Modularity and Dynamics on Complex Networks

Renaud Lambiotte; Michael T. Schaub

doi:10.1017/9781108774116

Series: Elements in the Structure and Dynamics of Complex Networks

Modularity and Dynamics on Complex Networks

Published online by Cambridge University Press: 21 December 2021

Renaud Lambiotte and

Michael T. Schaub

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Renaud Lambiotte: Affiliation:
University of Oxford
Michael T. Schaub: Affiliation:
RWTH Aachen University, Germany

Summary

Complex networks are typically not homogeneous, as they tend to display an array of structures at different scales. A feature that has attracted a lot of research is their modular organisation, i.e., networks may often be considered as being composed of certain building blocks, or modules. In this Element, the authors discuss a number of ways in which this idea of modularity can be conceptualised, focusing specifically on the interplay between modular network structure and dynamics taking place on a network. They discuss, in particular, how modular structure and symmetries may impact on network dynamics and, vice versa, how observations of such dynamics may be used to infer the modular structure. They also revisit several other notions of modularity that have been proposed for complex networks and show how these can be related to and interpreted from the point of view of dynamical processes on networks.

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Keywords

modularity networks time scale dynamics block models

Type: Element
Information: Series: Elements in the Structure and Dynamics of Complex Networks

DOI: https://doi.org/10.1017/9781108774116 [Opens in a new window]

Online ISBN: 9781108774116

Publisher: Cambridge University Press

Print publication: 03 February 2022

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References

Abbe, E. (2017). Community detection and stochastic block models: recent developments. The Journal of Machine Learning Research, 18 (1), 6446–6531.Google Scholar

Abrams, D. M., Mirollo, R., Strogatz, S. H., & Wiley, D. A. (2008). Solvable model for chimera states of coupled oscillators. Physical Review Letters, 101 (8),084103.Google Scholar

Ahn, Y.-Y., Bagrow, J. P., & Lehmann, S. (2010). Link communities reveal multiscale complexity in networks. Nature, 466 (7307), 761–764.Google Scholar

Almquist, Z. W. (2012, October). Random errors in egocentric networks. Social Networks, 34(4), 493–505. doi: https://doi.org/10.1016/j.socnet.2012.03.002 Google Scholar

Alpert, C. J., & Kahng, A. B. (1995). Recent directions in netlist partitioning: a survey. Integration, 19(1–2), 1–81.Google Scholar

Altafini, C. (2012). Dynamics of opinion forming in structurally balanced social networks. PloS One, 7(6), e38135.Google Scholar

Altafini, C. (2013, April). Consensus problems on networks with antagonistic interactions. IEEE Transactions on Automatic Control, 58(4), 935–946. doi: https://doi.org/10.1109/TAC.2012.2224251 Google Scholar

Arenas, A., Díaz-Guilera, A., Kurths, J., Moreno, Y., & Zhou, C. (2008). Synchronization in complex networks. Physics Reports, 469 (3), 93–153.Google Scholar

Arenas, A., Díaz-Guilera, A., & Pérez-Vicente, C. J. (2006). Synchronization reveals topological scales in complex networks. Physical Review Letters, 96 (11),114102.Google Scholar

Asllani, M., Lambiotte, R., & Carletti, T. (2018). Structure and dynamical behavior of non-normal networks. Science Advances, 4(12),eaau9403.Google Scholar

Avella-Medina, M., Parise, F., Schaub, M. T., & Segarra, S. (2020). Centrality measures for graphons: accounting for uncertainty in networks. IEEE Transactions on Network Science and Engineering, 7 (1), 520–537. doi: https://doi.org/10.1109/TNSE.2018.2884235 Google Scholar

Aynaud, T., Blondel, V. D., Guillaume, J. L., & Lambiotte, R. (2013). Multilevel local optimization of modularity. In: Bichot, C.-E., Siarry, P. (eds.), Graph Partitioning, (pp. 315–345). John Wiley and Sons, Hoboken, NJ.Google Scholar

Banisch, R., & Conrad, N. D. (2015). Cycle-flow–based module detection in directed recurrence networks. EPL (Europhysics Letters), 108 (6), 68008.Google Scholar

Barabási, A.-L., et al. (2016). Network science. Cambridge University Press, Cambridge, UK.Google Scholar

Barbarossa, S., & Sardellitti, S. (2020). Topological signal processing: making sense of data building on multiway relations. IEEE Signal Processing Magazine, 37 (6), 174–183.Google Scholar

Battiston, F., Cencetti, G., Iacopini, I. et al. (2020). Networks beyond pairwise interactions: structure and dynamics. Physics Reports, 874, 1–92.Google Scholar

