Your search keyword '"Zhao, Tongge"' showing total 10 results

1. Quantum Random Number Generation Based on Phase Reconstruction

Author

Li, Jialiang, Huang, Zitao, Yu, Chunlin, Wu, Jiajie, Zhao, Tongge, Zhu, Xiangwei, and Sun, Shihai

Subjects

Quantum Physics

Abstract

Quantum random number generator (QRNG) utilizes the intrinsic randomness of quantum systems to generate completely unpredictable and genuine random numbers, finding wide applications across many fields. QRNGs relying on the phase noise of a laser have attracted considerable attention due to their straightforward system architecture and high random number generation rates. However, traditional phase noise QRNGs suffer from a 50\% loss of quantum entropy during the randomness extraction process. In this paper, we propose a phase-reconstruction quantum random number generation scheme, in which the phase noise of a laser is reconstructed by simultaneously measuring the orthogonal quadratures of the light field using balanced detectors. This enables direct discretization of uniform phase noise, and the min-entropy can achieve a value of 1. Furthermore, our approach exhibits inherent robustness against the classical phase fluctuations of the unbalanced interferometer, eliminating the need for active compensation. Finally, we conducted experimental validation using commercial optical hybrid and balanced detectors, achieving a random number generation rate of 1.96 Gbps at a sampling rate of 200 MSa/s., Comment: 11pages. Submitted to Optics Express, and any comment is welcome

Published

2024

2. An Unbiased Quantum Random Number Generator Based on Boson Sampling

Author

Shi, Jinjing, Zhao, Tongge, Wang, Yizhi, Yu, Chunlin, Lu, Yuhu, Shi, Ronghua, Zhang, Shichao, and Wu, Junjie

Subjects

Quantum Physics

Abstract

It has been proven that Boson sampling is a much promising model of optical quantum computation, which has been applied to designing quantum computer successfully, such as "Jiuzhang". However, the meaningful randomness of Boson sampling results, whose correctness and significance were proved from a specific quantum mechanical distribution, has not been utilized or exploited. In this research, Boson sampling is applied to design a novel Quantum Random Number Generator (QRNG) by fully exploiting the randomness of Boson sampling results, and its prototype system is constructed with the programmable silicon photonic processor, which can generate uniform and unbiased random sequences and overcome the shortcomings of the existing discrete QRNGs such as source-related, high demand for the photon number resolution capability of the detector and slow self-detection generator speed. Boson sampling is implemented as a random entropy source, and random bit strings with satisfactory randomness and uniformity can be obtained after post-processing the sampling results. It is the first approach for applying the randomness of Boson sampling results to develop a practical prototype system for actual tasks, and the experiment results demonstrate the designed Boson sampling-based QRNG prototype system pass 15 tests of the NIST SP 800-22 statistical test component, which prove that Boson sampling has great potential for practical applications with desirable performance besides quantum advantage., Comment: 14 pages, 8 figures

Published

2022

3. Gallium oxide nanocrystals for self-powered deep ultraviolet photodetectors

Author

Tan, Yufei, Qiao, Qian, Zhao, Tongge, Chang, Shulong, Zhang, Zhenfeng, Zang, Jinhao, Lin, Chaonan, Shang, Yuanyuan, Yang, Xun, Zhou, Jiawen, Yu, Xuan, Yu, Xiaoming, and Shan, Chongxin

Published

2024

4. Self-powered poly(3-hexylthiophene)/ZnO heterojunction ultraviolet photodetectors decorated by silver nanoparticles

Author

Qiao, Qian, Zhao, Tongge, Zheng, Jian, Yin, Huiting, Zhang, Yuan, Zang, Jinhao, Yang, Xun, Li, Haoyu, Rao, Taotao, Yu, Xuan, and Yu, Xiaoming

Published

2024

5. Image encryption with quantum cellular neural network

Author

Shi, Jinjing, Chen, Shuhui, Chen, Tian, Zhao, Tongge, Tang, Jiuqi, Li, Qin, Yu, Chunlin, and Shi, Heyuan

