面向图数据的量子行走模型及算法研究进展

doi:10.3778/j.issn.1673-9418.2311087

摘要/Abstract

摘要： 作为量子计算的通用计算模型，量子行走广泛应用于安全通信、快速搜索、相似性计算以及图挖掘等领域。现阶段研究者对量子行走的设计思路、未来发展以及模型与算法间的相互关系关注甚少，忽略了量子行走的量子特性在图计算等应用中的理论优势。聚焦面向图数据的量子行走模型及算法，首先，分析量子行走的核心设计策略及其理论优势，归纳相关算法核心算符的构造形式与空间维度特征，厘清模型与算法间的逻辑联系；其次，依据离散时间和连续时间的分类，梳理不同图数据上量子行走模型的研究进展及设计难点，总结量子行走从规则图向不规则图上扩展的演化趋势；进一步，围绕图相似性计算、空间搜索以及图挖掘三项应用系统地介绍量子行走算法的研究进展，分析相关算法的技术特征、优势及不足；最后，从效率优化、精度提升、幺正约束以及图重构等角度，对面向图数据的量子行走模型与算法未来发展方向进行了展望。

关键词: 量子计算, 量子行走, 图结构数据, 离散时间, 连续时间, 图挖掘

Abstract: As a universal computational model in quantum computing, the quantum walk is employed in secure communication, quick query, similar calculation, graph mining, etc. At present, researchers have paid limited attention to the design, development, and relationship between models and algorithms of the quantum walk. Further, the theoreticals advantages of the quantum walk on graphs in graph computing are neglected. Aiming at the quantum walk model and algorithms for graph data, firstly, the core design strategy and theoretical advantages of quantum walks are analyzed, the construction form of significant operators and spatial dimension characteristics of relevant algorithms are summarized, and the logical relationship between model and algorithm is clarified. Secondly, according to the classification of discrete-time and continuous-time, the research advances and design difficulties of the quantum walk model are summarized, and the evolutionary trend of quantum walk extending from regular graphs to irregular graphs is concluded. Furthermore, around the similarity calculation of graphs, spatial search, and graph mining, the research progress of quantum walk algorithms is reviewed, and the technical characteristics, advantages and shortcomings of relevant algorithms are analyzed. Finally, from the perspectives of efficiency optimization, accuracy improvement, unitary constraints, and graph reconstruction, the future research directions of the quantum walk models and algorithms are prospected.

Key words: quantum computing, quantum walk, graph-structural data, discrete-time, continuous-time, graph mining

梁文, 张文波. 面向图数据的量子行走模型及算法研究进展[J]. 计算机科学与探索, 2024, 18(7): 1748-1761.

LIANG Wen, ZHANG Wenbo. Research Advances of Quantum Walk Models and Algorithms for Graph Data[J]. Journal of Frontiers of Computer Science and Technology, 2024, 18(7): 1748-1761.