Belkin, M., & Niyogi, P. (2001). Laplacian eigenmaps and spectral techniques for embedding and clustering. Advances in Neural Information Processing Systems, 14, 585–591.Google Scholar

Bhatia, R. (2013). Matrix analysis (vol. 169). Springer Science & Business Media, London.Google Scholar

Blondel, V. D., Gajardo, A., Heymans, M., Senellart, P., & Van Dooren, P. (2004). A measure of similarity between graph vertices: applications to synonym extraction and web searching. SIAM Review, 46 (4), 647–666.Google Scholar

Blondel, V. D., Guillaume, J.-L., Lambiotte, R., & Lefebvre, E. (2008). Fast unfolding of communities in large networks. Journal of Statistical Mechanics: Theory and Experiment, 2008 (10),P10008.Google Scholar

Bohlin, L., Edler, D., Lancichinetti, A., & Rosvall, M. (2014). Community detection and visualization of networks with the map equation framework. In: Ding, Y., Rousseau, R., & Wolfram, D. (eds.), Measuring scholarly impact, (pp. 3–34). Springer, New York.Google Scholar

Borgatti, S. P., Carley, K. M., & Krackhardt, D. (2006). On the robustness of centrality measures under conditions of imperfect data. Social Networks, 28(2), 124–136. doi: https://doi.org/10.1016/j.socnet.2005.05.001 Google Scholar

Brandes, U. (2005). Network analysis: methodological foundations, (vol. 3418). Springer Science & Business Media, London.Google Scholar

Brandes, U., Delling, D., Gaertler, M. et al. (2007). On modularity clustering. IEEE Transactions on Knowledge and Data Engineering, 20(2), 172–188.Google Scholar

Brin, S., & Page, L. (1998). The anatomy of a large-scale hypertextual web search engine. Computer Networks and ISDN Systems, 30(1–7), 107–117.Google Scholar

Broido, A. D., & Clauset, A. (2019). Scale-free networks are rare. Nature Communications, 10 (1), 1–10.Google Scholar

Bui-Xuan, B.-M., & Jones, N. S. (2014). How modular structure can simplify tasks on networks: parameterizing graph optimization by fast local community detection. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 470 (2170),20140224.Google Scholar

Bullo, F. (2019). Lectures on network systems. Kindle Direct Publishing. ISBN 978-1-986425-64-3.Google Scholar

Burt, R. S. (2004). Structural holes and good ideas. American Journal of Sociology, 110 (2), 349–399.Google Scholar

Cardoso, D. M., Delorme, C., & Rama, P. (2007). Laplacian eigenvectors and eigenvalues and almost equitable partitions. European Journal of Combinatorics, 28 (3), 665–673.Google Scholar

Carletti, T., Fanelli, D., & Lambiotte, R. (2020). Random walks and community detection in hypergraphs. arXiv preprint arXiv:2010.14355.Google Scholar

Cason, T. P. (2014). Role extraction in networks. (unpublished doctoral dissertation). Catholic University of Louvain.Google Scholar

Cavallari, S., Zheng, V. W., Cai, H., Chang, K. C.-C., & Cambria, E. (2017). Learning community embedding with community detection and node embedding on graphs. In Proceedings of the 2017 ACM on Conference on Information and Knowledge Management, (pp. 377–386).Google Scholar

Chan, A., & Godsil, C. D. (1997). Symmetry and eigenvectors. In: Hahn, G., & Sabidussi, G. (eds.), Graph Symmetry, (pp. 75–106). Springer, New York.Google Scholar

Chandra, A. K., Raghavan, P., Ruzzo, W. L., Smolensky, R., & Tiwari, P. (1996). The electrical resistance of a graph captures its commute and cover times. Computational Complexity, 6 (4), 312–340.Google Scholar

Chodrow, P. S., Veldt, N., & Benson, A. R. (2021). Hypergraph clustering: from blockmodels to modularity. arXiv preprint arXiv:2101.09611.Google Scholar

Chung, F., & Lu, L. (2002). Connected components in random graphs with given expected degree sequences. Annals of Combinatorics, 6 (2), 125–145.Google Scholar

Chung, F. R. (1997). Spectral graph theory, (vol. 92). American Mathematical Society, Providence, RI.Google Scholar

Coifman, R. R., Lafon, S., Lee, A. B. et al. (2005). Geometric diffusions as a tool for harmonic analysis and structure definition of data: diffusion maps. Proceedings of the National Academy of Sciences of the United States of America, 102 (21), 7426–7431.CrossRef Google Scholar PubMed

Conrad, N. D., Weber, M., & Schütte, C. (2016). Finding dominant structures of nonreversible Markov processes. Multiscale Modeling & Simulation, 14 (4), 1319–1340.Google Scholar

Cooper, K., & Barahona, M. (2010). Role-based similarity in directed networks. arXiv preprint arXiv:1012.2726.Google Scholar

