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1 - 10 of 22 results for: EE

EE 47: Press Play: Interactive Device Design

Introduction to the human-centered and technical workings behind interactive devices ranging from cellphones and video controllers to smart cars and appliances. Students build a working MP3 player prototype of their own design, using embedded microcontrollers, digital audio decoders and component sensors, and other electronic hardware. Topics include electronics prototyping, interface prototyping, sensors and actuators, micro-controller development, physical prototyping, and user testing. Prerequisite: CS106A and X or consent of instructor.
Terms: Sum | Units: 3
Instructors: Sirkin, D. (PI)

EE 102A: Signal Processing and Linear Systems I

Concepts and tools for continuous- and discrete-time signal and system analysis with applications in signal processing, communications, and control. Mathematical representation of signals and systems. Linearity and time invariance. System impulse and step responses. System frequency response. Frequency-domain representations: Fourier series and Fourier transforms. Filtering and signal distortion. Time/frequency sampling and interpolation. Continuous-discrete-time signal conversion and quantization. Discrete-time signal processing. Prerequisite: MATH 53 or ENGR 155A.
Terms: Win, Sum | Units: 4 | UG Reqs: GER:DB-EngrAppSci, WAY-AQR, WAY-FR

EE 190: Special Studies or Projects in Electrical Engineering

Independent work under the direction of a faculty member. Individual or team activities involve lab experimentation, design of devices or systems, or directed reading. Course may be repeated for credit.
Terms: Aut, Win, Spr, Sum | Units: 1-15 | Repeatable for credit
Instructors: Aghajan, H. (PI) ; Allison, D. (PI) ; Apostolopoulos, J. (PI) ; Arbabian, A. (PI) ; Bahai, A. (PI) ; Bambos, N. (PI) ; Boahen, K. (PI) ; Boneh, D. (PI) ; Bosi, M. (PI) ; Bowden, A. (PI) ; Boyd, S. (PI) ; Bravman, J. (PI) ; Bube, R. (PI) ; Cheriton, D. (PI) ; Cioffi, J. (PI) ; Cover, T. (PI) ; Cox, D. (PI) ; DaRosa, A. (PI) ; Dally, B. (PI) ; Dasher, R. (PI) ; De-Micheli, G. (PI) ; Dill, D. (PI) ; Dutton, R. (PI) ; El Gamal, A. (PI) ; Emami-Naeini, A. (PI) ; Enge, P. (PI) ; Engler, D. (PI) ; Fan, S. (PI) ; Franklin, G. (PI) ; Fraser-Smith, A. (PI) ; Garcia-Molina, H. (PI) ; Gibbons, F. (PI) ; Gibbons, J. (PI) ; Gill, J. (PI) ; Giovangrandi, L. (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) ; Hashemi, H. (PI) ; Hellman, M. (PI) ; Hennessy, J. (PI) ; Hesselink, L. (PI) ; Horowitz, M. (PI) ; Howe, R. (PI) ; Inan, U. (PI) ; Kahn, J. (PI) ; Kazovsky, L. (PI) ; Khuri-Yakub, B. (PI) ; Kino, G. (PI) ; Kovacs, G. (PI) ; Koza, J. (PI) ; Kozyrakis, C. (PI) ; Lall, S. (PI) ; Lam, M. (PI) ; Lee, T. (PI) ; Leeson, D. (PI) ; Levin, C. (PI) ; Levis, P. (PI) ; Levoy, M. (PI) ; Linscott, I. (PI) ; Long, E. (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) ; Poon, A. (PI) ; Pop, E. (PI) ; Prabhakar, B. (PI) ; Pratt, V. (PI) ; Reis, R. (PI) ; Rosenblum, M. (PI) ; Saraswat, K. (PI) ; Saxena, N. (PI) ; Shahidi, R. (PI) ; Shen, Z. (PI) ; Shenoy, K. (PI) ; Siegel, M. (PI) ; Smith, J. (PI) ; Solgaard, O. (PI) ; Solomon, G. (PI) ; Spielman, D. (PI) ; Stinson, J. (PI) ; Thompson, N. (PI) ; Thrun, S. (PI) ; Tobagi, F. (PI) ; Tomlin, C. (PI) ; Tyler, G. (PI) ; Ullman, J. (PI) ; Van Roy, B. (PI) ; Vishnu, M. (PI) ; Vuckovic, J. (PI) ; Walt, M. (PI) ; Wandell, B. (PI) ; Wang, S. (PI) ; Weissman, T. (PI) ; Wenstrand, J. (PI) ; Widom, J. (PI) ; Widrow, B. (PI) ; Wong, H. (PI) ; Wong, S. (PI) ; Wooley, B. (PI) ; Yamamoto, Y. (PI) ; Zebker, H. (PI)

