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Amnon Yariv
Researcher at California Institute of Technology
Publications - 1084
Citations - 56928
Amnon Yariv is an academic researcher from California Institute of Technology. The author has contributed to research in topics: Laser & Semiconductor laser theory. The author has an hindex of 103, co-authored 1082 publications receiving 55256 citations. Previous affiliations of Amnon Yariv include University of California, Santa Barbara & Watkins-Johnson Company.
Papers
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Groove GaInAsP laser on semi-insulating InP
TL;DR: In this article, a new GaInAsP/InP injection laser was fabricated on a semi-insulating substrate and a single LPE growth process on a grooved substrate was used to form an index guided device.
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Nonlinear self‐phase matching of optical second harmonic generation in lithium niobate
TL;DR: In this article, the authors show that the nonlinear index perturbation due to light-induced photovoltaic space charge field in LiNbO3 can give rise to self-phase matching of second harmonic generation.
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Semiparallel microelectronic implementation of neural network models using CCD technology
Aharon J. Agranat,Amnon Yariv +1 more
TL;DR: A new generic architecture for realising the basic functions of neural networks is described, and the N × N interconnectivity problem is accomplished by a simultaneous combination of horizontal and vertical shifting of CCD arrays.
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An experimental and theoretical study of the suppression of interferometric noise and distortion in AM optical links by phase dither
TL;DR: In this article, the effects of phase dither on the magnitude and spectral distribution of interferometric fiber optic noise and intermodulation products are considered and a theory is presented as well as experimental data which show major reduction of AM noise brought about by intentional narrow band and wide band phase-dither of the laser output.
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Quantum control of phase fluctuations in semiconductor lasers
TL;DR: The reduction of the quantum phase noise of a semiconductor laser is demonstrated through the direct control of the spontaneous emission into the laser mode, exercised via the precise and deterministic manipulation of the optical mode’s spatial field distribution.