Dasgupta, A., Hopcroft, J. E., & McSherry, F. (2004). Spectral analysis of random graphs with skewed degree distributions. In 45th Annual IEEE Symposium on Foundations of Computer Science, (pp. 602–610). doi: https://doi.org/10.1109/FOCS.2004.61.Google Scholar

De Domenico, M., Solé-Ribalta, A., Cozzo, E. et al. (2013). Mathematical formulation of multilayer networks. Physical Review X, 3 (4),041022.Google Scholar

Delvenne, J.-C., & Libert, A.-S. (2011). Centrality measures and thermodynamic formalism for complex networks. Physical Review E, 83(4), 046117.Google Scholar

Delvenne, J.-C., Schaub, M. T., Yaliraki, S. N., & Barahona, M. (2013). The stability of a graph partition: a dynamics-based framework for community detection. In A. Mukherjee, M. Choudhury, F. Peruani, N. Ganguly, & B. Mitra (eds.), Dynamics On and Of Complex Networks, Volume 2 (pp. 221–242). Springer, New York. doi: https://doi.org/10.1007/978-1-4614-6729-8_11 CrossRef Google Scholar

Delvenne, J.-C., Yaliraki, S. N., & Barahona, M. (2010). Stability of graph communities across time scales. Proceedings of the National Academy of Sciences, 107 (29),12755–12760. doi: https://doi.org/10.1073/pnas.0903215107 Google Scholar

Derrida, B., & Flyvbjerg, H. (1986). Multivalley structure in Kauffman’s model: analogy with spin glasses. Journal of Physics A: Mathematical and General, 19 (16),L1003.Google Scholar

Devriendt, K. (2020). Effective resistance is more than distance: Laplacians, simplices and the Schur complement. arXiv preprint arXiv:2010.04521.Google Scholar

Doreian, P., Batagelj, V., & Ferligoj, A. (2020). Advances in Network Clustering and Blockmodeling. John Wiley & Hoboken, NJ.Google Scholar

Egerstedt, M., Martini, S., Cao, M., Camlibel, K., & Bicchi, A. (2012). Interacting with networks: how does structure relate to controllability in single-leader, consensus networks? Control Systems, IEEE, 32 (4),66–73. doi: https://doi.org/10.1109/MCS.2012.2195411 Google Scholar

Eriksson, A., Edler, D., Rojas, A., & Rosvall, M. (2020). Mapping flows on hypergraphs. arXiv preprint arXiv:2101.00656.Google Scholar

Eriksson, A., Edler, D., Rojas, A., & Rosvall, M. (2021). Mapping flows on hypergraphs. arXiv preprint arXiv:2101.00656.Google Scholar

Estrada, E., & Hatano, N. (2008). Communicability in complex networks. Physical Review E, 77 (3),036111.Google Scholar

Everett, M. G., & Borgatti, S. P. (1994). Regular equivalence: general theory. Journal of Mathematical Sociology, 19 (1), 29–52.Google Scholar

Expert, P., Evans, T. S., Blondel, V. D., & Lambiotte, R. (2011). Uncovering space-independent communities in spatial networks. Proceedings of the National Academy of Sciences, 108 (19), 7663–7668.CrossRef Google Scholar PubMed

Faccin, M., Schaub, M. T., & Delvenne, J.-C. (2018). Entrograms and coarse graining of dynamics on complex networks. Journal of Complex Networks, 6 (5), 661–678.CrossRef Google Scholar

Faccin, M., Schaub, M. T., & Delvenne, J.-C. (2020). State aggregations in Markov chains and block models of networks. arXiv preprint arXiv:2005.00337.Google Scholar

Faqeeh, A., Osat, S., & Radicchi, F. (2018). Characterizing the analogy between hyperbolic embedding and community structure of complex networks. Physical Review Letters, 121(9), 098301.Google Scholar

Fiedler, M. (1973). Algebraic connectivity of graphs. Czechoslovak Mathematical Journal, 23(2), 298–305.CrossRef Google Scholar

Fiedler, M. (2011). Matrices and Graphs in Geometry. Cambridge University Press, Cambridge, UK. doi: https://doi.org/10.1017/cbo9780511973611 CrossRef Google Scholar

Fortunato, S. (2010). Community detection in graphs. Physics Reports, 486(3–5), 75–174. doi: https://doi.org/10.1016/j.physrep.2009.11.002 Google Scholar

Fortunato, S., & Barthelemy, M. (2007). Resolution limit in community detection. Proceedings of the National Academy of Sciences, 104(1),36–41.Google Scholar

Fortunato, S., & Hric, D. (2016). Community detection in networks: a user guide. Physics Reports, 659, 1–44.CrossRef Google Scholar

