| source Yale (X) |
level |
department Engineering (X) |
TTh 2.30-3.45 Fall 2009 Final exam scheduled (Group 27) 12/17/2009 Th 2.00 Skills QR Areas Sc The basic concepts and techniques of quantum mechanics essential for solid-state physics and quantum electronics. Topics include the Schrödinger treatment of the harmonic oscillator, atoms and molecules and tunneling, matrix methods, and perturbation theory.
Score: 10.140942 Details | Listing | Web page
TTh 1.00-2.15 Fall 2009 Final exam scheduled (Group 26) 12/15/2009 T 2.00 Skills QR Areas Sc The first term of a two-term sequence covering the principles underlying the electrical, thermal, magnetic, and optical properties of solids, including crystal structure, phonons, energy bands, semiconductors, Fermi surfaces, magnetic resonances, phase transitions, dielectrics, magnetic materials, and superconductors.
Score: 10.140942 Details | Listing | Web page
TTh 11.35-12.50 Fall 2009 Final exam scheduled (Group 24) 12/15/2009 T 9.00 Skills QR Areas Sc Introduction to the principles of optics and electromagnetic wave phenomena with applications to microscopy, optical fibers, laser spectroscopy, and nanostructure physics. Topics include propagation of light, reflection and refraction, guiding light, polarization, interference, diffraction, scattering, Fourier optics, and optical coherence.
Score: 10.140942 Details | Listing | Web page
1 HTBA Fall 2009 No regular final examination Permission of instructor required Faculty-supervised individual or small-group projects with emphasis on research (laboratory or theory). Students are expected to consult the director of undergraduate studies and appropriate faculty members to discuss ideas and suggestions for suitable topics. These courses may be taken at any appropriate time in the student?s career; they may be taken more than once.
Score: 10.140942 Details | Listing | Web page
MWF 9.25-10.15 Fall 2009 Final exam scheduled (Group 32) 12/12/2009 S 9.00 Areas Sc Regulation and control in biological systems, emphasizing human physiology and principles of feedback. Biomechanical properties of tissues emphasizing the structural basis of physiological control. Conversion of chemical energy into work in light of metabolic control and temperature regulation.
Score: 10.140942 Details | Listing | Web page
TTh 11.35-12.50 Fall 2009 Final exam scheduled (Group 24) 12/15/2009 T 9.00 Skills QR Areas Sc Together with the companion course BENG 352b, a yearlong presentation of the fundamentals of biomedical engineering. Demonstration of the use of engineering analysis and synthesis in problems in the life sciences and medicine; focus on modeling of molecular physiological processes and design of artificial organs. Lectures are coordinated with BENG 350a to illustrate how engineering analysis can be used to understand physiological processes. Additional topics include pharmacokinetics, heat and mass transfer in physiological systems, hemodialysis, drug delivery, and tissue engineering.
Score: 10.140942 Details | Listing | Web page
MT 1.00-5.00 Fall 2009 No regular final examination Areas Sc Introduction to laboratory techniques and tools used for physiological measurement in biomedical engineering. Topics include bioelectric measurement, bioimaging technologies, signal processing, and dialysis.
Score: 10.140942 Details | Listing | Web page
TTh 1.00-2.15 Fall 2009 Final exam scheduled (Group 26) 12/15/2009 T 2.00 Skills QR Areas Sc Permission of instructor required Basic principles and technologies for sensing the chemical, electrical, and structural properties of living tissues and of biological macromolecules. Topics include magnetic resonance spectroscopy, microelectrodes, fluorescent probes, chip-based biosensors, X-ray and electron tomography, and MRI.
Score: 10.140942 Details | Listing | Web page
TTh 9.00-10.15 Fall 2009 Final exam scheduled (Group 22) 12/12/2009 S 2.00 Areas Sc Introduction to the major classes of biomedical materials: ceramics, metals, and polymers. Their structure, properties, and fabrication connected to biological applications, from implants to tissue-engineered devices and drug delivery systems.
Score: 10.140942 Details | Listing | Web page
1 HTBA Fall 2009 No regular final examination Permission of instructor required Faculty-supervised individual or small-group projects with emphasis on research (laboratory or theory), engineering design, or tutorial study. Students are expected to consult the director of undergraduate studies and appropriate faculty members about ideas and suggestions for suitable topics. This course is usually taken during the spring term of the senior year but with permission of the director of undergraduate studies can be taken any time during a student?s career, and may be taken more than once.
Score: 10.140942 Details | Listing | Web page
W 1.00-3.00 Fall 2009 No regular final examination Permission of instructor required Oral presentations and written reports by students analyzing papers from scientific journals on topics of interest in biomedical engineering, including discussions and advanced seminars from faculty on selected subjects.
Score: 10.140942 Details | Listing | Web page
TTh 4.00-5.15 Fall 2009 Final exam scheduled (Group 27) 12/17/2009 Th 2.00 Skills QR Areas Sc Permission of instructor required
Score: 10.140942 Details | Listing | Web page
TTh 11.35-12.50 Fall 2009 Final exam scheduled (Group 24) 12/15/2009 T 9.00 Skills QR Introduction to the basic principles of analog and digital electronics. Analysis, design, and synthesis of electronic circuits and systems. Topics include current and voltage laws that govern electronic circuit behavior, node and loop methods for solving circuit problems, DC and AC circuit elements, frequency response, nonlinear circuits, semiconductor devices, and small-signal amplifiers. A lab session approximately every other week.
Score: 10.140942 Details | Listing | Web page
MW 2.30-3.45 Fall 2009 Final exam scheduled (Group 37) 12/18/2009 F 2.00 Skills QR Introduction to systems that sense, process, control, and communicate. Techniques that analyze system performance are applied to first- and second-order systems that operate on continuous-time waveforms and numerical data. Applications include robotics, digital image processing, and voice recognition systems. MATLAB programming and laboratory experiments illustrate concepts.