EE 191: Special Studies and Reports in Electrical Engineering

Independent work under the direction of a faculty member given for a letter grade only. If a letter grade given on the basis of required written report or examination is not appropriate, enroll in 190. Course may be repeated for credit.
Terms: Aut, Win, Spr, Sum | Units: 1-15 | Repeatable for credit
Instructors: Aghajan, H. (PI) ; Allison, D. (PI) ; Apostolopoulos, J. (PI) ; Arbabian, A. (PI) ; Bahai, A. (PI) ; Bambos, N. (PI) ; Boneh, D. (PI) ; Bosi, M. (PI) ; Bowden, A. (PI) ; Boyd, S. (PI) ; Bravman, J. (PI) ; Bube, R. (PI) ; Carpenter, D. (PI) ; Cheriton, D. (PI) ; Cioffi, J. (PI) ; Cover, T. (PI) ; Cox, D. (PI) ; DaRosa, A. (PI) ; Dally, B. (PI) ; Dasher, R. (PI) ; De-Micheli, G. (PI) ; Dill, D. (PI) ; Dutton, R. (PI) ; El Gamal, A. (PI) ; Emami-Naeini, A. (PI) ; Enge, P. (PI) ; Engler, D. (PI) ; Fan, S. (PI) ; Franklin, G. (PI) ; Fraser-Smith, A. (PI) ; Garcia-Molina, H. (PI) ; Gibbons, F. (PI) ; Gibbons, J. (PI) ; Gill, J. (PI) ; Giovangrandi, L. (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) ; Hashemi, H. (PI) ; Hellman, M. (PI) ; Hennessy, J. (PI) ; Hesselink, L. (PI) ; Horowitz, M. (PI) ; Howe, R. (PI) ; Huang, K. (PI) ; Inan, U. (PI) ; Kahn, J. (PI) ; Katti, S. (PI) ; Kazovsky, L. (PI) ; Khuri-Yakub, B. (PI) ; Kino, G. (PI) ; Kovacs, G. (PI) ; Koza, J. (PI) ; Kozyrakis, C. (PI) ; Lall, S. (PI) ; Lam, M. (PI) ; Lauben, D. (PI) ; Lee, T. (PI) ; Leeson, D. (PI) ; Levin, C. (PI) ; Levis, P. (PI) ; Levoy, M. (PI) ; Linscott, I. (PI) ; Long, E. (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) ; Moslehi, M. (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) ; Poon, A. (PI) ; Pop, E. (PI) ; Prabhakar, B. (PI) ; Pratt, V. (PI) ; Reis, R. (PI) ; Rosenblum, M. (PI) ; Saraswat, K. (PI) ; Saxena, N. (PI) ; Shahidi, R. (PI) ; Shen, Z. (PI) ; Shenoy, K. (PI) ; Siegel, M. (PI) ; Smith, J. (PI) ; Solgaard, O. (PI) ; Solomon, G. (PI) ; Spielman, D. (PI) ; Stinson, J. (PI) ; Thompson, N. (PI) ; Thrun, S. (PI) ; Tobagi, F. (PI) ; Tomlin, C. (PI) ; Tyler, G. (PI) ; Ullman, J. (PI) ; Van Roy, B. (PI) ; Vishnu, M. (PI) ; Vuckovic, J. (PI) ; Walt, M. (PI) ; Wandell, B. (PI) ; Wang, S. (PI) ; Weissman, T. (PI) ; Wenstrand, J. (PI) ; Widom, J. (PI) ; Widrow, B. (PI) ; Wong, H. (PI) ; Wong, S. (PI) ; Wooley, B. (PI) ; Yamamoto, Y. (PI) ; Zebker, H. (PI)

