The Department of Electrical
and Computer Engineering

Graduate Studies in Electrical and Computer Engineering
Doctoral Programs
Master of Science Programs
CONCENTRATION AREA
CONCENTRATION AREAS IN ELECTRICAL ENGINEERING
CONCENTRATION AREAS IN COMPUTER SYSTEMS ENGINEERING
CONCENTRATION AREAS IN PHOTONICS
Admission Requirements
Research Interests of the Faculty

Department Chairman Bahaa Saleh

Associate Chairman for Graduate Studies Thomas D. C. Little

Department Director Wayne Rennie

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Graduate Studies in Electrical and Computer Engineering

Graduate Programs within the Department of Electrical and Computer Engineering develop students’ understanding of the scientific and mathematical basis of critical technologies and prepare them for the application of sophisticated analysis and design methods to solve a broad range of problems. With more than 43 full-time and 14 affiliated faculty members and state-of-the-art facilities, the ECE department offers a solid course curriculum and a rich selection of research opportunities. Our MS and PhD graduates enjoy successful careers in industry and academia often working at the forefront of the technology as well as interdisciplinary fields.

Research activities in the ECE department are broadly classified into three main areas: (i) Electro-Physics, (ii) Information Systems and Sciences, and (iii) Computer Systems Engineering. Each area has distinct, faculty-centered groups. The boundaries between these groups are not sharp, and interaction and cross-fertilization are encouraged and common. Graduate students have the opportunity to conduct research in any of these groups under the guidance of ECE faculty, through access to University wide centers and cross-disciplinary collaborations. The description of laboratories are located in the “Specialized Facilities for Instruction and Research” section of this bulletin. Research in ECE has a strong funding base from governmental agencies, foundations, and corporate sponsors. More information is available at Electrical & Computer Engineering.

Study in solid-state materials and devices addresses the modeling of new electrical, optical, or magnetic structures, the fabrication of such devices, and detailed characterization of their properties and performance. Ongoing projects consider MBE of blue sources, high-speed and RF electronics, ultra-fast optical detectors, and arrays of micromagnetic structures.

In Photonics, which includes the MS in Photonics program, groups are looking at a range of topics, including biophotonics for detection, diagnosis and therapy, femto-second and nano-meter optical characterizations, quantum and high-speed optics, optical cryptography, fabrication of sources and detectors, and fiber sensors and systems. Wireless optical communications and opto-electronic devices overlap with ISS and solid-state efforts.

The electromagnetics area has groups working on theoretical models of wave phenomena, methods for computational electromagnetics, applied electrostatics, atmospheric plasmas and space weather, space instrumentation, and micromagnetic sensors and storage modeling.

The space science and technology area has groups working on radar remote sensing of the ionosphere and atmosphere; ionospheric theory, modeling, and simulation; space instrumentation; optical remote sensing of planetary atmospheres; and related topics.

The field of Signal and Image Processing encompasses the development and implementation of algorithms and methods to analyze and extract information from signals obtained from observing natural and human-generated phenomena, including biological and biomedical signals.

Research in the area of Multimedia Processing concentrates on issues related to the modeling of multimedia signals (still images, image sequences, video, music, speech, etc.) as well as their processing in order to facilitate information extraction, compression and transmission in computer networks. The area of Information and Decision Systems spans a variety of topics, including robust signal processing that deals with developing statistical modeling and processing techniques for limited informational contexts (cases where “data/information available is insufficient relative to the complexity of the process or system”), distributed and networked signal processing to deal with noisy distributed information from multiple sources that must be fused under communication constraints, as well as control and decision theory.

Research in the area of Communications and Networking concentrates around several topics, including digital communications theory and applications, wireless infrared and broadband communications, sensor networks, wireless networks, multiuser scheduling, multi-antenna systems, scalability, heterogeneity, and performance of networks.

