[1] Huang H M, Xu L P. Survey on quantum positioning system[J]. Laser Journal, 36, 1-6(2015).
[2] Villoresi P, Jennewein T, Tamburini F et al. Experimental verification of the feasibility of a quantum channel between space and Earth[J]. New Journal of Physics, 10, 033038(2008).
[3] Zhang H Y, Zhang G J, Lin X P. The future of GPS: quantum positioning system[J]. Ship Electronic Engineering, 24, 40-43(2004).
[4] Yang C Y, Wu D W, Yu Y L et al[J]. Research on optimal constellation distribution of interferometric quantum positioning system Bulletin of Surveying and Mapping, 2009, 1-6.
[5] Li Y F, Wang Z H, Li B H et al. Experimental scheme design and analysis for the quantum spatial positioning with pulse laser[J]. Acta Photonica Sinica, 39, 1811-1815(2010).
[6] Nie M, Ren J M, Yang G et al. Influences of the ice-water mixed clouds on the performance of quantum satellite communication[J]. Acta Photonica Sinica, 45, 0927004(2016).
[7] Zhang X Z, Xu X, Liu B Y. Influence of fog on performance of free-space quantum communication[J]. Acta Optica Sinica, 40, 0727001(2020).
[8] Liu T, Zhu C, Sun C Y et al. Influences of different weather conditions on performance of free-space quantum communication system[J]. Acta Optica Sinica, 40, 0227001(2020).
[9] Huang H M, Xu L P, Wang Y et al. Attenuation characteristic of the QPS signal in the airspace[J]. Journal of Astronautics, 33, 891-895(2012).
[10] Cong S, Wu W S, Shang W W et al. Three quantum ranging and positioning schemes to reduce atmospheric interferences[J]. Journal of University of Science and Technology of China, 50, 64-71(2020).
[11] Bennett C H, Brassard G. Quantum cryptography: public key distribution and coin tossing[J]. Theoretical Computer Science, 560, 7-11(2014).
[12] Hwang W Y. Quantum key distribution with high loss: toward global secure communication[J]. Physical Review Letters, 91, 057901(2003).
[13] Wang X B. Decoy-state protocol for quantum cryptography with four different intensities of coherent light[J]. Physical Review A, 72, 012322(2005).
[14] Lo H K, Ma X F, Chen K. Decoy state quantum key distribution[J]. Physical Review Letters, 94, 230504(2005).
[15] Nie M, Wang Y, Yang G et al. Optimal mean photon number of decoy state protocol based on chameleon self-adaptive strategy under the background of rainfall[J]. Acta Physica Sinica, 65, 020303(2016).
[16] Xiao J J. Research of measuring technology based on quantum navigation and position[D]. Shanghai: Shanghai Jiao Tong University, 1-7(2014).
[17] Caves C M. Quantum-mechanical noise in an interferometer[J]. Physical Review D, 23, 1693-1708(1981).
[18] Pezzé L, Smerzi A. Entanglement, nonlinear dynamics, and the Heisenberg limit[J]. Physical Review Letters, 102, 100401(2009).
[19] Ou Z Y. Complementarity and fundamental limit in precision phase measurement[J]. Physical Review Letters, 77, 2352-2355(1996).
[20] Ou Z Y. Fundamental quantum limit in precision phase measurement[J]. Physical Review A, 55, 2598-2609(1997).
[21] Qing S. Research and application of security of quantum key distribution decoy BB84 protocol[D]. Xi’an: Xidian University, 26-42(2020).
[22] Wei H L, Liu Q H, Song Z F et al. Extinction of infrared radiation by rain[J]. Journal of Infrared Millimeter Waves, 16, 418-424(1997).
[23] Marshall J S. Palmer W M K. The distribution of raindrops with size[J]. Journal of Meteorology, 5, 165-166(1948).
[24] Wang H, Zhang T. Analysis of performance for free-space optical communications with rain or fog weather condition[J]. Laser & Optoelectronics Progress, 49, 080101(2012).
[25] Song F H, Xu C L, Wang S M. Multi-parameters measurement for liquid column based on rainbow technology[J]. Proceedings of the CSEE, 32, 110-116(2012).
[26] Li Y. Research on the practical security of the decoy state quantum key distribution[D]. Zhengzhou: Information Engineering University, 11-58(2015).
[27] Zhang Z P, Liu G J, Lu X et al. Security performance analysis of quantum key distribution protocol based on depolarization channel[J]. Chinese Journal of Quantum Electronics, 36, 464-470(2019).