Fosdick, B. K., Larremore, D. B., Nishimura, J., & Ugander, J. (2018). Configuring random graph models with fixed degree sequences. SIAM Review, 60 (2), 315–355.Google Scholar

Fouss, F., Saerens, M., & Shimbo, M. (2016). Algorithms and models for network data and link analysis. Cambridge University Press, Cambridge, UK.Google Scholar

Ghasemian, A., Hosseinmardi, H., & Clauset, A. (2019). Evaluating overfit and underfit in models of network community structure. IEEE Transactions on Knowledge and Data Engineering, 32(9), 1722–1735. doi: https://doi.org/10.1109/TKDE.2019.2911585.Google Scholar

Gleich, D. F. (2015). Pagerank beyond the web. SIAM Review, 57 (3), 321–363.Google Scholar

Godsil, C., & Royle, G. F. (2013). Algebraic graph theory (vol. 207). Springer Science & Business Media, London.Google Scholar

Golub, G., & Van Loan, C. (2013). Matrix computations. 4th ed. Johns Hopkins. University Press, Baltimore, MD.Google Scholar

Golubitsky, M., & Stewart, I. (2006). Nonlinear dynamics of networks: the groupoid formalism. Bulletin of the American Mathematical Society, 43 (3), 305–364.CrossRef Google Scholar

Golubitsky, M., & Stewart, I. (2015). Recent advances in symmetric and network dynamics. Chaos: An Interdisciplinary Journal of Nonlinear Science, 25(9),097612.Google Scholar

Good, B. H., De Montjoye, Y.-A., & Clauset, A. (2010). Performance of modularity maximization in practical contexts. Physical Review E, 81 (4),046106.Google Scholar

Grohe, M., Kersting, K., Mladenov, M., & Selman, E. (2014). Dimension reduction via colour refinement. In European Symposium on Algorithms, (pp. 505–516). Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-44777-2_42 Google Scholar

Grohe, M., & Schweitzer, P. (2020). The graph isomorphism problem. Communications of the ACM, 63 (11), 128–134.Google Scholar

Grover, A., & Leskovec, J. (2016). node2vec: Scalable feature learning for networks. In Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, (pp. 855–864).Google Scholar

Gvishiani, A. D., & Gurvich, V. A. (1987). Metric and ultrametric spaces of resistances. Uspekhi Matematicheskikh Nauk, 42 (6), 187–188.Google Scholar

Hage, P., Harary, F., & Harary, F. (1983). Structural models in anthropology. Cambridge Studies in Anthropology, Social. No. 46. Cambridge University Press, Cambridge, UK.Google Scholar

Higham, N. J. (2008). Functions of matrices: theory and computation. SIAM.Google Scholar

Holland, P. W., Laskey, K. B., & Leinhardt, S. (1983). Stochastic blockmodels: first steps. Social Networks, 5 (2), 109–137.CrossRef Google Scholar

Holland, P. W., & Leinhardt, S. (1973). The structural implications of measurement error in sociometry. Journal of Mathematical Sociology, 3 (1), 85–111.Google Scholar

Holme, P., & Saramäki, J. (2019). Temporal Network Theory. Springer.Google Scholar

Karrer, B., & Newman, M. E. J. (2011). Stochastic blockmodels and community structure in networks. Physical Review E, 83(1), 016107. doi: https://doi.org/10.1103/PhysRevE.83.016107 Google Scholar

Kivela, M., Arenas, A., Barthelemy, M. et al. (2014). Multilayer networks. Journal of Complex Networks, 2 (3),203–271. doi: https://doi.org/10.1093/comnet/cnu016 Google Scholar

Klein, D. J., & Randić, M. (1993). Resistance distance. Journal of Mathematical Chemistry, 12 (1), 81–95. doi: https://doi.org/10.1007%2Fbf01164627 Google Scholar

Klimm, F., Jones, N. S., & Schaub, M. T. (2021). Modularity maximisation for graphons. arXiv preprint arXiv:2101.00503.Google Scholar

Kloumann, I. M., Ugander, J., & Kleinberg, J. (2017). Block models and personalized pagerank. Proceedings of the National Academy of Sciences, 114 (1), 33–38.Google Scholar

Komarek, A., Pavlik, J., & Sobeslav, V. (2015). Network visualization survey. In Computational Collective Intelligence, (pp. 275–284). Springer.CrossRef Google Scholar

Kondor, R., & Lafferty, J. (2002). Diffusion kernels on graphs and other discrete input spaces. In Proceedings of the ICML’02: Nineteenth International Joint Conference on Machine Learning, (pp. 315–322).Google Scholar

