Highly robust and hardware-efficient frame synchronization and carrier recovery via pilot-only approaches for short-reach optical interconnections

Chenchen Wang; Zhipei Li; Ze Dong; Junyuan Song; Ran Gao; Dong Guo; Huan Chang; Lei Zhu; Xiaolong Pan; Tianle Mai; Shanting Hu; Xiangjun Xin

doi:10.3788/COL202523.060602

Highly robust and hardware-efficient frame synchronization and carrier recovery via pilot-only approaches for short-reach optical interconnections

Chenchen Wang, Zhipei Li^*, Ze Dong, Junyuan Song, Ran Gao, Dong Guo, Huan Chang, Lei Zhu, Xiaolong Pan, Tianle Mai, Shanting Hu, Xiangjun Xin

^*Corresponding author for this work

School of Information and Electronics, Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

We propose a cost-effective scheme relying exclusively on pilot symbols for robust frame synchronization and high-precision, wide-range carrier recovery in short-reach optical interconnects. Our method mitigates phase offsets and enhances phase tracking by strategically placing dual-polarization pilot symbols, both aligned and misaligned, within the frame. Compared to traditional carrier recovery schemes, our approach offers a broader frequency offset estimation range, higher carrier recovery accuracy, and significantly lower computational complexity. Experimental results show a 0.7 dB sensitivity improvement at the soft decision forward error correction threshold, outperforming Fourier transform-based frequency offset estimation combined with blind phase search.

Original language	English
Article number	060602
Journal	Chinese Optics Letters
Volume	23
Issue number	6
DOIs	https://doi.org/10.3788/COL202523.060602
Publication status	Published - 1 Jun 2025
Externally published	Yes

Keywords

carrier recovery
frame synchronization
pilot symbol
short-reach optical interconnect

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10.3788/COL202523.060602

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title = "Highly robust and hardware-efficient frame synchronization and carrier recovery via pilot-only approaches for short-reach optical interconnections",

abstract = "We propose a cost-effective scheme relying exclusively on pilot symbols for robust frame synchronization and high-precision, wide-range carrier recovery in short-reach optical interconnects. Our method mitigates phase offsets and enhances phase tracking by strategically placing dual-polarization pilot symbols, both aligned and misaligned, within the frame. Compared to traditional carrier recovery schemes, our approach offers a broader frequency offset estimation range, higher carrier recovery accuracy, and significantly lower computational complexity. Experimental results show a 0.7 dB sensitivity improvement at the soft decision forward error correction threshold, outperforming Fourier transform-based frequency offset estimation combined with blind phase search.",

keywords = "carrier recovery, frame synchronization, pilot symbol, short-reach optical interconnect",

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T1 - Highly robust and hardware-efficient frame synchronization and carrier recovery via pilot-only approaches for short-reach optical interconnections

AU - Wang, Chenchen

AU - Li, Zhipei

AU - Dong, Ze

AU - Song, Junyuan

AU - Gao, Ran

AU - Guo, Dong

AU - Chang, Huan

AU - Zhu, Lei

AU - Pan, Xiaolong

AU - Mai, Tianle

AU - Hu, Shanting

AU - Xin, Xiangjun

PY - 2025/6/1

Y1 - 2025/6/1

N2 - We propose a cost-effective scheme relying exclusively on pilot symbols for robust frame synchronization and high-precision, wide-range carrier recovery in short-reach optical interconnects. Our method mitigates phase offsets and enhances phase tracking by strategically placing dual-polarization pilot symbols, both aligned and misaligned, within the frame. Compared to traditional carrier recovery schemes, our approach offers a broader frequency offset estimation range, higher carrier recovery accuracy, and significantly lower computational complexity. Experimental results show a 0.7 dB sensitivity improvement at the soft decision forward error correction threshold, outperforming Fourier transform-based frequency offset estimation combined with blind phase search.

AB - We propose a cost-effective scheme relying exclusively on pilot symbols for robust frame synchronization and high-precision, wide-range carrier recovery in short-reach optical interconnects. Our method mitigates phase offsets and enhances phase tracking by strategically placing dual-polarization pilot symbols, both aligned and misaligned, within the frame. Compared to traditional carrier recovery schemes, our approach offers a broader frequency offset estimation range, higher carrier recovery accuracy, and significantly lower computational complexity. Experimental results show a 0.7 dB sensitivity improvement at the soft decision forward error correction threshold, outperforming Fourier transform-based frequency offset estimation combined with blind phase search.

KW - carrier recovery

KW - frame synchronization

KW - pilot symbol

KW - short-reach optical interconnect

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M3 - Article

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JF - Chinese Optics Letters

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ER -

Highly robust and hardware-efficient frame synchronization and carrier recovery via pilot-only approaches for short-reach optical interconnections

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Keywords

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