Experimental demonstration on enhanced separation of mixed high-dimension optical-chaotic signals using double photonic reservoir computing based on optically pumped VCSELs

Experimental demonstration on enhanced separation of mixed high-dimension optical-chaotic signals using double photonic reservoir computing based on optically pumped VCSELs

We present an experimental methodology designed to separate two groups of mixed optical chaotic signals, whether the mixing fractions are known or unknown. This separation is achieved using a VCSEL-based reservoir computing (RC) system. In the experiment, one group of mixed optical chaotic signals i...

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Veröffentlicht in:Journal of lightwave technology 2024-12, p.1-12
Hauptverfasser: Zhong, Dongzhou, Wu, Qingfan, Zeng, Hongen, Chen, Yujun, Wang, Tiankai, Ren, Zhanfeng, Wang, Youmeng, Qiu, Chenghao, Jiang, Wei
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Sprache:eng
Schlagworte:
Adaptive optics
Chaotic communication
High-speed optical techniques
Optical amplifiers
Optical attenuators
Optical feedback
Optical mixing
Optical polarization
Optical pumping
Photon reservoir computing
Separation of mixed optical chaotic signals
Vertical cavity surface emitting laser
Vertical cavity surface emitting lasers
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container_issue
container_start_page 1
container_title Journal of lightwave technology
container_volume
creator Zhong, Dongzhou
Wu, Qingfan
Zeng, Hongen
Chen, Yujun
Wang, Tiankai
Ren, Zhanfeng
Wang, Youmeng
Qiu, Chenghao
Jiang, Wei
description We present an experimental methodology designed to separate two groups of mixed optical chaotic signals, whether the mixing fractions are known or unknown. This separation is achieved using a VCSEL-based reservoir computing (RC) system. In the experiment, one group of mixed optical chaotic signals is linearly combined with two beams of chaotic X-polarization components (X-PCs) or Y-polarization components (Y-PCs) emitted by optically pumped spin-VCSELs with optical feedback. Double reservoirs are formed using the chaotic X-PC and Y-PC outputs from the optically pumped spin-VCSEL, which is subjected to both optical feedback and optical injection. Moreover, we experimentally demonstrate the performance of separating each group of linearly mixed chaotic signals into their individual components. The results show that two groups of mixed optical chaotic signals can be effectively separated using two reservoirs in a single RC system, with separation errors, characterized by normalized mean square error, being no more than 0.1 through system parameter optimization when the mixing fractions are known in advance. If the mixing fractions are unknown, we utilize two cascaded RC systems to separate each group of mixed optical signals. The mixing fractions can be accurately estimated using double reservoirs in the first RC system. Based on these estimated mixing fractions, the two groups of mixed optical chaotic signals can be effectively separated using double reservoirs in the second RC system, with separation errors also being no more than 0.1 through further optimization of the system parameters. The photonic reservoir computing hardware proposed in our experiment for separating complex optical chaotic signals has the potential to significantly impact the development of novel principles and hardware implementations for multiple access and demultiplexing in multi-channel chaotic cryptographic communication.
doi_str_mv 10.1109/JLT.2024.3517145
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If the mixing fractions are unknown, we utilize two cascaded RC systems to separate each group of mixed optical signals. The mixing fractions can be accurately estimated using double reservoirs in the first RC system. Based on these estimated mixing fractions, the two groups of mixed optical chaotic signals can be effectively separated using double reservoirs in the second RC system, with separation errors also being no more than 0.1 through further optimization of the system parameters. The photonic reservoir computing hardware proposed in our experiment for separating complex optical chaotic signals has the potential to significantly impact the development of novel principles and hardware implementations for multiple access and demultiplexing in multi-channel chaotic cryptographic communication.</abstract><pub>IEEE</pub><doi>10.1109/JLT.2024.3517145</doi><tpages>12</tpages></addata></record>
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subjects Adaptive optics
Chaotic communication
High-speed optical techniques
Optical amplifiers
Optical attenuators
Optical feedback
Optical mixing
Optical polarization
Optical pumping
Photon reservoir computing
Separation of mixed optical chaotic signals
Vertical cavity surface emitting laser
Vertical cavity surface emitting lasers
title Experimental demonstration on enhanced separation of mixed high-dimension optical-chaotic signals using double photonic reservoir computing based on optically pumped VCSELs
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