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Course Criteria
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4.00 Credits
Lecture-3 hours; laboratory-3 hours. Prerequisite:course 165. Optical gain and amplification, laser threshold conditions, laser pumping requirements and techniques, laser resonator optics, cavity design, specific laser systems, short pulse generation, Q-switching, mode-locking, principles of nonlinear optics, second harmonic generation. optical parametric amplification, electro-optic effect.-II. (II.) Krol, Yeh
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4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:Physics 104A and Electrical and Computer Engineering 130B. Linear systems analysis of two-dimensional optical systems, 2D Fourier transforms, scalar diffraction theory, Fresnel and Fraunhofer diffraction, coherent and incoherent optical systems, spatial frequency analysis, analog optical information processing, spatial light modulators, film, holography, character recognition, and image restoration.-II. (II.) Kolner, Orel, Jensen
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4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:course 108B, Engineering 45, and Chemistry 110A. Relation between structure, composition, and optical properties of laser materials, nonlinear optical materials, photorefractives, fiber optics, semiconductors, liquid crystals, and thin films.-III. (III.) Krol, Parikh
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4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:Chemistry 110A and course 166. Fundamentals of absorption and emission, spectrometers, interferometers, light sources and detectors, UV, Visible, and IR spectroscopy, fluorescence spectroscopy, Raman and Brillouin scattering, high-resolution laser spectroscopy.- III. (III.) Orel, Kolner, Yeh, Parikh
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4.00 Credits
Lecture-3 hours; discussion-1 hour. Prerequisite:course 108B, Biological Sciences 2A, and Chemistry 110A. Optical techniques for resolving significant research problems in biology. Examples include the sequence, structure, and movement of DNA; nuclear organization and DNA replication; channel transport; membrane receptor sites and cell fusion; protein-protein interactions and supramolecular organization.-III. (III.) Yeh
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1.00 Credits
Discussion-1 hour. Prerequisite: advanced standing; consent of instructor. Weekly conference on research problems, progress and techniques in applied science. May be repeated for credit. (P/NP grading only.)-I, II, III. (I, II, III.)
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1.00 - 5.00 Credits
Internship-3-36 hours. Prerequisite: consent of instructor; upper division standing; approval of project prior to the period of the internship. Supervised work experience in Optical Science Engineering or Computational Applied Science. May be repeated for credit. (P/NP grading only.)-I, II, III. (I, II, III.)
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1.00 - 5.00 Credits
Prerequisite: consent of instructor. (P/NP grading only.)
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1.00 - 5.00 Credits
Prerequisite: consent of instructor. (P/NP grading only.)
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4.00 Credits
Lecture-3 hours; laboratory-3 hours. Prerequisite:Mathematics 21C (may be taken concurrently), Physics 9A (may be taken concurrently), Computer Science Engineering 30. Role of mathematics in modeling physical, biological, and engineering phenomena. Pitfalls in computation. Limitations of models, numerical implementations, and quality assessment of computational data. Interactions among mathematics, algorithms, computer hardware and software, and selected scientific and engineering applications.-III. (III.)
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