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Autori principali: Lin, Hong, Liu, Mengmeng, Guo, Xiaomin, Luo, Yue, Wang, Qiqi, Song, Zhijie, Guo, Yanqiang, Xiao, Liantuan
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2503.03298
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author Lin, Hong
Liu, Mengmeng
Guo, Xiaomin
Luo, Yue
Wang, Qiqi
Song, Zhijie
Guo, Yanqiang
Xiao, Liantuan
author_facet Lin, Hong
Liu, Mengmeng
Guo, Xiaomin
Luo, Yue
Wang, Qiqi
Song, Zhijie
Guo, Yanqiang
Xiao, Liantuan
contents True random numbers are extracted through measurements of vacuum fluctuations in quantum state components. We propose an improved scheme utilizing an optimization-based simulation methodology to enhance the temporal resolution of quantum state detection and processing efficiency of vacuum fluctuation signals in continuous-variable quantum random number generators (CV-QRNGs), while simultaneously maximizing the entropy content of quantum noise sources. This work presents the first application of optimization simulation methodology to balanced homodyne detector (BHD) circuit design, with particular emphasis on improving high-frequency transmission characteristics. The design framework prioritizes system stability and S-parameter sensitivity to optimize both circuit architecture and critical component parameters. The AC amplifier circuit was implemented through ADS high-frequency simulations using two ABA-52563 RF amplifiers in a cascaded configuration, with circuit modeling performed on Rogers 4350 substrate optimized for high-frequency applications. This approach enabled the development of a switched-configuration BHD featuring: 1) 1.9 GHz bandwidth, 2) 41.5 dB signal-to-noise ratio at 1.75 GHz, 3) 30 dB common-mode rejection ratio at 100 MHz, and 4) frequency response flatness within 1.5 dB across 1.3-1.7 GHz. Additionally, the Husimi function is employed for entropy analysis to reconstruct vacuum state phase-space distributions, validating the detector's quantum measurement fidelity. The implemented system demonstrates a collective generation rate of 20.0504 Gbps across four parallel channels, with all output streams successfully passing NIST SP 800-22 statistical testing requirements.
format Preprint
id arxiv_https___arxiv_org_abs_2503_03298
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Development_of_a_novel_high-performance_balanced_homodyne_detector
Lin, Hong
Liu, Mengmeng
Guo, Xiaomin
Luo, Yue
Wang, Qiqi
Song, Zhijie
Guo, Yanqiang
Xiao, Liantuan
Quantum Physics
Optics
True random numbers are extracted through measurements of vacuum fluctuations in quantum state components. We propose an improved scheme utilizing an optimization-based simulation methodology to enhance the temporal resolution of quantum state detection and processing efficiency of vacuum fluctuation signals in continuous-variable quantum random number generators (CV-QRNGs), while simultaneously maximizing the entropy content of quantum noise sources. This work presents the first application of optimization simulation methodology to balanced homodyne detector (BHD) circuit design, with particular emphasis on improving high-frequency transmission characteristics. The design framework prioritizes system stability and S-parameter sensitivity to optimize both circuit architecture and critical component parameters. The AC amplifier circuit was implemented through ADS high-frequency simulations using two ABA-52563 RF amplifiers in a cascaded configuration, with circuit modeling performed on Rogers 4350 substrate optimized for high-frequency applications. This approach enabled the development of a switched-configuration BHD featuring: 1) 1.9 GHz bandwidth, 2) 41.5 dB signal-to-noise ratio at 1.75 GHz, 3) 30 dB common-mode rejection ratio at 100 MHz, and 4) frequency response flatness within 1.5 dB across 1.3-1.7 GHz. Additionally, the Husimi function is employed for entropy analysis to reconstruct vacuum state phase-space distributions, validating the detector's quantum measurement fidelity. The implemented system demonstrates a collective generation rate of 20.0504 Gbps across four parallel channels, with all output streams successfully passing NIST SP 800-22 statistical testing requirements.
title Development_of_a_novel_high-performance_balanced_homodyne_detector
topic Quantum Physics
Optics
url https://arxiv.org/abs/2503.03298