参考文献

[1] YANG Z, ZOLANVARI M, JAIN R. A survey of important issues in quantum computing and communications[J]. IEEE Communications Surveys & Tutorials, 2023, 25(2): 1059-1094.
[2] DUAN B J, YUAN J B, YU C H, et al. A survey on HHL algorithm: from theory to application in quantum machine learning[J]. Physics Letters A, 2020, 384(24): 126595.
[3] KADIAN K, GARHWAL S, KUMAR A. Quantum walk and its application domains: a systematic review[J]. Computer Science Review, 2021, 41: 100419.
[4] 闫飞, 梁文, 董芳艳. 量子行走在复杂网络中的应用[M]. 北京: 科学出版社, 2023.
YAN F, LIANG W, DONG F Y. Applications of the quantum walk on complex networks[M]. Beijing: Science Press, 2023.
[5] YAN F, HUANG H S, YU X. A multiwatermarking scheme for verifying medical image integrity and authenticity in the Internet of medical things[J]. IEEE Transactions on Industrial Informatics, 2022, 18(12): 8885-8894.
[6] LIANG W, YAN F, ILIYASU A M, et al. A Hadamard walk model and its application in identification of important edges in complex networks[J]. Computer Communications, 2022, 193: 378-387.
[7] LIANG W, YAN F, ILIYASU A M, et al. A simplified quantum walk model for predicting missing links of complex networks[J]. Entropy, 2022, 24(11): 1547.
[8] LIANG W, YAN F, ILIYASU A M, et al. Three degrees of influence rule-based Grover walk model with application in identifying significant nodes of complex networks[J]. Human-Centric Computing and Information Sciences, 2023, 13(9): 1-16.
[9] XIE W, TAMON C. Optimality of spatial search in graphs with infinite tail[J]. Physical Review A, 2023, 107(3): 032416.
[10] CUI L, LI M, BAI L, et al. QBER: quantum-based entropic representations for un-attributed graphs[J]. Pattern Recognition, 2024, 145: 109877.
[11] VENEGAS-ANDRACA S E. Quantum walks: a comprehensive review[J]. Quantum Information Processing, 2012, 11(5): 1015-1106.
[12] XIA F, LIU J, NIE H, et al. Random walks: a review of algorithms and applications[J]. IEEE Transactions on Emerging Topics in Computational Intelligence, 2020, 4(2): 95-107.
[13] ZHOU W. Review on quantum walk algorithm[J]. Journal of Physics: Conference Series, 2021, 1748(3): 032022.
[14] AHARONOV Y, DAVIDOVICH L, ZAGURY N. Quantum random walks[J]. Physical Review A, 1993, 48(2): 1687.
[15] FALCAO P R N, MENDON?A J P, BUARQUE A R C, et al. Nonlinear three-state quantum walks[J]. Physical Review A, 2022, 106(4): 042202.
[16] PORTUGAL R. Quantum walks and search algorithms[M]. Berlin, Heidelberg: Springer, 2018.
[17] HE Z M, HUANG Z M, LI L Z, et al. Coherence evolution in two-dimensional quantum walk on lattice[J]. International Journal of Quantum Information, 2018, 16(2): 1850011.
[18] SHANG Y, WANG Y, LI M, et al. Quantum communication protocols by quantum walks with two coins[J]. Europhysics Letters, 2019, 124(6): 60009.
[19] SAHA A, MANDAL S B, SAHA D, et al. One-dimensional lazy quantum walk in ternary system[J]. IEEE Transactions on Quantum Engineering, 2021, 2: 1-12.
[20] BERRY S D, WANG J B. Two-particle quantum walks: entanglement and graph isomorphism testing[J]. Physical Review A, 2011, 83(4): 042317.
[21] 冯艳艳, 施荣华, 石金晶, 等. 基于量子游走的仲裁量子签名方案[J]. 物理学报, 2019, 68(12): 68-76.
FENG Y Y, SHI R H, SHI J J, et al. Arbitrated quantum signature scheme based on quantum walks[J]. Acta Physica Sinica, 2019, 68(12): 68-76.
[22] CHO B, XIAO Y, HUI P, et al. Quantum bandit with amplitude amplification exploration in an adversarial environment[J]. IEEE Transactions on Knowledge and Data Engineering, 2024, 36(1): 311-317.
[23] CARETTE T, LAURIèRE M, MAGNIEZ F. Extended learning graphs for triangle finding[J]. Algorithmica, 2020, 82(4): 980-1005.
