[1] Shaoping Shi, Long Tian, Yajun Wang, et al. Demonstration of channel multiplexing quantum communication exploiting entangled sideband modes. Physical Review Letters, 125, 070502(2020).

[2] Qingwei Wang, Wei Li, Yimiao Wu, et al. Demonstration of 1→3 continuous-variable quantum telecloning. Physical Review A, 104, 032419(2021).

[3] Hexi Liang, Yonghong Dai, Yong Ai, . Design and test of space optical coupling balance detector. Infrared and Laser Engineering, 46, 0320002(2017).

[4] Yingxiu Kong, Xizheng Ke, Yuan Yang. Impact of local oscillator power on SNR in space coherent optical communications. Infrared and Laser Engineering, 45, 0222002(2016).

[5] Xuling Lin, Zhiqiang Wu, Song Yang, . A weak signal detection technique applied in deep space exploration. Infrared and Laser Engineering, 46, 0913002(2017).

[6] Xiaocong Sun, Yajun Wang, Yuhang Tian, et al. Deterministic and universal quantum squeezing gate with a teleportation‐like protocol. Laser & Photonics Reviews, 12, 2100329(2021).

[7] Yang Wenhai. Experimental instrumented study of strong squeezing quantum light source[D]. Taiyuan: Shanxi University, 2018. (in Chinese)

[8] Xiaoli Jin, Jing Su, Yaohui Zheng, et al. Balanced homodyne detection with high common mode rejection ratio based on parameter compensation of two arbitrary photodiodes. Opt Express, 23, 23859-23866(2015).

[9] Duan Huang, Jian Fang, Chao Wang, et al. A 300-MHz bandwidth balanced homodyne detector for continuous variable quantum key distribution. Chin Phys Lett, 30, 114209(2013).

[10] Du Shanna. Research on quantum classical channel multiplexing source independent security of continuous variable quantum key distribution with entangled states[D]. Taiyuan: Shanxi University, 2021. (in Chinese)

[11] Yunfei Bai, Junxiang Zhang. The experimental investigation of time-domain balanced homodyne detection of weak pulse. Journal of Quantum Optics, 2, 84-89(2011).

[12] Lixia Ma, Jiliang Qin, Zhihui Yan, . Fast response balanced homodyne detector for continuous-variable quantum memory. Acta Optica Sinica, 38, 0227001(2018).

[13] Huadong Lu, Jing Su, Yaohui Zheng, et al. Physical conditions of single-longitudinal-mode operation for high-power all-solid-state lasers. Opt Lett, 39, 1117-1120(2014).

[14] Keisuke Goda, O Miyakawa, E E Mikhailov, et al. A quantum-enhanced prototype gravitational-wave detector. Nat Phys, 4, 472(2008).

[15] LIGO Scientific Collaboration The. A gravitational wave observatory operating beyond the quantum shot-noise limit. Nature Phys, 7, 962-965(2011).

[16] M Stefszky, C M Mow-Lowry, S S Y Chua, et al. Balanced homodyne detection of optical quantum states at audio-band frequencies and below. Classical and Quantum Gravity, 29, 145015(2012).

[17] H Vahlbruch, S Chelkowski, K Danzmann, et al. Quantum engineering of squeezed states for quantum communication and metrology. New J Phys, 371(2007).

[18] O Jennrich. LISA technology and instrumentation. IOP Publishing, 26, 153001-153032(2009).

[19] Ziren Luo, Shan Bai, Xing Bian, . Gravitational wave detection by space laser interferometry. Advances in Mechanics, 43, 415-447(2013).

[20] Zhi Wang, Wei Sha, Zhe Chen, . Preliminary design and analysis of telescope for space gravitational wave detection. Chinese Optics, 11, 131-151(2018).

[21] Heshan Liu, Ruihong Gao, Ziren Luo, . Laser ranging and data communication for space gravitational wave detection. Chinese Optics, 12, 486-492(2019).

[22] Luyu Wang, Yuqiong Li, Rong Cai. Noise suppression of laser jitter in space laser interferometer. Chinese Optics, 14, 1426-1434(2021).

[23] Yajun Wang, Li Gao, Xiaoli Zhang, . Recent development of low noise laser for precision measurement (Invited). Infrared and Laser Engineering, 49, 20201073(2020).

[24] Jun Luo, Lisheng Chen, Huizhong Duan, et al. Tianqin: A space-borne gravitational wave detector. Classical & Quantum Gravity, 33, 035010(2015).

[25] Shubhashish Datta, Abhay Joshi, Jim Rue. Largearea InGaAs quad photeceiver f laser interferometry space antenna[C]Nanophotonics Macrophotonics f Space Environments IV, 2010.

[26] Kwee Patrick, Willke Benno, Danzmann Karsten. Shot-noise-limited laser power stabilization with a high-power photodiode array. Optics Letters, 34, 2912-2914(2009).

[27] Yuqiong Li, Luyu Wang, Chenyu Wang. Preliminary test of performance detection and analysis of weak-light detector for space gravitational wave detection. Optics and Precision Engineering, 27, 1710-1718(2019).

[28] Fernández Barranco. Photodetection in intersatellite laser interferometers[D]. Hannover: Gottfried Wilhelm Leibniz Universitt, 2017.

[29] Xiaocong Sun, Yajun Wang, Long Tian, et al. Detection of 13.8 dB squeezed vacuum states by optimizing the interference efficiency and gain of balanced homodyne detection. Chinese Optics Letters, 83-86(2019).

[30] Wang Jinrong. Experimental study of highperfmance photodetect in the squeezed light source[D]. Taiyuan: Shanxi University, 2021. (in Chinese)

[31] Xiaoli Jin, Jing Su, Yaohui Zheng. Influence of the non-ideal balanced homodyne detection on the measured squeezing degree. Acta Optica Sinica, 36, 1027001(2016).

[32] Jia Xue, Jiliang Qin, Yuchi Zhang, . Measurement of standard vacuum noise at low frequencies. Acta Phys Sin, 65, 044211(2016).

[33] Shaofeng Wang, Xiao Xiang, Conghua Zhou, et al. Simulation of high SNR photodetector with L-C coupling and transimpedance amplifier circuit and its verification. Rev Sci Instrum, 131, 013107(2017).

[34] Kay A. Operational Amplifier Noise: Techniques Tips f Analyzinig Reducing Noise [M]. Amsterdam: Elsevier Publication, 2012.

[35] M Tröbs, G Heinzel. Improved spectrum estimation from digitized time series on a logarithmic frequency axis. Measurement, 39, 120-129(2006).