Optical Feedback Self-Mixing Interferometry With a Large Feedback Factor C : Behavior Studies

This paper studies the behavior of optical feedback self-mixing interferometric (OFSMI) systems, where the semiconductor lasers operate at a single mode (perturbed external cavity mode) with a large optical feedback factor C . Based on analysis of the spectral linewidth associated with all the possi...

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Veröffentlicht in:	IEEE journal of quantum electronics 2009-07, Vol.45 (7), p.840-848
Hauptverfasser:	Yanguang Yu, Jiangtao Xi, Chicharo, J.F., Bosch, T.M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Competition Displacement Equations Exact sciences and technology Fundamental areas of phenomenology (including applications) Holes Jumping Laser feedback Laser modes Laser sintering Lasers Lasing Mode competition Optical feedback optical feedback factor optical feedback interferometry Optical interferometry Optics Physics Power lasers Quantum electronics self-mixing effect semiconductor laser (SL) Semiconductor lasers Semiconductor lasers laser diodes Stimulated emission Surface emitting lasers
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creator	Yanguang Yu Jiangtao Xi Chicharo, J.F. Bosch, T.M.
description	This paper studies the behavior of optical feedback self-mixing interferometric (OFSMI) systems, where the semiconductor lasers operate at a single mode (perturbed external cavity mode) with a large optical feedback factor C . Based on analysis of the spectral linewidth associated with all the possible lasing modes at different C values, a set of mode jumping rules are proposed following the minimum linewidth mode competition principle proposed in . According to the rules, the C factor can be classified into different regions, on which an OFSMI system will exhibit distinct phenomena. In particular, for the same amount of displacement associated with the external cavity, the fringe number reduction on the OFSMI signal should be observed when C increases from one region to the next. An experimental setup with a laser diode HL7851G was implemented and employed to verify the proposed rules. The behavior of the OFSMI predicted by the paper has been confirmed by the experiments with C value up to 8.0.
doi_str_mv	10.1109/JQE.2009.2013153
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Based on analysis of the spectral linewidth associated with all the possible lasing modes at different C values, a set of mode jumping rules are proposed following the minimum linewidth mode competition principle proposed in . According to the rules, the C factor can be classified into different regions, on which an OFSMI system will exhibit distinct phenomena. In particular, for the same amount of displacement associated with the external cavity, the fringe number reduction on the OFSMI signal should be observed when C increases from one region to the next. An experimental setup with a laser diode HL7851G was implemented and employed to verify the proposed rules. 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Based on analysis of the spectral linewidth associated with all the possible lasing modes at different C values, a set of mode jumping rules are proposed following the minimum linewidth mode competition principle proposed in . According to the rules, the C factor can be classified into different regions, on which an OFSMI system will exhibit distinct phenomena. In particular, for the same amount of displacement associated with the external cavity, the fringe number reduction on the OFSMI signal should be observed when C increases from one region to the next. An experimental setup with a laser diode HL7851G was implemented and employed to verify the proposed rules. 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subjects	Competition Displacement Equations Exact sciences and technology Fundamental areas of phenomenology (including applications) Holes Jumping Laser feedback Laser modes Laser sintering Lasers Lasing Mode competition Optical feedback optical feedback factor optical feedback interferometry Optical interferometry Optics Physics Power lasers Quantum electronics self-mixing effect semiconductor laser (SL) Semiconductor lasers Semiconductor lasers laser diodes Stimulated emission Surface emitting lasers
title	Optical Feedback Self-Mixing Interferometry With a Large Feedback Factor C : Behavior Studies
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