EE 191W: Special Studies and Reports in Electrical Engineering (WIM)

WIM-version of EE 191. For EE students using special studiesnn(e.g., honors project, independent research project) to satisfy thennwriting-in-major requirement. A written report that has gone through revision with an advisor is required. An advisor from the Writing Center is recommended.
Terms: Aut, Win, Spr, Sum | Units: 3-10

EE 216: Principles and Models of Semiconductor Devices

Carrier generation, transport, recombination, and storage in semiconductors. Physical principles of operation of the p-n junction, heterojunction, metal semiconductor contact, bipolar junction transistor, MOS capacitor, MOS and junction field-effect transistors, and related optoelectronic devices such as CCDs, solar cells, LEDs, and detectors. First-order device models that reflect physical principles and are useful for integrated-circuit analysis and design. Prerequisite: 116 or equivalent.
Terms: Aut, Win, Sum | Units: 3

EE 261: The Fourier Transform and Its Applications

The Fourier transform as a tool for solving physical problems. Fourier series, the Fourier transform of continuous and discrete signals and its properties. The Dirac delta, distributions, and generalized transforms. Convolutions and correlations and applications; probability distributions, sampling theory, filters, and analysis of linear systems. The discrete Fourier transform and the FFT algorithm. Multidimensional Fourier transform and use in imaging. Further applications to optics, crystallography. Emphasis is on relating the theoretical principles to solving practical engineering and science problems. Prerequisites: Math through ODEs, basic linear algebra, Comfort with sums and discrete signals, Fourier series at the level of 102A
Terms: Aut, Win, Sum | Units: 3

EE 263: Introduction to Linear Dynamical Systems (CME 263)

Applied linear algebra and linear dynamical systems with application to circuits, signal processing, communications, and control systems. Topics: least-squares approximations of over-determined equations and least-norm solutions of underdetermined equations. Symmetric matrices, matrix norm, and singular value decomposition. Eigenvalues, left and right eigenvectors, with dynamical interpretation. Matrix exponential, stability, and asymptotic behavior. Multi-input/multi-output systems, impulse and step matrices; convolution and transfer matrix descriptions. Control, reachability, and state transfer; observability and least-squares state estimation. Prerequisites: linear algebra and matrices as in MATH 103; differential equations and Laplace transforms as in EE 102A.
Terms: Aut, Sum | Units: 3

EE 264: Digital Signal Processing

The fundamentals of digital signal processing techniques and their applications. Topics include review of two sided Z-transform, linear time invariant discrete-time systems, and sampling theory; A/D and D/A conversion, rate conversion, and oversampling techniques for ADC and DAC; filter design; quantization in digital filter implementation; discrete Fourier analysis; and parametric signal modeling. Prerequisite: EE102A and EE102B . Recommended: EE261, EE278B.
Terms: Aut, Spr, Sum | Units: 3

EE 278B: Introduction to Statistical Signal Processing

Review of basic probability and random variables. Random vectors and processes; convergence and limit theorems; IID, independent increment, Markov, and Gaussian random processes; stationary random processes; autocorrelation and power spectral density; mean square error estimation, detection, and linear estimation. Prerequisites: EE178/278A and linear systems and Fourier transforms at the level of EE102A,B or EE261.
Terms: Aut, Win, Sum | Units: 3
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