Published

2022

6. Quantum Random Number Generation Based on Phase Reconstruction

Author

Li, Jialiang, primary, Huang, Zitao, additional, Yu, Chunlin, additional, Wu, Jiajie, additional, Zhao, Tongge, additional, Zhu, Xiangwei, additional, and Sun, Shi-Hai, additional

Published

2024

7. An Unbiased Quantum Random Number Generator Based on Boson Sampling

Author

Shi, Jinjing, primary, Zhao, Tongge, additional, Wang, Yizhi, additional, Yu, Chunlin, additional, Lu, Yuhu, additional, Wu, JiaJie, additional, Shi, Ronghua, additional, Zhang, Shichao, additional, Peng, Shaoliang, additional, and Wu, Junjie, additional

Published

2023

8. An Unbiased Quantum Random Number Generator Based on Boson Sampling.

Author

Shi, Jinjing, Zhao, Tongge, Wang, Yizhi, Yu, Chunlin, Lu, Yuhu, Wu, JiaJie, Shi, Ronghua, Zhang, Shichao, Peng, Shaoliang, and Wu, Junjie

Subjects

RANDOM number generators, QUANTUM numbers, BOSONS, PHOTON counting, QUANTUM computing, QUANTUM computers

Abstract

It is proven that Boson sampling is a much promising model of optical quantum computation, which is applied to designing quantum computer successfully, such as "Jiuzhang". However, the meaningful randomness of Boson sampling results has not been utilized or exploited. In this research, Boson sampling is applied to design a quantum random number generator (QRNG) by fully exploiting the randomness of Boson sampling results, and its prototype system is constructed with the programmable silicon photonic processor, which can generate unbiased random sequences and overcome the shortcomings of the existing discrete QRNGs such as source‐restricted, high demand for the photon number resolution capability of detector and slow self‐detection generator speed. Boson sampling is implemented as a random entropy source, and random bit strings with satisfactory randomness and uniformity can be obtained after post‐processing the sampling results. It is the first approach for applying the randomness of Boson sampling results to develop a practical prototype system for actual tasks, and the experiment results demonstrate that the designed Boson sampling‐based QRNG prototype system passes 15 tests of the NIST SP 800‐22 statistical test component, which proves that Boson sampling has great potential for practical applications with desirable performance besides quantum advantage. [ABSTRACT FROM AUTHOR]

Published

2024

9. Chaotic Image Encryption Based on Boson Sampling

Author

Shi, Jinjing, primary, Zhao, Tongge, additional, Wang, Yizhi, additional, Feng, Yanyan, additional, and Wu, Junjie, additional

Published

2022

10. Chaotic Image Encryption Based on Boson Sampling.

Author

Shi, Jinjing, Zhao, Tongge, Wang, Yizhi, Feng, Yanyan, and Wu, Junjie

Subjects

IMAGE encryption, DISTRIBUTION (Probability theory), BOSONS, RANDOM numbers, ENTROPY (Information theory), NUMERICAL analysis

Abstract

As a fundamental form of information representation, image encryption is a significant research issue in the multimedia era. An image encryption scheme is proposed benefiting from chaotic random behavior characteristics of Boson sampling (BS) probability distribution, where the chaotic random number sequence is used to implement the encryption process including scrambling image pixels and altering the values of pixels. Further, a BS‐based image encryption prototype system is constructed on the programmable silicon photonic processor chip for BS with 5‐mode 2‐photon, which can encrypt 4 × 4 grayscale images. Besides, experiments for encrypting 256 × 256 gray‐scale images with 20‐mode 8‐photon BS are simulated on the StrawberryFields photonic quantum software platform. Numerical analyses demonstrate the proposed scheme has good effectiveness in terms of randomness test, information entropy, histogram, correlation, key space, key sensitivity, and anti‐attack, offering gains in many cryptographic applications. The BS‐based image encryption prototype system extends the application of BS to solve practical problems in addition to proving quantum advantages. [ABSTRACT FROM AUTHOR]

Published

2023