Kossinets, G. (2006). Effects of missing data in social networks. Social Networks, 28(3),247–268. Accessed 1 October 2020 from https://linkinghub.elsevier.com/retrieve/pii/S0378873305000511 doi: https://doi.org/10.1016/j.socnet.2005.07.002 Google Scholar

Krzakala, F., Moore, C., Mossel, E. et al. (2013). Spectral redemption in clustering sparse networks. Proceedings of the National Academy of Sciences, 110 (52), 20935–20940.Google Scholar

Kunegis, J., Schmidt, S., Lommatzsch, A. et al. (2010). Spectral analysis of signed graphs for clustering, prediction and visualization. In Proceedings of the 2010 SIAM International Conference on Data Mining (SDM) (vol. 10, pp. 559–570). Society for Industrial and Applied Mathematics.Google Scholar

Lafon, S., & Lee, A. (2006). Diffusion maps and coarse-graining: a unified framework for dimensionality reduction, graph partitioning, and data set parameterization. Pattern Analysis and Machine Intelligence, IEEE Transactions on, 28(9), 1393–1403. doi: https://doi.org/10.1109/TPAMI.2006.184 CrossRef Google Scholar PubMed

Lambiotte, R., Ausloos, M., & Holyst, J. (2007). Majority model on a network with communities. Physical Review E, 75 (3),030101.Google Scholar

Lambiotte, R., Delvenne, J.-C., & Barahona, M. (2014). Random walks, Markov processes and the multiscale modular organization of complex networks. IEEE Transactions on Network Science and Engineering, 1(2), 76–90. doi: https://doi.org/10.1109/TNSE.2015.2391998 Google Scholar

Lambiotte, R., & Rosvall, M. (2012). Ranking and clustering of nodes in networks with smart teleportation. Physical Review E, 85 (5),056107.Google Scholar

Lambiotte, R., Rosvall, M., & Scholtes, I. (2019). From networks to optimal higher-order models of complex systems. Nature Physics, 15(4), 313–320.Google Scholar

Langville, A. N., & Meyer, C. D. (2011). Google’s PageRank and beyond: the science of search engine rankings. Princeton University Press.Google Scholar

Le, C. M., Levina, E., & Vershynin, R. (2017). Concentration and regularization of random graphs. Random Structures & Algorithms, 51 (3), 538–561.Google Scholar

Lei, J., & Rinaldo, A. (2015). Consistency of spectral clustering in stochastic block models. The Annals of Statistics, 43 (1), 215–237.CrossRef Google Scholar

Leskovec, J., Lang, K. J., Dasgupta, A., & Mahoney, M. W. (2008). Statistical properties of community structure in large social and information networks. In Proceedings of the 17th International Conference on World Wide Web (pp. 695–704).Google Scholar

Lorrain, F., & White, H. C. (1971). Structural equivalence of individuals in social networks. The Journal of Mathematical Sociology, 1 (1), 49–80.Google Scholar

Malliaros, F. D., & Vazirgiannis, M. (2013). Clustering and community detection in directed networks: a survey. Physics Reports, 533 (4), 95–142.Google Scholar

Martin, T., Ball, B., & Newman, M. E. J. (2016). Structural inference for uncertain networks. Physical Review E, 93 (1),012306.Google Scholar

Masuda, N., & Lambiotte, R. (2020). A guide To Temporal Networks (vol. 6). World Scientific.Google Scholar

Masuda, N., Porter, M. A., & Lambiotte, R. (2017). Random walks and diffusion on networks. Physics Reports, 716, 1–58.Google Scholar

Mauroy, A., Susuki, Y., & Mezić, I. (2020). The Koopman Operator in Systems and Control. Springer.Google Scholar

McPherson, M., Smith-Lovin, L., & Cook, J. M. (2001). Birds of a feather: homophily in social networks. Annual Review of Sociology, 27(1), 415–444.Google Scholar

Meilǎ, M. (2007). Comparing clusterings – an information based distance. Journal of Multivariate Analysis, 98 (5), 873–895.Google Scholar

Menczer, F., Fortunato, S., & Davis, C. A. (2020). A First Course in Network Science. Cambridge University Press.Google Scholar

Meunier, D., Lambiotte, R., & Bullmore, E. T. (2010). Modular and hierarchically modular organization of brain networks. Frontiers in Neuroscience, 4, 200.CrossRef Google Scholar PubMed

Milo, R., Shen-Orr, S., Itzkovitz, S. et al. (2002). Network motifs: simple building blocks of complex networks. Science, 298 (5594), 824–827.Google Scholar

Mucha, P. J., Richardson, T., Macon, K., Porter, M. A., & Onnela, J.-P. (2010). Community structure in time-dependent, multiscale, and multiplex networks. Science, 328 (5980), 876–878.Google Scholar

Newman, M. E., et al. (2003). Random graphs as models of networks. Handbook of Graphs and Networks, 1, 35–68.Google Scholar

