The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
Kami menerangkan reflekometri FMCW untuk pencirian gentian optik panjang dengan menggunakan diod laser rongga luaran sebagai sumber cahaya. Memandangkan perbezaan laluan optik antara rasuk rujukan dan rasuk pantulan daripada gentian optik yang sedang diuji adalah lebih panjang daripada panjang koheren sumber cahaya, rujukan dan rasuk pantulan adalah berhias fasa. Akibatnya, spektrum rentak antara rujukan dan rasuk pantulan diukur. Dalam reflektomiti FMCW yang dihias fasa, resolusi spatial dipertingkatkan dengan mengecilkan lebar garis spektrum sumber cahaya dan meningkatkan kekerapan pengulangan sapuan frekuensi optik serta meningkatkan julat kicauan sapuan frekuensi optik. Dalam eksperimen, laser DFB rongga luaran digunakan sebagai sumber cahaya lebar talian sempit, dan frekuensi optik disapu oleh modulasi minit panjang rongga luaran. Gentian optik mod tunggal panjang dicirikan, dan julat pengukuran maksimum 80 km dicapai, dan resolusi spatial 46 m, 100 m dan 2 km dicapai masing-masing pada jarak 5 km, 11 km dan 80 km. Penyebaran belakang Rayleigh diukur dengan jelas dan kehilangan perambatan gentian optik juga diukur. Keuntungan optik penguat gentian optik berdop erbium (EDFA) juga dianggarkan daripada perubahan tahap serakan belakang Rayleigh dalam gentian optik diikuti selepas EDFA.
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Salinan
Koichi IIYAMA, Takahiro MAEDA, Saburo TAKAMIYA, "Phase-Decorrelated FMCW Reflectometry for Long Optical Fiber Characterization by Using a Laser Diode with Modulated External-Cavity" in IEICE TRANSACTIONS on Electronics,
vol. E83-C, no. 3, pp. 428-434, March 2000, doi: .
Abstract: We describe FMCW reflectometry for characterization of long optical fibers by using an external-cavity laser diode as a light source. Since the optical path difference between the reference beam and the reflected beam from the optical fiber under test is much longer than the coherence length of the light source, the reference and the reflected beams are phase-decorrelated. As a result, the beat spectrum between the reference and the reflected beams is measured. In the phase-decorrelated FMCW reflectomety, the spatial resolution is enhanced by narrowing the spectral linewidth of the light source and increasing the repetition frequency of the optical frequency sweep as well as increasing the chirping range of the optical frequency sweep. In the experiments, an external-cavity DFB laser is used as a narrow linewidth light source, and the optical frequency is swept by minute modulation of the external cavity length. Long single mode optical fibers are characterized, and the maximum measurement range of 80 km is achieved, and the spatial resolutions of 46 m, 100 m and 2 km are achieved at 5 km, 11 km and 80 km distant, respectively. The Rayleigh backscattering is clearly measured and the propagation loss of optical fiber is also measured. The optical gain of an erbium-doped optical fiber amplifier (EDFA) is also estimated from the change in the Rayleigh backscattering level in the optical fiber followed after the EDFA.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e83-c_3_428/_p
Salinan
@ARTICLE{e83-c_3_428,
author={Koichi IIYAMA, Takahiro MAEDA, Saburo TAKAMIYA, },
journal={IEICE TRANSACTIONS on Electronics},
title={Phase-Decorrelated FMCW Reflectometry for Long Optical Fiber Characterization by Using a Laser Diode with Modulated External-Cavity},
year={2000},
volume={E83-C},
number={3},
pages={428-434},
abstract={We describe FMCW reflectometry for characterization of long optical fibers by using an external-cavity laser diode as a light source. Since the optical path difference between the reference beam and the reflected beam from the optical fiber under test is much longer than the coherence length of the light source, the reference and the reflected beams are phase-decorrelated. As a result, the beat spectrum between the reference and the reflected beams is measured. In the phase-decorrelated FMCW reflectomety, the spatial resolution is enhanced by narrowing the spectral linewidth of the light source and increasing the repetition frequency of the optical frequency sweep as well as increasing the chirping range of the optical frequency sweep. In the experiments, an external-cavity DFB laser is used as a narrow linewidth light source, and the optical frequency is swept by minute modulation of the external cavity length. Long single mode optical fibers are characterized, and the maximum measurement range of 80 km is achieved, and the spatial resolutions of 46 m, 100 m and 2 km are achieved at 5 km, 11 km and 80 km distant, respectively. The Rayleigh backscattering is clearly measured and the propagation loss of optical fiber is also measured. The optical gain of an erbium-doped optical fiber amplifier (EDFA) is also estimated from the change in the Rayleigh backscattering level in the optical fiber followed after the EDFA.},
keywords={},
doi={},
ISSN={},
month={March},}
Salinan
TY - JOUR
TI - Phase-Decorrelated FMCW Reflectometry for Long Optical Fiber Characterization by Using a Laser Diode with Modulated External-Cavity
T2 - IEICE TRANSACTIONS on Electronics
SP - 428
EP - 434
AU - Koichi IIYAMA
AU - Takahiro MAEDA
AU - Saburo TAKAMIYA
PY - 2000
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E83-C
IS - 3
JA - IEICE TRANSACTIONS on Electronics
Y1 - March 2000
AB - We describe FMCW reflectometry for characterization of long optical fibers by using an external-cavity laser diode as a light source. Since the optical path difference between the reference beam and the reflected beam from the optical fiber under test is much longer than the coherence length of the light source, the reference and the reflected beams are phase-decorrelated. As a result, the beat spectrum between the reference and the reflected beams is measured. In the phase-decorrelated FMCW reflectomety, the spatial resolution is enhanced by narrowing the spectral linewidth of the light source and increasing the repetition frequency of the optical frequency sweep as well as increasing the chirping range of the optical frequency sweep. In the experiments, an external-cavity DFB laser is used as a narrow linewidth light source, and the optical frequency is swept by minute modulation of the external cavity length. Long single mode optical fibers are characterized, and the maximum measurement range of 80 km is achieved, and the spatial resolutions of 46 m, 100 m and 2 km are achieved at 5 km, 11 km and 80 km distant, respectively. The Rayleigh backscattering is clearly measured and the propagation loss of optical fiber is also measured. The optical gain of an erbium-doped optical fiber amplifier (EDFA) is also estimated from the change in the Rayleigh backscattering level in the optical fiber followed after the EDFA.
ER -