Research in communication and computer networking involves fundamental principles and applications of point-to-point communications and communication networking. Broad areas of interest are information theory; error correcting codes; analysis, design, and control of networks; and wireless communication systems and networking theory. Specific research projects include: data synchronization especially for PDAs and mobile networks, Internet traffic engineering, sensor-based location detection, scaling mobile ad hoc networks, wireless infrared communications, fault-tolerant routing, design of reliable networks, embedded sensor network application development, switch design, and ecological applications.

Research in computer engineering involves design, evaluation, and tools for computers, computer-based systems, and computer-based-system applications. Classical areas of computer engineering are computer architecture, electronic design automation, embedded systems and applications, and design and test of computers and computer systems. Specific research projects include: quantum computing, design automation of asynchronous circuits, FPGA-based computation, fine-grained modeling of physics-like systems, VLSI design using analog and digital techniques in CMOS, fault-tolerant computing and circuits, and secure cryptographic devices.

Research in software engineering and applications involves methodologies, tools and techniques used to construct, deploy, support, and evolve software. Issues considered by faculty include quality, performance, development time, and target environment. Specific projects include: embedded software application development, environments for developing high-performance applications, implementation and testing of distributed software systems, and personal knowledge engineering.

Doctoral Programs

Programs of study leading to the PhD in electrical engineering, computer engineering, and systems engineering are available. Completion of the PhD establishes a student’s ability to conduct independent basic or applied research, and prepares him or her for a career in academia, industry, or government. Students pursue theoretical and empirical studies in a topic area determined by their interests, faculty research areas, and departmental research facilities. External collaborations with industry and government laboratories are encouraged. Information regarding admissions, degree requirements, and financial aid may be found in the Graduate Programs section of this site.

Doctoral program candidates should contact faculty members in the department to discuss their research plans (for contact information, send e-mail to ecegrad@bu.edu or see Electrical & Computer Engineering.Students admitted to the PhD program must first complete the department’s MS degree requirements.

Electrical Engineering and Computer Engineering In addition to fulfilling the MS degree program requirements, all PhD students must enroll for an additional 32 units (8 courses) at the graduate level (500 level or above). Post-master’s PhD students are required to complete 32 graduate units (8 courses) beyond their MS work. In addition to an oral prospectus defense and final dissertation defense, students must pass two written comprehensive examinations covering basic knowledge in (a) applied mathematics and (b) electrical and computer engineering. The College of Engineering Graduate Committee administers the applied mathematics examination, while the electrical and computer engineering qualifying exam is administered by the ECE Graduate Committee.

Systems Engineering The PhD in systems engineering is for those wishing to do advanced work in such cross-disciplinary areas as control systems, robotics, information processing and systems, energy systems, transportation systems, or intelligent systems. Graduates of any engineering discipline may apply to the program. All ECE students in the Systems Engineering postbachelor’s PhD program must fulfill the MS degree requirements (32 credits) in one of the ECE MS degree programs and an additional 32 credits at the graduate level (500 level or above). ECE students in the Systems Engineering post-master’s PhD program are required to complete a total of 32 credits at the graduate level (500 level or above). As with other PhD programs, students are also required to pass the mathematics exam, as well as the qualifying examination administered by the ECE Graduate Committee in coordination with the interdepartmental PhD Systems Engineering Committee. For further information, contact Professor D. Castañon, Department of Electrical and Computer Engineering, and consult the Systems Engineering website at Systems Engineering.

Master of Science Programs

Programs of study leading to the MS in electrical engineering, computer systems engineering, or photonics may be pursued. The degree programs have a common structure that includes requirements for concentration, breadth, advanced coursework, and a thesis or project. The degrees are differentiated by the concentration area chosen (see below). There is a great deal of flexibility in the program, and each student is expected to work with his or her faculty advisor to design a specific program of study that meets his or her professional needs.

The study program must satisfy both the general graduate requirements of the College of Engineering as well as additional requirements of the Department of Electrical and Computer Engineering. A 3.0 (B) average must be maintained to graduate and grades of C– or lower are unacceptable for credit. All programs in the department require 32 credit hours of study. Up to 8 credits may be transferred from other approved graduate schools.

