineering without the commitment of undertaking a full Master’s degree. 3 Units. EE 308. http://web.stanford.edu/class/ee374. Preference to freshman. This course teaches advanced principles for endowing mobile autonomous robots with capabilities to autonomously learn new skills and to physically interact with the environment and with humans. How spaceborne imaging technology makes it possible to respond quickly and mitigate consequences; how it is applied to natural disasters; and remote sensing data manipulation and analysis. 1-3 Unit. No prior photovoltaics knowledge is required. Most of the grade will be based on the project. Preferred: EE 316, EE 309A. The focus is on group IV semiconductors ¿ especially epitaxial and heteroepitaxial deposition, in which the crystal structure of the depositing layer is related to that of the substrate. Atomic systems, spontaneous emission, stimulated emission, amplification. Image Processing of Fine Art. IoT system management tools. The doctoral program, requiring a minimum of 135 units of graduate study, should be considered by those with the ability and desire to make a life's work of research or teaching. Students work on real-world projects with help from members of NGOs and social entrepreneurial companies as part of the hand-on learning experience. To engage in this profession with competence, four years of undergraduate study and at least one year of postgraduate study are recommended. Same as: CS 241. Nyquist and oversampling A/D and D/A converters. Register in Section 02 to take the lab. 4 Units. EE Student Information, Spring Quarter through Academic Year 2020-2021: FAQs and Updated EE Course List. EE 384E. The second part of each lecture will consist of outside speakers, including founders of some of the most exciting companies in Silicon Valley, who will share their experiences about engineering design. Prerequisites: CS106A or equivalent, CME 100 or equivalent (for linear algebra), CME 106 or equivalent (for probability theory), and AA 171/274. Introduction to Linear Dynamical Systems. Prerequisite: one of CS107 or CS 107E (required) and EE108 (recommended but not required). The SEE course portfolio includes one of Stanford's most popular sequences: the three-course Introduction to Computer Science, taken by the majority of Stanford’s undergraduates, as well as more advanced courses … Prerequisites: familiarity with linear algebra (ENGR 108 or equivalent), basic probability and statistics (EE 178 or equivalent), basic programming skills. A course may only be counted towards one requirement; it may not be double-counted. Prerequisite: 236A or equivalent. Focus is on global health and sustainable development by learning from experts in these fields. This is an advanced topics course on building autonomous networks using data and techniques from machine learning. Prerequisites: EE153/EE253. Prerequisites: for 290B, EE MS and PhD students who have received a Satisfactory ("S") grade in EE290A; for 290C, EE PhD degree candidacy and an "S" grade in EE 290B; for 290D, EE PhD degree candidacy, an "S" grade in EE 290C and instructor consent; for 290E, EE PhD degree candidacy, an "S" grade in EE 290D and instructor consent. The program is designed to give … EE 377. Multi-Dimensional Data Transmission. 3 Units. EE 369B. Prerequisite: 102A. A single course can concurrently meet the WIM and Design Requirements. Autonomous Implantable Systems. Independent work under the direction of a faculty member. Similar trends are observed for modern displays pushing the boundaries of resolution, contrast, 3D capabilities, and immersive experiences through the co-design of optics, electronics, and computation. Formerly EE392Q. EE 293B. The profession of electrical engineering demands a strong foundation in physical science and mathematics, a broad knowledge of engineering techniques, and an understanding of the relationship between technology and society. Admission and financial aid are critical aspects in the university experience. Performance evaluation using computer-aided design tools. Operating principles and practical device features of semiconductor optoelectronic materials and heterostructures. The program proposal must be submitted to the Degree Progress Officer before the end of the first quarter of graduate study (second quarter for Honors Cooperative Program students); a final revised version is due at the beginning of the final quarter of study, prior to degree conferral. Completion of the undergraduate program in Electrical Engineering leads to the conferral of the Bachelor of Science in Electrical Engineering. Formerly EE 278B. Students identify their doctoral research/thesis advisor, pass the qualifying exam, and advance to candidacy prior to the end of the second year of study. Analysis techniques based on Fourier transforms and energy/power spectral density will be developed. Applied linear algebra and linear dynamical systems with applications to circuits, signal processing, communications, and control systems. Linearity and time invariance. Same as: CME 364B. Modes in waveguides: slab, rectangular, circular. Extensive use of modern CAD tools. IEEE 802.11 physical layer specifications: FHSS, DSSS, IEEE 802.11b (CCK), and 802.11a/g (OFDM). 