[24] BAI L, JIAO Y H, CUI L X, et al. Learning graph convolutional networks based on quantum vertex information propagation[J]. IEEE Transactions on Knowledge and Data Engineering, 2021, 35(2): 1747-1760.
[25] 胡钢, 卢志宇, 王乐萌, 等. 基于复杂网络多阶邻域贡献度的节点重要性序结构辨识[J]. 电子学报, 2023, 51(7): 1956-1963.
HU G, LU Z Y, WANG L M, et al. Identification of node importance order structure based on multi-order neighborhood contribution of complex network[J]. Acta Electronica Sinica, 2023, 51(7): 1956-1963.
[26] MUKHAMEDOV F, SOUISSI A, HAMDI T, et al. Open quantum random walks and quantum Markov chains on trees II: the recurrence[J]. Quantum Information Processing, 2023, 22(6): 232.
[27] HAO W, ZHANG T, CHEN X, et al. A hybrid NEQR image encryption cryptosystem using two-dimensional quantum walks and quantum coding[J]. Signal Processing, 2023, 205: 108890.
[28] ORTEGA S A, MARTIN-DELGADO M A. Generalized quantum PageRank algorithm with arbitrary phase rotations[J]. Physical Review Research, 2023, 5(1): 013061.
[29] MUKAI K, HATANO N. Discrete-time quantum walk on complex networks for community detection[J]. Physical Review Research, 2020, 2(2): 023378.
[30] WANG K K, SHI Y H, XIAO L, et al. Experimental realization of continuous-time quantum walks on directed graphs and their application in PageRank[J]. Optica, 2020, 7(11): 1524-1530.
[31] WU T, IZAAC J, LI Z X, et al. Experimental parity-time symmetric quantum walks for centrality ranking on directed graphs[J]. Physical Review Letters, 2020, 125(24): 240501.
[32] CARSON G R, LOKE T, WANG J B. Entanglement dynamics of two-particle quantum walks[J]. Quantum Information Processing, 2015, 14(9): 3193-3210.
[33] 李萌, 孙晓明. 量子游走相关算法研究进展[J]. 信息通信技术与政策, 2022, 337(7): 28-36.
LI M, SUN X M. Research progress on quantum walk related algorithms[J]. Information and Communications Technology and Policy, 2022, 337(7): 28-36.
[34] LIU K, ZHANG Y, LU K, et al. MapEff: an effective graph isomorphism algorithm based on the discrete-time quantum walk[J]. Entropy, 2019, 21(6): 569.
[35] SCHOFIELD C, WANG J B, LI Y Y. Quantum walk inspired algorithm for graph similarity and isomorphism[J]. Quantum Information Processing, 2020, 19(9): 1-19.
[36] ZHANG Y, WANG L L, WILSON R C, et al. An R-convolution graph kernel based on fast discrete-time quantum walk[J]. IEEE Transactions on Neural Networks and Learning Systems, 2022, 33(1): 292-303.
[37] WANG X, LU K, ZHANG Y, et al. QSIM: a novel approach to node proximity estimation based on discrete-time quantum walk[J]. Applied Intelligence, 2021, 51(4): 2574-2588.
[38] 王兆慧, 沈华伟, 曹婍, 等. 图分类研究综述[J]. 软件学报, 2022, 33(1): 171-192.
WANG Z H, SHEN H W, CAO Q, et al. Survey on graph classification[J]. Journal of Software, 2022, 33(1): 171-192.
[39] DERNBACH S, MOHSENI-KABIR A, PAL S, et al. Quantum walk neural networks with feature dependent coins[J]. Applied Network Science, 2019, 4(1): 1-16.
[40] BAI L, ROSSI L, CUI L, et al. A quantum-inspired similarity measure for the analysis of complete weighted graphs[J]. IEEE Transactions on Cybernetics, 2020, 50(3): 1264-1277.
[41] DOUGLAS B L, WANG J B. A classical approach to the graph isomorphism problem using quantum walks[J]. Journal of Physics A: Mathematical and Theoretical, 2008, 41(7): 075303.
[42] WANG X, JIAN S L, LU K, et al. RED: learning the role embedding in networks via discrete-time quantum walk[J]. Applied Intelligence, 2022, 52(2): 1493-1507.
[43] CHILDS A M, GOLDSTONE J. Spatial search by quantum walk[J]. Physical Review A, 2004, 70(2): 022314.
[44] OSADA T, COUTINHO B, OMAR Y, et al. Continuous-time quantum-walk spatial search on the Bollobás scale-free network[J]. Physical Review A, 2020, 101(2): 022310.