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CONCENTRATION AREA

Each student must take at least 16 units (four courses) in one of the ten ECE concentration areas listed below. Up to 8 units of 900-level EC courses (thesis, project, research or directed study) may be used to satisfy the concentration area requirement. The three degree programs are distinguished by the concentration area chosen as indicated below.

CONCENTRATION AREAS IN ELECTRICAL ENGINEERING

ENG EC 505 Stochastic Processes
ENG EC 515 Digital Communication
ENG EC 516 Digital Signal Processing
ENG EC 517 Introduction to Information Theory
ENG EC 520 Digital Image Processing and Communication
ENG EC 702 Recursive Estimation and Optimal Filtering
ENG EC 715 Wireless Communications
ENG EC 716 Advanced Digital Signal Processing
ENG EC 717 Image Reconstruction and Restoration
ENG EC 719 Statistical Pattern Recognition
ENG EC 720 Digital Video Processing

ENG EC 501/AM 501 State Space Control
ENG EC 505 Stochastic Processes
ENG EC 517 Introduction to Information Theory
ENG EC 524/MN 524 Optimization Theory and Methods
ENG EC 701/AM 764 Optimal and Robust Control
ENG EC 702 Recursive Estimation and Optimal Filtering
ENG EC 710/MN 710 Dynamic Programming and Stochastic Control
ENG EC 724/MN 724 Advanced Optimization Theory and Methods
ENG AM 740 Vision, Robotics, and Planning
ENG MN 755 Communication Networks Control
ENG AM 762 Non-linear Control of Mechanical Systems

ENG EC 571 VLSI Principles and Applications
ENG EC 574 Solid State Devices
ENG EC 575 Semiconductor Devices
ENG EC 578 Fabrication Technology for Integrated Circuits
ENG EC 579/MN 579 Microelectronic Device Manufacturing
ENG EC 580 Modern Active Circuit Design
ENG EC 582 RF/Analog IC Design Fundamentals
ENG EC 770 Guided-wave Optoelectronics
ENG EC 771 Physics of Compound Semiconductor Devices
ENG EC 772 VLSI Graduate Design Project
ENG EC 774 Semiconductor Quantum Structures and Photonic Devices
ENG EC 775 VLSI Devices and Device Models

ENG EC 560 Introduction to Photonics
ENG EC 563 Fiber Optic Communication Systems
ENG EC 566 The Atmosphere and Space Environment
ENG EC 567/MN 567 Electromagnetic Wave Computation
ENG EC 568 Optical Fiber Sensors
ENG EC 569 Introduction to Subsurface Imaging
ENG EC 570 Lasers
ENG EC 591 Photonics Laboratory I
ENG EC 707 Radar Remote Sensing
ENG EC 731 Applied Plasma Physics
ENG EC 760 Advanced Topics in Photonics
ENG EC 762 Quantum Optics
ENG EC 763 Nonlinear and Ultrafast Optics
ENG EC 764 Optical Measurement
ENG EC 765/BE 765 Biomedical Optics and Biophotonics
ENG EC 770 Guided-wave Optoelectronics

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CONCENTRATION AREAS IN COMPUTER SYSTEMS ENGINEERING

ENG EC 513 Computer Architecture
ENG EC 535 Introduction to Embedded Systems
ENG EC 551 Advanced Digital Design with Verilog and FPGA
ENG EC 561 Error-Control Codes
ENG EC 571 VLSI Principles and Applications
ENG EC 580 Modern Active Circuit Design
ENG EC 582 RF/Analog IC Design Fundamentals
ENG EC 713 Parallel Computer Architecture
ENG EC 749 Interconnection Networks for Multicomputers
ENG EC 751 Design of Asynchronous Circuit and Systems
ENG EC 752 Theory of Computer Hardware Testing
ENG EC 753 Fault-Tolerant Computing
ENG EC 757 Advanced Microprocessor Design
ENG EC 772 VLSI Graduate Design Project