Newman, M. E. J. (2013). Spectral methods for community detection and graph partitioning. Physical Review E, 88 (4),042822.Google Scholar

Newman, M. E. J. (2016). Community detection in networks: modularity optimization and maximum likelihood are equivalent. arXiv preprint arXiv:1606.02319.Google Scholar

Newman, M. E. J. (2018a). Network. Oxford University Press.Google Scholar

Newman, M. E. J. (2018b). Network structure from rich but noisy data. Nature Physics, 14, 5.Google Scholar

Newman, M. E. J., & Girvan, M. (2004). Finding and evaluating community structure in networks. Physical Review E, 69(2), 026113.Google Scholar

Nicosia, V., Mangioni, G., Carchiolo, V., & Malgeri, M. (2009). Extending the definition of modularity to directed graphs with overlapping communities. Journal of Statistical Mechanics: Theory and Experiment, 2009(03),P03024.Google Scholar

O’Clery, N., Yuan, Y., Stan, G.-B., & Barahona, M. (2013). Observability and coarse graining of consensus dynamics through the external equitable partition. Physical Review E, 88(4). doi: https://doi.org/10.1103/physreve.88.042805 Google Scholar

Park, J., & Newman, M. E. (2004). Statistical mechanics of networks. Physical Review E, 70 (6),066117.Google Scholar

Pastor-Satorras, R., Castellano, C., Van Mieghem, P., & Vespignani, A. (2015). Epidemic processes in complex networks. Reviews of Modern Physics, 87 (3), 925.Google Scholar

Pecora, L. M., Sorrentino, F., Hagerstrom, A. M., Murphy, T. E., & Roy, R. (2014). Cluster synchronization and isolated desynchronization in complex networks with symmetries. Nature Communications, 5, 4079.Google Scholar

Peel, L., Larremore, D. B., & Clauset, A. (2017). The ground truth about metadata and community detection in networks. Science Advances, 3 (5),e1602548.Google Scholar

Peixoto, T. P. (2018). Reconstructing networks with unknown and heterogeneous errors. Physical Review X, 8 (4),041011.CrossRef Google Scholar

Peixoto, T. P. (2019). Bayesian stochastic blockmodeling. Advances in Network Clustering and Blockmodeling, 289–332.Google Scholar

Perozzi, B., Al-Rfou, R., & Skiena, S. (2014). Deepwalk: online learning of social representations. In Proceedings of the 20th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining (pp. 701–710).Google Scholar

Piccardi, C. (2011). Finding and testing network communities by lumped Markov chains. PLoS One, 6(11), e27028. doi: 10.1371/journal.pone.0027028 Google Scholar

Pons, P., & Latapy, M. (2005). Computing communities in large networks using random walks. In: Yolum, P., Güngör, T., Gürgen, F., & Özturan, C. (eds.), International symposium on computer and information sciences, (pp. 284–293). Springer, Berlin, Heidelberg. doi: https://doi.org/10.1007/11569596_31 Google Scholar

Porter, M., Onnela, J., & Mucha, P. (2009). Communities in networks. Notices of the AMS, 56 (9),1082–1097, 1164–1166.Google Scholar

Porter, M. A., & Gleeson, J. P. (2016). Dynamical systems on networks. Frontiers in Applied Dynamical Systems: Reviews and Tutorials, 4. doi: https://doi.org/10.1101/2021.01.21.427609 Google Scholar

Proskurnikov, A. V., & Tempo, R. (2017). A tutorial on modeling and analysis of dynamic social networks. Part i. Annual Reviews in Control, 43, 65–79. doi: https://doi.org/10.1016/j.arcontrol.2017.03.002 Google Scholar

Putra, P., Thompson, T. B., & Goriely, A. (2021). Braiding braak and braak: staging patterns and model selection in network neurodegeneration. bioRxiv. Accessed at www.biorxiv.org.Google Scholar

Read, K. E. (1954). Cultures of the Central Highlands, New Guinea. Southwestern Journal of Anthropology, 10 (1), 1–43.Google Scholar

Reichardt, J., & Bornholdt, S. (2006). Statistical mechanics of community detection. Physical Review E, 74 (1),016110.Google Scholar

Reichardt, J., & White, D. R. (2007). Role models for complex networks. The European Physical Journal B, 60 (2), 217–224.Google Scholar

Rényi, A., et al. (1961). On measures of entropy and information. In Proceedings of the Fourth Berkeley Symposium on Mathematical Statistics and Probability Volume 1: contributions to the theory of statistics.Google Scholar

Rohe, K., Chatterjee, S., Yu, B., et al. (2011). Spectral clustering and the high-dimensional stochastic blockmodel. The Annals of Statistics, 39 (4), 1878–1915.Google Scholar

