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EE 300: Master's Thesis and Thesis Research

Independent work under the direction of a department faculty. Written thesis required for final letter grade. The continuing grade 'N' is given in quarters prior to thesis submission. See 390 if a letter grade is not appropriate. Course may be repeated for credit.
Terms: Aut, Win, Spr, Sum | Units: 1-15 | Repeatable for credit
Instructors: Allison, D. (PI) ; Bambos, N. (PI) ; Boneh, D. (PI) ; Bosi, M. (PI) ; Boyd, S. (PI) ; Bravman, J. (PI) ; Bube, R. (PI) ; Byer, R. (PI) ; Cheriton, D. (PI) ; Chidsey, C. (PI) ; Cioffi, J. (PI) ; Cover, T. (PI) ; Cox, D. (PI) ; DaRosa, A. (PI) ; Dally, B. (PI) ; Dasher, R. (PI) ; Dill, D. (PI) ; Dutton, R. (PI) ; El Gamal, A. (PI) ; Emami-Naeini, A. (PI) ; Engler, D. (PI) ; Eshleman, V. (PI) ; Fan, S. (PI) ; Flynn, M. (PI) ; Franklin, G. (PI) ; Fraser-Smith, A. (PI) ; Garcia-Molina, H. (PI) ; Gibbons, F. (PI) ; Gibbons, J. (PI) ; Gill, J. (PI) ; Girod, B. (PI) ; Glover, G. (PI) ; Goldsmith, A. (PI) ; Goodman, J. (PI) ; Gorinevsky, D. (PI) ; Gray, R. (PI) ; Guibas, L. (PI) ; Hanrahan, P. (PI) ; Harris, J. (PI) ; Harris, S. (PI) ; Hennessy, J. (PI) ; Hesselink, L. (PI) ; Horowitz, M. (PI) ; Howe, R. (PI) ; Inan, U. (PI) ; Kahn, J. (PI) ; Kailath, T. (PI) ; Kazovsky, L. (PI) ; Khuri-Yakub, B. (PI) ; Kino, G. (PI) ; Kovacs, G. (PI) ; Kozyrakis, C. (PI) ; Lall, S. (PI) ; Lam, M. (PI) ; Lee, T. (PI) ; Leeson, D. (PI) ; Levis, P. (PI) ; Levoy, M. (PI) ; Linscott, I. (PI) ; Luckham, D. (PI) ; Macovski, A. (PI) ; Manoharan, H. (PI) ; McCluskey, E. (PI) ; McKeown, N. (PI) ; Melen, R. (PI) ; Meng, T. (PI) ; Miller, D. (PI) ; Mitchell, J. (PI) ; Mitra, S. (PI) ; Montanari, A. (PI) ; Murmann, B. (PI) ; Napel, S. (PI) ; Narasimha, M. (PI) ; Ng, A. (PI) ; Nishi, Y. (PI) ; Nishimura, D. (PI) ; Olukotun, O. (PI) ; Osgood, B. (PI) ; Paulraj, A. (PI) ; Pauly, J. (PI) ; Pease, R. (PI) ; Pelc, N. (PI) ; Pianetta, P. (PI) ; Plummer, J. (PI) ; Popelka, G. (PI) ; Powell, J. (PI) ; Prabhakar, B. (PI) ; Pratt, V. (PI) ; Quate, C. (PI) ; Rosenblum, M. (PI) ; Saraswat, K. (PI) ; Shahidi, R. (PI) ; Shen, Z. (PI) ; Shenoy, K. (PI) ; Siegel, M. (PI) ; Smith, J. (PI) ; Solgaard, O. (PI) ; Spielman, D. (PI) ; Stinson, J. (PI) ; Thrun, S. (PI) ; Tobagi, F. (PI) ; Tyler, G. (PI) ; Ullman, J. (PI) ; Van Roy, B. (PI) ; Vuckovic, J. (PI) ; Walt, M. (PI) ; Wandell, B. (PI) ; Wang, S. (PI) ; Weissman, T. (PI) ; Wenstrand, J. (PI) ; White, R. (PI) ; Widom, J. (PI) ; Widrow, B. (PI) ; Wong, H. (PI) ; Wong, S. (PI) ; Wooley, B. (PI) ; Yamamoto, Y. (PI) ; Zebker, H. (PI)

EE 303: Autonomous Implantable Systems

Integrating electronics with sensing, stimulation, and locomotion capabilities into the body will allow us to restore or enhance physiological functions. In order to be able to insert these electronics into the body, energy source is a major obstacle. This course focuses on the analysis and design of wirelessly powered catheter-deliverable electronics. Emphases will be on the interaction between human and electromagnetic fields in order to transfer power to the embedded electronics via electromagnetic fields, power harvesting circuitry, electrical-tissue interface, and sensing and actuating frontend designs. Prerequisites: EE 252 or equivalent.
Last offered: Spring 2015

EE 304: Neuromorphics: Brains in Silicon (BIOE 313)