ENG EC 505 Stochastic Processes
ENG EC 515 Digital Communication
ENG EC 524/MN 524 Optimization Theory and Methods
ENG EC 534 Discrete Stochastic Models
ENG EC 541 Computer Communication Networks
ENG EC 544 Networking the Physical World
ENG EC 561 Error-Control Codes
ENG EC 715 Wireless Communications
ENG EC 724/MN 724 Advanced Optimization Theory and Methods
ENG EC 725 Queuing Systems
ENG EC 727 Advanced Coding Theory
ENG EC 733 Discrete Event and Hybrid Systems
ENG EC 744 Mobile Ad Hoc Networking and Computing
ENG EC 749 Interconnection Networks for Multicomputers
ENG EC 761 Information Theory and Coding

ENG EC 504 Advanced Data Structures
ENG EC 511 Software Systems Design
ENG EC 512 Enterprise Client-Server Software Systems
Design
ENG EC 518 Software Project Management
ENG EC 535
Introduction to Embedded Systems
ENG EC 544 Networking the Physical World
ENG EC 712 Advanced Software for Computer Engineers
ENG EC 726 Personal Knowledge Engineering
ENG EC 730 Information-Theoretical Design of Algorithms

CONCENTRATION AREAS IN PHOTONICS

ENG EC 560 Introduction to Photonics
ENG EC 569 Introduction to Subsurface Imaging
ENG EC 570 Lasers
ENG EC 591 Photonics Laboratory I
ENG EC 760 Advanced Topics in Photonics
ENG EC 762 Quantum Optics
ENG EC 763 Nonlinear and Ultrafast Optics
ENG EC 764 Optical Measurement
ENG EC 765/BE 765 Biomedical Optics and Biophotonics

ENG EC 560 Introduction to Photonics
ENG EC 563 Fiber Optic Communication Systems
ENG EC 568 Optical Fiber Sensors
ENG EC 591 Photonics Laboratory I
ENG EC 760 Advanced Topics in Photonics
ENG EC 770 Guided-wave Optoelectronics

ENG EC 560 Introduction to Photonics
ENG EC 575 Semiconductor Devices
ENG EC 574 Solid State Devices
ENG EC 577 Solid State Devices
ENG EC 591 Photonics Laboratory I
ENG EC 760 Advanced Topics in Photonics
ENG EC 771 Physics of Compound Semiconductor Devices
ENG EC 774 Semiconductor Quantum Structures and Photonic Devices

Breadth Requirement Students must take 8 credits from other concentration area(s). A course listed under multiple concentrations may be used as either a concentration or a breadth course, but not both. ENG EC 560 may not be taken for breadth requirement by Photonics majors.

Advanced Technical Electives Students must take 8 credits of EC 700-level coursework. These may also count as concentration or breadth requirements. The 700-level project-oriented courses may not be counted as Advanced Technical Electives.

Thesis or Project Requirement Students must take 4 credits of Thesis (EC 901) or Project (EC 910, EC 911, EC 912, EC 913, EC 914, EC 915) or an approved project-oriented course (EC 566, EC 712, EC 757, EC 772). This may also count as a concentration requirement but may not count as an advanced technical elective. Passing the PhD prospectus defense will be considered to be the equivalent of completing a project course for post-BS PhD students.

Thesis Students wishing to undertake a research project must be supervised by a member of the department or by someone acceptable to the Associate Chairman for Graduate Studies. The suitability of the research is determined primarily by the student’s thesis advisor, based on informal discussions and a brief written thesis proposal. Thesis proposal guidelines are available and should be consulted. Registration for ENG EC 901 Thesis cannot begin until an acceptable proposal has been submitted. Thesis students register for ENG EC 901 each semester they work on their project, and may apply up to 8 credits of EC 901 registration toward the 32 credits required for the degree.

When a graduate student nears completion of his or her MS research, an oral defense of the work must be scheduled. Deadlines are listed at the beginning of this bulletin. The thesis advisor and readers are responsible for establishing the format of the public defense.

