Page 127 - Kaleidoscope Academic Conference Proceedings 2021
P. 127
Connecting physical and virtual worlds
addition, global collaboration with relevant standardization [12] Eisaman, M. D. and Fan, Jingyun and Migdall, A. and
organizations is needed to further stimulate quantum Polyakov, S. V., “Invited Review Article: Single-photon
randomness activities. sources and detectors,” Rev. Sci. Instrum., vol. 82 no. 7,
pp. 071101, 2011.
REFERENCES
[13] Pironio, Stefano and Acín, Antonio and Massar, Serge
[1] Knuth, Donald E, “The Art of Computer Programming. and de La Giroday, A Boyer and Matsukevich, Dzimitry
3rd ed.,” Addison Wesley, 1997. N and Maunz, Peter and Olmschenk, Steven and Hayes,
David and Luo, Le and Manning, T Andrew and others,
[2] Yuan X, Zhou H Q, Cao Z, et al., “Intrinsic randomness
“Random numbers certified by Bell’s theorem,” Nature,
as a measure of quantum coherence,” Physics Review
vol. 464 no. 7291, pp. 1021–1024, 2010.
A, 92:022124, 2015.
[14] Coudron, Matthew and Yuen, Henrys, “Infinite
[3] Colbeck, Roger, “Quantum and relativistic protocols for
randomness expansion with a constant number
secure multi-party computation,” Phd Thesis., 2011.
of devices,” Proceedings of the 46th Annual
[4] Acín, Antonio and Masanes, Lluis “Certified ACM Symposium on Theory of Computing, ACM,
randomness in quantum physics,” Nature, Nature pp. 427–436, 2014.
Publishing Group., vol. 540 no. 7632, pp. 213, 2016.
[15] Arnon-Friedman, Rotem and Dupuis, Frédéric and
[5] Recommendation ITU T X.1702, “Quantum Fawzi, Omar and Renner, Renato and Vidick, Thomas,
noise random number generator architecture,” “Practical device-independent quantum cryptography
TELECOMMUNICATION STANDARDIZATION via entropy accumulation,” Nat. Commun., vol. 9 no. 1,
SECTOR OF ITU, 2019. pp. 459, 2018.
[6] Marco Avesani et al, “Source-device-independent [16] Knill, Emanuel and Zhang, Yanbao and Fu, Honghao,
heterodyne-based quantum random number generator “Quantum Probability Estimation for Randomness with
at 17 Gbps,” Nat Commun 9, 5365 2018. Quantum Side Information,” arXiv:1806.04553, 2018.
[7] Liu, Yang and Zhao Qi and Li, Ming-Han and Guan,
[17] Brown, Peter J and Ragy, Sammy and Colbeck,
Jian-Yu and Zhang, Yanbao and Bai, Bing and Zhang,
Roger, “An adaptive framework for quantum-secure
Weijun and Liu, Wen-Zhao and Wu, Cheng and
device-independent randomness expansion,”
Yuan, Xiao and others, “Device-independent quantum
arXiv:1810.13346, 2018.
random-number generation,” Nature, vol. 562 no. 7728,
pp. 548, 2018. [18] Li Ming-Han, Zhang, Xingjian, Liu Wen-Zhao, Zhao
Si-Ran, Bai Bing, Liu Yang, Zhao Qi, Peng Yuxiang,
[8] Bierhorst, Peter and Knill, Emanuel and Glancy, Scott
Zhang Jun, Zhang Yanbao, Munro W. J. , Ma Xiongfeng,
and Zhang, Yanbao and Mink, Alan and Jordan, Stephen
Zhang Qiang, Fan Jingyun and Pan Jian-Wei,
and Rommal, Andrea and Liu, Yi-Kai and Christensen,
“Experimental Realization of Device-Independent
Bradley and Nam, Sae Woo and others, “Experimentally
Quantum Randomness Expansion,” Phys. Rev. Lett,
generated randomness certified by the impossibility
vol. 126 no. 5, pp. 050503, 2021.
of superluminal signals,” Nature, vol. 556 no. 7700,
pp. 223, 2018. [19] Liu Wen-Zhao, Li Ming-Han, Ragy Sammy, Zhao
Si-Ran, Bai Bing, Liu Yang, Brown Peter J., Zhang
[9] Zhang, Yanbao and Shalm, Lynden K. and Bienfang,
Jun, Colbeck Roger, Fan Jingyun, Zhang Qiang, Pan
Joshua C. and Stevens, Martin J. and Mazurek Michael
Jian-Wei, “Device-independent randomness expansion
D. and Nam, Sae Woo and Abellán, Carlos and
against quantum side information,” Nature Physics,
Amaya, Waldimar and Mitchell, Morgan W. and
vol. 17, pp. 448–451, 2021.
Fu, Honghao and others, “Experimental Low-Latency
Device-Independent Quantum Randomness,” Physical
[20] Lynden K. Shalm, Yanbao Zhang, Joshua C. Bienfang,
review letters, 124(1):010505 2020.
Collin Schlager, Martin J. Stevens, Michael D.
[10] Vazirani, Umesh V and Vazirani, Vijay V, “Efficient and Mazurek, Carlos Abellán, Waldimar Amaya, Morgan
secure pseudo-random number generation,” Workshop W. Mitchell, Mohammad A. Alhejji, Honghao Fu, Joel
on the Theory and Application of Cryptographic Ornstein, Richard P. Mirin, Sae Woo Nam, Emanuel
Techniques, Springer, pp. 193–202, 1984. Knill, “Device-independent randomness expansion
with entangled photons,” Nature Physics, vol. 17,
[11] Miller, Carl A. and Shi, Yaoyun, “Robust Protocols pp. 452–456, 2021.
for Securely Expanding Randomness and Distributing
Keys Using Untrusted Quantum Devices,” Proceedings [21] Eberhard, Philippe H, “Background level and
of the 46th Annual ACM Symposium on Theory of counter efficiencies required for a loophole-free
Computing, ACM, New York, NY, USA, pp. 417–426, Einstein-Podolsky-Rosen experiment,” Physical Review
doi = 10.1145/2591796.2591843, 2014. A, vol. 47 no. 2, pp. 747, 1993.
– 65 –
