Modulation format identification in fiber communications using single dynamical node-based photonic reservoir computing
Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid
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Yn: Photon. Res., Cyfrol 9, Rhif 1, 01.01.2021, t. B1-B8.
Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid
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T1 - Modulation format identification in fiber communications using single dynamical node-based photonic reservoir computing
AU - Cai, Qiang
AU - Guo, Ya
AU - Li, Pu
AU - Bogris, Adonis
AU - Shore, K. Alan
AU - Zhang, Yamei
AU - Wang, Yuncai
PY - 2021/1/1
Y1 - 2021/1/1
N2 - We present a simple approach based on photonic reservoir computing (P-RC) for modulation format identification (MFI) in optical fiber communications. Here an optically injected semiconductor laser with self-delay feedback is trained with the representative features from the asynchronous amplitude histograms of modulation signals. Numerical simulations are conducted for three widely used modulation formats (onx2013;off keying, differential phase-shift keying, and quadrature amplitude modulation) for various transmission situations where the optical signal-to-noise ratio varies from 12 to 26x00A0;dB, the chromatic dispersion varies from x2212;500 to 500x00A0;ps/nm, and the differential group delay varies from 0 to 20x00A0;ps. Under these situations, final simulation results demonstrate that this technique can efficiently identify all those modulation formats with an accuracy of gt;95RC layer such as the injection strength, feedback strength, bias current, and frequency detuning. The proposed technique utilizes very simple devices and thus offers a resource-efficient alternative approach to MFI.
AB - We present a simple approach based on photonic reservoir computing (P-RC) for modulation format identification (MFI) in optical fiber communications. Here an optically injected semiconductor laser with self-delay feedback is trained with the representative features from the asynchronous amplitude histograms of modulation signals. Numerical simulations are conducted for three widely used modulation formats (onx2013;off keying, differential phase-shift keying, and quadrature amplitude modulation) for various transmission situations where the optical signal-to-noise ratio varies from 12 to 26x00A0;dB, the chromatic dispersion varies from x2212;500 to 500x00A0;ps/nm, and the differential group delay varies from 0 to 20x00A0;ps. Under these situations, final simulation results demonstrate that this technique can efficiently identify all those modulation formats with an accuracy of gt;95RC layer such as the injection strength, feedback strength, bias current, and frequency detuning. The proposed technique utilizes very simple devices and thus offers a resource-efficient alternative approach to MFI.
KW - Differential phase shift keying
KW - Fiber optic communications
KW - Numerical simulation
KW - Optical networks
KW - Phase modulation
KW - Quadrature amplitude modulation
U2 - 10.1364/PRJ.409114
DO - 10.1364/PRJ.409114
M3 - Article
VL - 9
SP - B1-B8
JO - Photon. Res.
JF - Photon. Res.
IS - 1
ER -