The results of the student’s research must be communicated to the scientific and engineering communities as a formal thesis. Editorial guidance can be found in A Guide for the Writers of Dissertations and Theses, available in the departmental office or in the College Graduate Programs Office. The student must submit the thesis to Mugar Memorial Library and provide a copy to the advisor, to each reader, and a bound copy to the ECE Department.

It is also possible to satisfy the project requirement by taking one of the desig- nated project oriented courses (EC 566, EC 712, EC 757, or EC 772) that include a substantial project as an integral part of the course material.

Graduate Technical Electives The remainder of the course requirements may be met through graduate technical electives, which include all courses at the 500 level or above in ENG, as well as courses in the following CAS departments: astronomy, biology, chemistry, cognitive and neural systems, computer science, mathematics, and physics, except courses for nonmajors (e.g., CAS PY 633 Energy). CAS courses require advisor approval and a petition. Certain teaching seminars (e.g., EC 850) and preparatory courses (e.g., MN 566) are not allowed.

Academic Standards All graduate courses will be counted in the cumulative GPA, which must be at least 3.0 for good academic standing and graduation. Only grades of C or above receive graduate credit and fulfill MS curricular requirements.

Approval All individual programs must be reviewed and approved by the academic advisor and the Department of Electrical and Computer Engineering. Approval must be completed before registration for the second semester of study.

Exceptions Individuals who have outstanding records of professional achievement or academic accomplishment at an advanced level may be exempted, by petition, from some of the MS program distribution requirements listed above, thereby facilitating the planning of a more advanced program. Such a proposal should be accompanied by a clear statement of objectives and a description of how the program will achieve the proposed objectives. In general, a more advanced course in an area may be substituted for a required course in satisfying the degree requirements.

Admission Requirements

Students entering the graduate programs in the Department of Electrical and Computer Engineering are expected to have completed a Bachelor of Science degree in Electrical or Computer Engineering. Prospective applicants from other fields such as other engineering disciplines, computer science, mathematics, or physics may be accepted with possible additional requirements for the completion of background courses. Such applicants will be judged individually according to their backgrounds and professional objectives. Required background work should be taken at the start of a student’s program.

Applications for admission may be obtained from the College of Engineering Graduate Programs Office, 48 Cummington Street, Boston, MA 02215; Tel: 617-353-9760; e-mail: enggrad@bu.edu; or College of Engineering Graduate Programs. An electronic application is available at College of Engineering Admissions Application.

Research Interests of the Faculty

Murat Alanyali, PhD: communication networks; performance analysis and optimization; stochastic systems.

Hatice Altug, PhD: nanophotonics, photonic crystals.

John Baillieul, PhD: robotics; control of mechanical systems; mathematic system theory.

Enrico Bellotti, PhD: computational electronics; semiconductor materials and device simulations; power electronics; parallel computing.

Irving Bigio, PhD: medical application of optics, lasers, and spectroscopy; biophotonics; nonlinear optics; applied spectroscopy; laser physics.

Richard Brower, PhD: molecular dynamics simulation for biomolecules; lattices methods for QCD and statistical mechanics; quantum field theory of strings and particles.

Robert Brown, PhD: mathematical modeling of the fluid mechanics, heat and mass transfer and interfacial phenomena associated with materials processing, especially melt crystal growth, polymer processing and coating deposition; fluid mechanics of viscoelastic fluids; analysis and numerical simulation of flow instabilities; prediction and characterization of microscopic changes in interface morphology during directional solidification; experimental measurement of microscale morphologies in melt/solid interfaces during solidification; efficient numerical solutions of transport problems, especially by finite element methods; modeling the dynamics of defects in crystalline semiconductors grown from the melt and in semiconductor processing.

Maja E. Bystrom, PhD: source and channel coding; multimedia communications; image processing.