Score: 10.140942 Details | Listing | Web page
1 HTBA Fall 2009 No regular final examination Permission of instructor required Faculty-supervised individual or small-group projects with emphasis on laboratory experience, engineering design, or tutorial study. Students are expected to consult the director of undergraduate studies and appropriate faculty members about ideas and suggestions for suitable topics during the term preceding enrollment, so as to arrive at the necessary prospectus. These courses may be taken at any time during the student?s career. Enrollment requires permission of both the instructor and the director of undergraduate studies, and submission to the latter of a one- to two-page prospectus signed by the instructor. The prospectus is due in the departmental office one day prior to the date that the student's course schedule is due.
Score: 10.140942 Details | Listing | Web page
3 HTBA Fall 2009 Permission of instructor required Faculty-supervised individual or small-group projects with emphasis on laboratory experience, engineering design, or tutorial study. Students are expected to consult the director of undergraduate studies and appropriate faculty members about ideas and suggestions for suitable topics during the term preceding enrollment, so as to arrive at the necessary prospectus. These courses may be taken at any time during the student?s career. Enrollment requires permission of both the instructor and the director of undergraduate studies, and submission to the latter of a one- to two-page prospectus signed by the instructor. The prospectus is due in the departmental office one day prior to the date that the student's course schedule is due.
Score: 10.140942 Details | Listing | Web page
TTh 1.00-2.15 Fall 2009 Final exam scheduled (Group 26) 12/15/2009 T 2.00 Skills QR Areas Sc Permission of instructor required An introduction to the physics of semiconductors and semiconductor devices. Topics include crystal structure; energy bands in solids; charge carriers with their statistics and dynamics; junctions, p-n diodes, and LEDs; bipolar and field-effect transistors; and device fabrication.
Score: 10.140942 Details | Listing | Web page
TTh 2.30-3.45 Fall 2009 Final exam scheduled (Group 27) 12/17/2009 Th 2.00 Skills QR Development of engineering skills through the design and analysis of digital logic components and circuits. Introduction to gate-level circuit design, beginning with single gates and building up to complex systems. Hands-on experience with circuit design using computer-aided design tools and microcontroller programming.
Score: 10.140942 Details | Listing | Web page
Fall 2009 No regular final examination Permission of instructor required Cross-disciplinary laboratory experiments covering microfabrication, silicon micromachining, MEMS device fabrication and characterization, scanned probe microscopy, electron microscopy, microfluidics, and lab-on-a-chip systems. Students fabricate MEMS, bio-MEMS, and microfluidic devices in a cleanroom environment.
Score: 10.140942 Details | Listing | Web page
MW 11.35-12.50 Fall 2009 Final exam scheduled (Group 34) 12/17/2009 Th 9.00 Skills QR Areas Sc Survey and review of fundamental issues associated with modern microelectronic and optoelectronic materials. Topics include band theory, electronic transport, surface kinetics, diffusion, materials defects, elasticity in thin films, epitaxy, and Si integrated circuits.
Score: 10.140942 Details | Listing | Web page
MW 1.00-2.15 Fall 2009 Final exam scheduled (Group 36) 12/14/2009 M 2.00 Skills QR Areas Sc A survey of the enabling components and devices that constitute modern optical communications systems. Focus on the physics and principles of each functional unit, its current technological status, important design issues relevant to the overall performance, and future directions.
Score: 10.140942 Details | Listing | Web page
Th 1.30-3.20 Fall 2009 Final exam scheduled (Group 26) 12/15/2009 T 2.00 Skills QR Permission of instructor required Chip design; integrated devices, circuits, and digital subsystems needed for design and implementation of silicon logic chips. CMOS fabrication overview, complementary logic circuits, design methodology, computer-aided design techniques, timing, and area estimation. Exploration of recent and future chip technologies. A course project is the design, through layout, of a digital CMOS subsystem chip; selected projects are fabricated for students.
Score: 10.140942 Details | Listing | Web page
MW 2.30-3.45 Fall 2009 Final exam scheduled (Group 37) 12/18/2009 F 2.00 Skills QR Permission of instructor required Fundamental theory and algorithms of optimization, emphasizing convex optimization. The geometry of convex sets, basic convex analysis, the principle of optimality, duality. Numerical algorithms: steepest descent, Newton's method, interior point methods, dynamic programming, unimodal search. Applications from engineering and the sciences.
Score: 10.140942 Details | Listing | Web page
MW 1.00-2.15 Fall 2009 Final exam scheduled (Group 36) 12/14/2009 M 2.00 Skills QR Permission of instructor required Introduction to finite-dimensional, continuous, and discrete-time linear dynamical systems. Exploration of the basic properties and mathematical structure of the linear systems used for modeling dynamical processes in robotics, signal and image processing, economics, statistics, environmental and biomedical engineering, and control theory.
Score: 10.140942 Details | Listing | Web page
TTh 1.00-2.15 Fall 2009 Final exam scheduled (Group 26) 12/15/2009 T 2.00 Skills QR Introduction to the fundamental theory underlying modern digital communication. Quantitative measures of information and data compression: the Huffman and Lempel-Ziv algorithms, scalar and vector quantization. Representations of signal waveforms: sampling, orthonormal expansions, waveforms as vectors in signal space. Transmission of signals through noisy channels; pulse amplitude and quadrature amplitude modulation, orthogonal signaling, signal design, noise processes, optimal detection, and error probability analysis. Applications to practical systems such as CD players, telephone modems, and wireless networks.
Score: 10.140942 Details | Listing | Web page