Means of Hitting Times for Random Walks on Graphs: Connections, Computation, and Optimization

被引：0

作者：

Xia, Haisong ^{[1
]}

Xu, Wanyue ^{[1
]}

Zhang, Zuobai ^{[1
]}

Zhang, Zhongzhi ^{[1
,2
,3
]}

机构：

[1] Fudan Univ, Sch Comp Sci, Shanghai Key Lab Intelligent Informat Proc, Shanghai, Peoples R China

[2] Fudan Univ, Shanghai Engn Res Inst Blockchains, Shanghai, Peoples R China

[3] Fudan Univ, Res Inst Intelligent Complex Syst, Shanghai, Peoples R China

来源：

ACM TRANSACTIONS ON KNOWLEDGE DISCOVERY FROM DATA | 2025年 / 19卷 / 02期

基金：

中国国家自然科学基金;

关键词：

Random walk; hitting time; Kemeny constant; spectral algorithm; complex network; optimization; vertex centrality; COMPLETE BINARY-TREES; 1ST-PASSAGE TIMES; KEMENYS CONSTANT; ALGORITHMS; CENTRALITY; RESISTANCE; LAPLACIAN; NETWORKS; DYNAMICS; NUMBER;

D O I：

10.1145/3708561

中图分类号：

TP [自动化技术、计算机技术];

学科分类号：

0812 ;

摘要：

For random walks on graph G with n vertices and m edges, the mean hitting time H-j from a vertex chosen from the stationary distribution to vertex j measures the importance for j, while the Kemeny constant K is the mean hitting time from one vertex to another selected randomly according to the stationary distribution. In this article, we first establish a connection between the two quantities, representing K in terms of H-j for all vertices. We then develop an efficient algorithm estimating H-j for all vertices and K in nearly linear time of m. Moreover, we extend the centrality H-j of a single vertex to H(S) of a vertex set S, and establish a link between H(S) and some other quantities. We further study the NP-hard problem of selecting a group S of k << n vertices with minimum H(S), whose objective function is monotonic and supermodular. We finally propose two greedy algorithms approximately solving the problem. The former has an approximation factor (1-k/k-1 1/e) and O(kn(3)) running time, while the latter returns a (1-k/k-1 1/e-& varepsilon;)-approximation solution in nearly-linear time of m, for any parameter 0<& varepsilon;<1. Extensive experiment results validate the performance of our algorithms.

引用

页数：35

共 98 条

[41] Hunter J.J., The role of Kemeny’s constant in properties of Markov chains, Commun. Stat. Theor. Methods, 43, 7, pp. 1309-1321, (2014)
[42] Jadbabaie A., Olshevsky A., Scaling Laws for consensus protocols subject to noise, IEEE Trans. Autom. Control., 64, 4, pp. 1389-1402, (2019)
[43] Johnson J., Ng Y.-K., Enhancing long tail item recommendations using tripartite graphs and Markov process, Proc. Int. Conf. Web Intell., pp. 761-768, (2017)
[44] Julaiti A., Wu B., Zhang Z., Eigenvalues of normalized laplacian matrices of fractal trees and dendrimers: Analytical results and applications, J. Chem. Phys., 138, 20, (2013)
[45] Klavzar S., Mohar B., Crossing numbers of Sierpiński-like graphs, J. Graph Theory, 50, 3, pp. 186-198, (2005)
[46] Klein D.J., Randic M., Resistance distance, J. Math. Chem., 12, 1, pp. 81-95, (1993)
[47] Koutis I., Miller G.L., Peng R., A nearly-M log n time solver for SDD linear systems, Proc. IEEE 52nd Ann. Symp. Found. Comput. Sci. IEEE, pp. 590-598, (2011)
[48] Krause A., Singh A., Guestrin C., Near-optimal sensor placements in gaussian processes: Theory, efficient algorithms and empirical studies, J. Mach. Learn. Res., 9, pp. 235-284, (2008)
[49] Kunegis J., KONECT: The Koblenz network collection, Proc. Int. Conf. World Wide Web, pp. 1343-1350, (2013)
[50] Kyng R., Sachdeva S., Approximate Gaussian elimination for laplacians-fast, sparse, and simple, Proc. IEEE 57th Ann. Symp. Found. Comput. Sci. IEEE, pp. 573-582, (2016)

← 1 2 3 4 5 6 7 8 9 10 →