Rombach, M. P., Porter, M. A., Fowler, J. H., & Mucha, P. J. (2014). Core-periphery structure in networks. SIAM Journal on Applied Mathematics, 74 (1), 167–190.Google Scholar

Rossetti, G., & Cazabet, R. (2018). Community discovery in dynamic networks: a survey. ACM Computing Surveys (CSUR), 51(2), 1–37.Google Scholar

Rossi, R. A., Jin, D., Kim, S. et al. (2020). On proximity and structural role-based embeddings in networks: misconceptions, techniques, and applications. ACM Transactions on Knowledge Discovery from Data (TKDD), 14 (5), 1–37.Google Scholar

Rosvall, M., & Bergstrom, C. T. (2008). Maps of random walks on complex networks reveal community structure. Proceedings of the National Academy of Sciences, 105 (4), 1118–1123.Google Scholar

Rosvall, M., Esquivel, A. V., Lancichinetti, A., West, J. D., & Lambiotte, R. (2014). Memory in network flows and its effects on spreading dynamics and community detection. Nature Communications, 5, 4630. doi: https://doi.org/10.1038/ncomms5630 CrossRef Google Scholar PubMed

Ruggeri, N., & De Bacco, C. (2019, August). Sampling on networks: estimating eigenvector centrality on incomplete graphs. arXiv:1908.00388v1 [cs.SI].Google Scholar

Salnikov, V., Schaub, M. T., & Lambiotte, R. (2016). Using higher-order Markov models to reveal flow-based communities in networks. Scientific Reports, 6, 23194. doi: https://doi.org/10.1038/srep23194 Google Scholar

Sanchez-Garcia, R. J. (2018). Exploiting symmetry in network analysis. arXiv preprint arXiv:1803.06915.Google Scholar

Schaeffer, S. E. (2007). Graph clustering. Computer Science Review, 1(1), 27–64. doi: https://doi.org/10.1016/j.cosrev.2007.05.001 Google Scholar

Schaub, M. T. (2014). Unraveling complex networks under the prism of dynamical processes: relations between structure and dynamics. (Doctoral dissertation). Imperial College London.Google Scholar

Schaub, M. T., Benson, A. R., Horn, P., Lippner, G., & Jadbabaie, A. (2020). Random walks on simplicial complexes and the normalized Hodge 1-Laplacian. SIAM Review, 62 (2), 353–391.Google Scholar

Schaub, M. T., Billeh, Y. N., Anastassiou, C. A., Koch, C., & Barahona, M. (2015). Emergence of slow-switching assemblies in structured neuronal networks. PLOS Computational Biology, 11 (7),e1004196.Google Scholar

Schaub, M. T., Delvenne, J.-C., Lambiotte, R., & Barahona, M. (2019a). Multiscale dynamical embeddings of complex networks. Physical Review E, 99 (6),062308. doi: https://doi.org/10.1103/PhysRevE.99.062308 Google Scholar

Schaub, M. T., Delvenne, J.-C., Lambiotte, R., & Barahona, M. (2019b). Structured networks and coarse-grained descriptions: a dynamical perspective. Advances in Network Clustering and Blockmodeling, pp. 333–361.Google Scholar

Schaub, M. T., Delvenne, J.-C., Rosvall, M., & Lambiotte, R. (2017, 02). The many facets of community detection in complex networks. Applied Network Science, 2(1), 4. doi: 10.1007/s41109-017-0023-6 Google Scholar

Schaub, M. T., Delvenne, J.-C., Yaliraki, S. N., & Barahona, M. (2012a). Markov dynamics as a zooming lens for multiscale community detection: non clique-like communities and the field-of-view limit. PloS One, 7(2), e32210.Google Scholar

Schaub, M. T., Lambiotte, R., & Barahona, M. (2012b). Encoding dynamics for multiscale community detection: Markov time sweeping for the map equation. Physical Review E, 86 (2),026112.Google Scholar

Schaub, M. T., O’Clery, N., Billeh, Y. N. et al. (2016). Graph partitions and cluster synchronization in networks of oscillators. Chaos: An Interdisciplinary Journal of Nonlinear Science, 26 (9),094821.Google Scholar

Schaub, M. T., & Peel, L. (2020). Hierarchical community structure in networks. arXiv preprint arXiv:2009.07196.Google Scholar

Schaub, M. T., Zhu, Y., Seby, J.-B., Roddenberry, T. M., & Segarra, S. (2021). Signal processing on higher-order networks: Livin’ on the edge... and beyond. Signal Processing, 187, 108149. doi: https://doi.org/10.1016/j.sigpro.2021.108149 Google Scholar

Serrano, M. A., & Boguná, M. (2021). The shortest path to network geometry. Cambridge University Press.Google Scholar