Neuromorphic systems run perceptual, cognitive and motor tasks in real-time on a network of highly interconnected nonlinear units. To maximize density and minimize energy, these units--like the brain's neurons--are heterogeneous and stochastic. The first half of the course covers learning algorithms that automatically synthesize network configurations to perform a desired computation on a given heterogeneous neural substrate. The second half of the course surveys system-on-a-chip architectures that efficiently realize highly interconnected networks and mixed analog-digital circuit designs that implement area and energy-efficient nonlinear units. Prerequisites: EE102A and EE108 are required; EE114 is recommended.
Terms: Spr | Units: 3
Instructors: Boahen, K. (PI) ; Fok, S. (TA)

EE 308: Advanced Circuit Techniques

Design of advanced analog circuits at the system level, including switching power converters, amplitude-stabilized and frequency-stabilized oscillators, voltage references and regulators, power amplifiers and buffers, sample-and-hold circuits, and application-specific op-amp compensation. Approaches for finding creative design solutions to problems with difficult specifications and hard requirements. Emphasis on feedback circuit techniques, design-oriented thinking, and hands-on experience with modern analog building blocks. Several designs will be built and evaluated, along with associated laboratory projects. Prerequisite: EE 251 or EE 314A.
Terms: Win | Units: 3
Instructors: Lee, T. (PI) ; Chen, Y. (TA)

EE 309: Semiconductor Memory Devices and Technology

The functionality and performance of ULSI systems are increasingly dependent upon the characteristics of the memory subsystem. This course introduces the student to various memory devices: SRAM, DRAM, NVRAM (non-volatile memory). This course will cover various aspects of semiconductor memories, including basic operation principles, device design considerations, device scaling, device fabrication, memory array addressing and readout circuits. Various cell structures (e.g. 1T-1C, 6T, 4T, 1T-1R, 0T-1R, 1S-1R, floating gate FLASH, SONOS, NROM), and memory organization (open bit-line, folded bit-line, NAND, NOR, cross-point etc.). This course will include a survey of new memory concepts (e.g. magnetic tunnel junction memory (MRAM, SST-RAM), ferroelectric memory (FRAM), phase change memory (PCM), metal oxide resistive switching memory (RRAM), nanoconductive bridge memory (CBRAM)). Offered Alternate years. Pre-requisite: EE 216. Preferred: EE 316.
Last offered: Autumn 2013

EE 310: SystemX: Ubiquitous Sensing, Computing and Communication Seminar

This is a seminar course with invited speakers. Sponsored by Stanford¿s SystemX Alliance, the talks will cover emerging topics in contemporary hardware/software systems design. Special focus will be given to the key building blocks of sensors, processing elements and wired/wireless communications, as well as their foundations in semiconductor technology, SoC construction, and physical assembly as informed by the SystemX Focus Areas. The seminar will draw upon distinguished engineering speakers from both industry and academia who are involved at all levels of the technology stack and the applications that are now becoming possible.
Terms: Aut, Win, Spr | Units: 1
Instructors: Bahr, R. (PI)

EE 311: Advanced Integrated Circuits Technology

What are the practical and fundamental limits to the evolution of the technology of modern MOS devices and interconnects? How are modern devices and circuits fabricated and what future changes are likely? Advanced techniques and models of MOS devices and back-end (interconnect and contact) processing. What are future device structures and materials to maintain progress in integrated electronics? MOS front-end and back-end process integration. Prerequisites: EE212, EE216 or equivalent.
Terms: Spr | Units: 3
Instructors: Saraswat, K. (PI)

EE 314A: RF Integrated Circuit Design

Design of RF integrated circuits for communications systems, primarily in CMOS. Topics: the design of matching networks and low-noise amplifiers at RF, mixers, modulators, and demodulators; review of classical control concepts necessary for oscillator design including PLLs and PLL-based frequency synthesizers. Design of low phase noise oscillators. Design of high-efficiency (e.g., class E, F) RF power amplifiers, coupling networks. Behavior and modeling of passive and active components at RF. Narrowband and broadband amplifiers; noise and distortion measures and mitigation methods. Overview of transceiver architectures. Prerequisite: EE214B.
Terms: Spr | Units: 3
Instructors: Arbabian, A. (PI) ; Baltsavias, S. (TA) ; Seyed Aliroteh, M. (TA)

EE 314B: Advanced RF Integrated Circuit Design

Analysis and design of modern communication circuits and systems with emphasize on design techniques for high-frequency (into mm-wave) ICs. Topics include MOS, bipolar, and BiCMOS high-frequency integrated circuits, including power amplifiers, extremely wideband amplifiers, advanced oscillators, phase-locked loops and frequency-translation circuits. Design techniques for mm-wave silicon ICs (on-chip low-loss transmissions lines, unilateralization techniques, in-tegrated antennas, harmonic generation, etc) will also be studied. Prerequisite: EE314A or equivalent course in RF or microwave.
Last offered: Spring 2015

EE 315: Analog-Digital Interface Circuits

Analysis and design of circuits and circuit architectures for signal conditioning and data conversion. Fundamental circuit elements such as operational transconductance amplifiers, active filters, sampling circuits, switched capacitor stages and voltage comparators. Sensor interfaces for micro-electromechanical and biomedical applications. Nyquist and oversampling A/D and D/A converters. Prerequisite: EE 214B.
Terms: Aut | Units: 3
Instructors: Murmann, B. (PI)
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