David K. Campbell, PhD: general nonlinear phenomena and complex systems; novel electronic materials, including conducting polymers and organic and high tc superconductors; electron transport in semiconductor superlattices.

Jeffrey B. Carruthers, PhD: photonic wireless communication; mobile and wireless networks; engineering education.

Christos G. Cassandras, PhD: analysis and control of discrete event dynamic systems; stochastic control and optimization; dynamic control of computer and communication networks.

David Castanon, PhD: stochastic control; estimation optimization; image understanding and parallel computation.

Supriya Chakrabarti, PhD: space experimentation; ultraviolet spectroscopy.

Luca Dal Negro, PhD: optical amplification phenomena and laser physics; optical spectroscopy of semiconductor nanostructures; photonic crystals, Anderson light localization and aperiodic dielectrics; nanophotonics and plasmonics.

Solomon Eisenberg, ScD: electrically mediated phenomena in tissues and biopolymers.

Farouk El-Baz, PhD: remote sensing with an emphasis on arid lands, particularly in the location of groundwater resources.

Azza Fahim, PhD: electric machines; computations in electromagnetics.

Theodore Fritz, PhD: space plasma and magnetospheric physics; magneto sphere-ionsphere coupling; substorms; charged particles and compositions; rocket and satellite experiments.

Roscoe Giles, PhD: advanced computer architectures; distributed and parallel computing; computational science.

Bennett Goldberg, PhD: room- and low-temperature, near-field microscopy of semiconductors and biological systems; magneto-optics and magnet-transport of two- and one-dimensional electron fields.

Martin Herbordt, PhD: computer architecture; electronic design automation; communication switch design; computer vision architecture; bioinformatics.

Mark Horenstein, PhD: applied electromagnetics; electrostatics; microelectromechanical systems (MEMS).

Allyn Hubbard, PhD: VLSI design using analog and digital techniques in CMOS ; neural net chips, smart sensor chips, and chips with biological applications; models of the peripheral auditory system.

Prakash Ishwar, PhD: distributed signal processing; information theory; statistical signal processing and modeling; image and video coding; decision theory; multiresolution signal analysis, and optimization theory with applications to sensor networks; multimedia-over-wireless; information security.

W. Clement Karl, PhD: multidimensional and multiscale signal and image processing and estimation, particularly applied to geometrically and medically oriented problems.

Mark Karpovsky, PhD: design of secure cryptographic devices and smart cards; routing in interconnection networks design and protection of cryptographic devices; fault-tolerant computing; error correcting codes; testing and diagnosis of computer hardware.

William Klein, PhD: theoretical condensed-matter physics; polymer physics, and statistical mechanics.

Ronald W. Knepper, PhD: VLSI integrated circuit technology; SiGe BICMOS device and circuit modeling; silicon CMOS and bipolar devices; numerical device simulation; RF/analog IC design.

Janusz Konrad, PhD: multimedia communications; image and video processing; stereoscopic and 3-D imaging; digital signal processing.

Robert Kotiuga, PhD: electromagnetics; numerical methods for three-dimensional vector field problems; Whitney forms and the Finite Element Method; micromagnetics; nanoscale magnetics; geometric inverse problems; topological aspects of magnetic scalar potentials; Helicity Functionals; analysis of high-performance interconnects.

Min-Chang Lee, PhD: radio communications; experimental plasma physics; ionospheric plasma physics.

Lev Levitin, PhD: information theory; physics of communication and computing; complex and organized systems; quantum theory of measurement; reliable communication and computing; and bioinformatics.

Thomas Little, PhD: Mobile Ad Hoc Networks (MANETs); multimedia computing; computer networking; software engineering; embedded sensor networks.

Fei Luo, PhD: optical fiber devices; optical fiber sensors and systems; fiber laser and amplifier.

Michael Mendillo, PhD: signal processing in space physics; GPS satellite communications; space plasmas in the solar system; low-light level optical instrumentation; planetary atmospheres.

Jerome Mertz, PhD: development and applications of novel optical microscopy techniques for biological imaging.

