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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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Dynamic analysis of the semiconductor laser as a current-controlled oscillator in the optical phased-lock loop: applications.
TL;DR: A methodology for treating the semiconductor laser as a current-controlled oscillator in an optical phase-lock loop is presented and the formalism is applied to phase demodulation of optical beams, reduction of phase noise by self-homodyning, and phase locking of a semiconductor lasers array.
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Spatial Information Processing And Distortion Correction Via Four-Wave Mixing
Jeffrey O. White,Amnon Yariv +1 more
TL;DR: The versatility of degenerate four-wave mixing has made possible its application to two major areas of spatial information processing: distortion correction and mathematical operations.
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Coherence Cloning Using Semiconductor Laser Optical Phase-Lock Loops
TL;DR: In this article, the authors demonstrate the concept of coherence cloning where the coherence properties of a high-quality spectrally stabilized fiber laser are transferred to a commercially available high-power DFB semiconductor laser (SCL) using an optical phase-lock loop.
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Broadband tunability of gain‐flattened quantum well semiconductor lasers with an external grating
TL;DR: In this paper, the gain requirement for a grating-tuned external cavity configuration is examined and applied to a semiconductor quantum well laser with an optimized length of gain region.
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Grating induced transparency (GIT) and the dark mode in optical waveguides
Hsi-Chun Liu,Amnon Yariv +1 more
TL;DR: A new type of optical mode that possesses a formal analogy to the dark atomic state involved in electromagnetically induced transparency that displays a transparency and slow light behavior free from the bandwidth-delay product constraint.