Serrano, M. A., Krioukov, D., & Boguná, M. (2008). Self-similarity of complex networks and hidden metric spaces. Physical Review Letters, 100 (7),078701.Google Scholar

Shi, J., & Malik, J. (1997). Normalized cuts and image segmentation. In Proceedings of IEEE Computer Society Conference on Computer Vision and Pattern Recognition (pp. 731–737).Google Scholar

Shuman, D. I., Narang, S. K., Frossard, P., Ortega, A., & Vandergheynst, P. (2013). The emerging field of signal processing on graphs: extending high-dimensional data analysis to networks and other irregular domains. IEEE Signal Processing Magazine, 30 (3), 83–98.Google Scholar

Simon, H. A. (1962). The architecture of complexity. Proceedings of the American Philosophical Society, 106 (6), 467–482.Google Scholar

Simon, H. A., & Ando, A. (1961). Aggregation of variables in dynamic systems. Econometrica: Journal of the Econometric Society, 111–138.Google Scholar

Simpson, E. H. (1949). Measurement of diversity. Nature, 163 (4148),688.Google Scholar

Smiljanić, J., Edler, D., & Rosvall, M. (2020). Mapping flows on sparse networks with missing links. Physical Review E, 102 (1),012302.Google Scholar

Spielman, D. A., & Teng, S.-H. (2011). Spectral sparsification of graphs. SIAM Journal on Computing, 40(4), 981–1025. doi: https://doi.org/10.1137/08074489X Google Scholar

Stamm, F. I., Neuhäuser, L., Lemmerich, F., Schaub, M. T., & Strohmaier, M. (2020). Systematic edge uncertainty in attributed social networks and its effects on rankings of minority nodes. arXiv:2010.11546v2 [cs.SI]Google Scholar

Stewart, G. W. (2001). Matrix algorithms volume 2: eigensystems. SIAM.Google Scholar

Stewart, I., Golubitsky, M., & Pivato, M. (2003). Symmetry groupoids and patterns of synchrony in coupled cell networks. SIAM Journal on Applied Dynamical Systems, 2 (4), 609–646.Google Scholar

Strogatz, S. (2004). Sync: the emerging science of spontaneous order. Penguin UK.Google Scholar

Stumpf, M. P., Wiuf, C., & May, R. M. (2005). Subnets of scale-free networks are not scale-free: sampling properties of networks. Proceedings of the National Academy of Sciences, 102 (12), 4221–4224.Google Scholar

Tian, F., Gao, B., Cui, Q., Chen, E., & Liu, T.-Y. (2014). Learning deep representations for graph clustering. In Proceedings of the AAAI Conference on Artificial Intelligence (vol. 28).CrossRef Google Scholar

Traag, V. A., Waltman, L., & Van Eck, N. J. (2019). From Louvain to Leiden: guaranteeing well-connected communities. Scientific Reports, 9 (1), 1–12.Google Scholar

Trefethen, L. N., & Embree, M. (2005). Spectra and pseudospectra: the behavior of nonnormal matrices and operators. Princeton University Press.Google Scholar

Van Lierde, H., Chow, T. W., & Delvenne, J.-C. (2019). Spectral clustering algorithms for the detection of clusters in block-cyclic and block-acyclic graphs. Journal of Complex Networks, 7 (1), 1–53.Google Scholar

Von Luxburg, U. (2007). A tutorial on spectral clustering. Statistics and Computing, 17(4), 395–416.Google Scholar

Wagner, C., Singer, P., & Karimi, F. (2017). Sampling from social networks with attributes, pp. 1181–1190. doi: https://doi.org/10.1145/3038912.3052665 Google Scholar

Wainwright, M. J. (2019). High-dimensional statistics: a non-asymptotic viewpoint, (vol. 48). Cambridge University Press.CrossRef Google Scholar

Wasserman, S., & Faust, K. (1994). Social network analysis: methods and applications, (vol. 8). Cambridge University Press.Google Scholar

Wu, Z., Pan, S., Chen, F. et al. (2020). A comprehensive survey on graph neural networks. IEEE Transactions on Neural Networks and Learning Systems. arXiv:1901.00596v4 [cs.LG]Google Scholar

Xu, R., & Wunsch, D. (2008). Clustering (vol. 10). John Wiley & Sons.Google Scholar

Young, J.-G., Cantwell, G. T., & Newman, M. E. J. (2020). Robust Bayesian inference of network structure from unreliable data. arXiv:2008.03334v2 [cs.SI]Google Scholar

Yu, Y., Wang, T., & Samworth, R. J. (2015). A useful variant of the Davis–Kahan theorem for statisticians. Biometrika, 102 (2), 315–323.Google Scholar

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