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Photonic Network Communications

Erschienen in:

18.05.2016

Error performance of optically preamplified hybrid BPSK-PPM systems with transmitter and receiver imperfections

verfasst von: Taha Landolsi, Aly F. Elrefaie, Sanaa Hamid, Mohamed S. Hassan

Erschienen in: Photonic Network Communications | Ausgabe 2/2017

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Abstract

In this paper, we investigate the impact of the transmitter finite extinction ratio and the receiver carrier recovery phase offset on the error performance of two optically preamplified hybrid M-ary pulse position modulation (PPM) systems with coherent detection. The first system, referred to as PB-mPPM, combines polarization division multiplexing (PDM) with binary phase-shift keying and M-ary PPM, and the other system, referred to as PQ-mPPM, combines PDM with quadrature phase-shift keying and M-ary PPM. We provide new expressions for the probability of bit error for PB-mPPM and PQ-mPPM under finite extinction ratios and phase offset. The extinction ratio study indicates that the coherent systems PB-mPPM and PQ-mPPM outperform the direct-detection ones. It also shows that at \(P_b=10^{-9}\) PB-mPPM has a slight advantage over PQ-mPPM. For example, for a symbol size \(M=16\) and extinction ratio \(r=30\) dB, PB-mPPM requires 0.6 dB less SNR per bit than PQ-mPPM to achieve \(P_b=10^{-9}\). This investigation demonstrates that PB-mPPM is less complex and less sensitive to the variations of the offset angle \(\theta \) than PQ-mPPM. For instance, for \(M=16\), \(r=30\) dB, and \(\theta =10^{\circ }\) PB-mPPM requires 1.6 dB less than PQ-mPPM to achieve \(P_b=10^{-9}\). However, PB-mPPM enhanced robustness to phase offset comes at the expense of a reduced bandwidth efficiency when compared to PQ-mPPM. For example, for \(M=2\) its bandwidth efficiency is 60 % that of PQ-mPPM and \(\approx 86\,\%\) for \(M=1024\). For these reasons, PB-mPPM can be considered a reasonable design trade-off for M-ary PPM systems.

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Titel: Error performance of optically preamplified hybrid BPSK-PPM systems with transmitter and receiver imperfections
verfasst von: Taha Landolsi
Aly F. Elrefaie
Sanaa Hamid
Mohamed S. Hassan
Publikationsdatum: 18.05.2016
Verlag: Springer US
Erschienen in: Photonic Network Communications / Ausgabe 2/2017
Print ISSN: 1387-974X
Elektronische ISSN: 1572-8188
DOI: https://doi.org/10.1007/s11107-016-0636-1

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