3 Units. Optimized ensembles, message passing algorithms, density evolution, and analytic techniques. Functional blocks of IoT systems: devices, communications, services, management, security, and application. Digital circuit, logic, and system design. The topics that will be … Prerequisite: EE 101A and EE 102A. Multichannel systems. 1-15 Unit. The University requirements for the Ph.D. degree are described in the “Graduate Degrees” section of this bulletin. 3 Units. SystemX: Ubiquitous Sensing, Computing and Communication Seminar. Declare the EE Honors major in Axess before the end of Autumn Quarter of senior year. 3 Units. Formerly EE 108B. This class is part of a multi-disciplinary collaboration between researchers in the CS, EE, and TAPS departments to design and develop a system to host a live theatrical production that will take place over the Internet in the winter quarter. How can we make sound decisions based on partial and noisy information? Renewable energy will make up at least half of the generation mix and drive adoption of novel technologies such as storage, fuel cells, waste to power and distributed generation. Such students may be allowed to complete a master’s degree in Electrical Engineering instead. 3 Units. EE 355. 3 Units. Students are encouraged to meet with the program advisor during the first quarter to go over their proposed master’s plan. 1-4 Unit. Students will be able to take courses with Satisfactory/Credit (S/CR) grades to count toward the EE degree requirements for all graduate degree programs. Algorithm design for pipelining and parallelism. Microscopic and macroscopic description of electric-dipole susceptibilities. In this master’s program, courses taken during or after the first quarter of the sophomore year are eligible for consideration for transfer to the graduate career; the timing of the first graduate quarter is not a factor. Depending on units completed in the Disciplinary Area, elective units will be in the range of 17 units or less. Loss function selection and its effect on learning. Read more.. EE Student Information, Spring Quarter through Academic Year 2020-2021: FAQs and Updated EE Course List. Elements of probability, conditional probability, Bayes rule, independence. Same as: CME 364A. Bit-level arithmetic: carry-save and redundant arithmetic. 3-4 Units. Prerequisites: Math through ODEs, basic linear algebra, Comfort with sums and discrete signals, Fourier series at the level of 102A. Previous companies profiled: Apple, Intel, Facebook, and Genentech -- to name a few. in EE degree: The Department of Electrical Engineering and the School of Law offer a joint degree program leading to an M.S. The course taken must be on the School of Engineering Approved Courses list, Fig 4-3, the year it is taken. 3 Units. 3 Units. Reconstruction problems from medical imaging, including magnetic resonance imaging (MRI), computed tomography (CT), and positron emission tomography (PET). The course comprises of lectures and hands-on laboratory experiments. 4 Units. 3 Units. Through lectures and lab visits, we'll learn how information can be measured and represented, why bits are the universal currency for information exchange, and how these ideas led to smartphones, the Internet, and more. Prerequisites: EE276 (Formerly EE376A). Successful products are the highest impact contribution anyone can make in product development. In this class we will discuss the design and modeling of magnetic components, which are essential tasks in the development of high performance converters and study advanced applications. Emphasis is on quantum mechanical foundations of the properties of solids, energy bandgap engineering, semi-classical transport theory, semi-conductor statistics, carrier scattering, electro-magneto transport effects, high field ballistic transport, Boltzmann transport equation, quantum mechanical transitions, optical absorption, and radiative and non-radiative recombination that are the foundations of modern transistors and optoelectronic devices. 3 Units. 3 Units. Prerequisite: Students must be currently enrolled in a MS or PhD engineering degree program. 1 Unit. EE 368. Topics covered include ac and dc rotating machines, power electronics inverters and drives, and control techniques. Upon completion of the qualifying examination and after securing agreement by two faculty members to serve as dissertation advisor and second reader, the student files an Application for Candidacy for Doctoral Degree. Analog-Digital Interface Circuits. Advanced techniques and models of MOS devices and back-end (interconnect and contact) processing. In weekly labs students create software to form images using these techniques with actual data. EE 385A. 1 Unit. Introduction to probability and its role in modeling and analyzing real world phenomena and systems, including topics in statistics, machine learning, and statistical signal processing. EE 387. Same as: STATS 376A. Recommended: ENGR40 or EE122A. Structure and components of computer networks; functions and services; packet switching; layered architectures; OSI reference model; physical layer; data link layer; error control; window flow control; media access control protocols used in local area networks (Ethernet, Token Ring, FDDI) and satellite networks; network layer (datagram service, virtual circuit service, routing, congestion control, Internet Protocol); transport layer (UDP, TCP); application layer.
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