[45] LI M, SHANG Y. Generalized exceptional quantum walk search[J]. New Journal of Physics, 2020, 22(12): 123030.
[46] CHAKRABORTY S, NOVO L, ROLAND J. Optimality of spatial search via continuous-time quantum walks[J]. Physical Review A, 2020, 102(3): 032214.
[47] CHAKRABORTY S, NOVO L, ROLAND J. Finding a marked node on any graph via continuous-time quantum walks[J]. Physical Review A, 2020, 102(2): 022227.
[48] APERS S, CHAKRABORTY S, NOVO L, et al. Quadratic speedup for spatial search by continuous-time quantum walk[J]. Physical Review Letters, 2022, 129(16): 160502.
[49] MAGNIEZ F, NAYAK A, ROLAND J, et al. Search via quantum walk[J]. SIAM Journal on Computing, 2011, 40(1): 142-164.
[50] AMBAINIS A. Quantum walk algorithm for element distinctness[C]//Proceedings of the 45th Annual IEEE Symposium on Foundations of Computer Science, Rome, Oct 17-19, 2014. Washington: IEEE Computer Society, 2014: 22-31.
[51] MAGNIEZ F, NAYAK A, RICHTER P C, et al. On the hitting times of quantum versus random walks[J]. Algorithmica, 2012, 63(1): 91-116.
[52] BUN M, KOTHARI R, THALER J. The polynomial method strikes back: tight quantum query bounds via dual polynomials[C]//Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing, Los Angeles, Jun 25-29, 2018. New York: ACM, 2018: 297-310.
[53] PAPARO G D, MüLLER M, COMELLAS F, et al. Quantum Google in a complex network[J]. Scientific Reports, 2013, 3(1): 2773.
[54] IZAAC J A, ZHAN X, BIAN Z H, et al. Centrality measure based on continuous-time quantum walks and experimental realization[J]. Physical Review A, 2017, 95(3): 032318.
[55] CHAWLA P, MANGAL R, CHANDRASHEKAR C M. Discrete-time quantum walk algorithm for ranking nodes on a network[J]. Quantum Information Processing, 2020, 19(5): 1-21.
[56] BOITO P, GRENA R. Ranking nodes in directed networks via continuous-time quantum walks[J]. Quantum Information Processing, 2023, 22(6): 246.
[57] B?TTCHER L, PORTER M A. Classical and quantum random-walk centrality measures in multilayer networks[J]. SIAM Journal on Applied Mathematics, 2021, 81(6): 2704-2724.
[58] WANG Y, XUE S, WU J, et al. Continuous-time quantum walk based centrality testing on weighted graphs[J]. Scientific Reports, 2022, 12(1): 6001.
[59] 赵国涛, 王立夫, 关博飞. 一类影响网络能控性的边集研究[J]. 物理学报, 2021, 70(14): 379-393.
ZHAO G T, WANG L F, GUAN B F. A class of edge set affecting network controllability[J]. Acta Physica Sinica, 2021, 70(14): 379-393.
[60] LOCKHART J, MINELLO G, ROSSI L, et al. Edge centrality via the Holevo quantity[C]//Proceedings of the 11th Joint IAPR International Workshops on Statistical Techniques in Pattern Recognition and Structural and Syntactic Pattern Recognition, Mérida, Nov 30-Dec 2, 2016. Cham: Springer, 2016: 143-152.
[61] KUMAR M, MISHRA S, BISWAS B. PQKLP: projected quantum kernel based link prediction in dynamic networks[J]. Computer Communications, 2022, 196: 249-267.
[62] MOUTINHO J P, MELO A, COUTINHO B, et al. Quantum link prediction in complex networks[J]. Physical Review A, 2023, 107(3): 032605.
[63] FACCIN M, MIGDA? P, JOHNSON T H, et al. Community detection in quantum complex networks[J]. Physical Review X, 2014, 4(4): 041012.
[64] 梁文, 闫飞, 陈柏圳. 两阶段量子行走算法在社区检测中的应用[J]. 计算机应用研究, 2023, 40(9): 2329-2333.
LIANG W, YAN F, CHEN B Z. Two-stage quantum walk algorithm with application to community detection[J]. Application Research of Computers, 2023, 40(9): 2329-2333.
[65] TANG H, SHI R X, HE T S, et al. TensorFlow solver for quantum PageRank in large-scale networks[J]. Science Bulletin, 2021, 66(2): 120-126.