Theodore Morse, PhD: photonic material processing; optical fiber fabrication, lasers, and sensors; high power double clad fiber lasers.

Theodore Moustakas, PhD: growth by MBE, MOCVD, HVPE and gas-cluster ion beam deposition (GCIB); growth, fabrication and characterization of optical devices (UV-LEDs, UV-LDs, optical modulators, detectors), electronic devices (high power diodes, transistors and thyristors) and electromechanical devices (SiC/III-Nitride MEMS sensors); III-nitride semiconductors (materials growth and device fabrication).

Syed Hamid Nawab, PhD: computational signal processing; applied artificial intelligence; analysis algorithms for EMG signals; analysis algorithms for patient activity signals; analysis algorithms for auditory signals.

Peter O’Connor, PhD: mass spectrometry instrumentation and applications.

William Oliver, PhD: global change in the upper atmosphere; radar studies of the upper atmosphere and ionosphere; modeling and simulation.

Roberto Paiella, PhD: optical technologies for information processing; photonic devices based on semiconductor quantum structures, including group-III nitride quantum wells; nanoscale photonic devices and circuits; ultrafast optics.

Ioannis Paschalidis, PhD: design, performance analysis and control of communication and sensor networks; design, stability, performance analysis and control of manufacturing systems, supply chains, and distribution systems; computational biology; queuing theory and stochastic systems; optimization and dynamic programming; pricing and revenue management; large deviations theory.

Wei Qin, PhD: design tools and methods for embedded systems and embedded processors; design languages for electronic systems.

Tatyana Roziner, PhD: digital design; testing and diagnostics of computer hardware; fault-tolerant computing.

Michael F. Ruane, PhD: resonant cavity imaging systems; K–12 and engineering education; optical systems; AFRL Loss Cone Imager DSK satellite.

Bahaa E. A. Saleh, PhD: quantum optics; nonlinear optics; image processing.

Venkatesh Saligrama, PhD: information and control theory; statistical signal processing; applications to sensor networks.

Eric Schwartz, PhD: computational neural science; machine vision; neural anatomy; neural modeling.

Joshua Semeter, PhD: ionospheric and space plasma physics; spectroscopy of atmospheric airglow and the aurora borealis; image processing; radar systems and radar signal processing.

Alexander Sergienko, PhD: correlation spectroscopy, field optical microscopy and spectroscopy of semiconductor materials and devices; quantum communications; remote laser sensing; laser physics; nonlinear optics; quantum optics, including quantum radiometry and metrology.

Masoud Sharif, PhD: wireless multiuser networks; communications and information theory.

Thomas Skinner, PhD: microprocessors; computer networks; operating systems; distributed systems.

William J. Skocpol, PhD: nanofabrication; device processing; transport experiments in materials.

David Starobinski, PhD: wireless and sensor networks; QOS and traffic engineering; networks performance evaluation.

Anna Swan, PhD: interactions of bio-material with nanostructures (mucin-nanotubes); optical properties of low-dimensional systems (carbon nanotubes and graphene); biological imaging and detection using interference techniques (4Pi microscopy and spectral fluorescence microscopy).

Alexander Taubin, PhD: asynchronous circuit, logic design; computer architecture; CAD; attack-resistant hardware.

Malvin C. Teich, PhD: quantum optics and imaging; photonics; fractal stochastic processes; information transmission in biological sensory systems.

Tommaso Toffoli, PhD: fundamental connections between physics and computation; fine-grained modeling of physics-like systems technology (cellular automata machines) and methodology (programmable matter); personal knowledge structuring.

Ari Trachtenberg, PhD: error correcting codes; data synchronization (especially for PDAs and mobile networks); sensor-based location detection; algorithms.

M. Selim Ünlü, PhD: near-field optical microscopy and spectroscopy of semiconductor materials and devices; design, processing, characterization, and simulation of semiconductor optoelectronic devices; nanoscale imaging of biological samples, biosensors.

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10 September 2007
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