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Geometry-free renormalization of directed networks: scale-invariance and reciprocity (2403.00235v1)

Published 1 Mar 2024 in physics.soc-ph, cond-mat.dis-nn, and cond-mat.stat-mech

Abstract: Recent research has tried to extend the concept of renormalization, which is naturally defined for geometric objects, to more general networks with arbitrary topology. The current attempts do not naturally apply to directed networks, for instance because they are based on the identification of (necessarily symmetric) inter-node distances arising from geometric embeddings or on the definition of Hermitian Laplacian operators requiring symmetric adjacency matrices in spectral approaches. Here we show that the Scale-Invariant Model, recently proposed as an approach to consistently model undirected networks at arbitrary (and possibly multi-scale) resolution levels, can be extended coherently to directed networks without the requirement of an embedding geometry or Laplacian structure. Moreover, it can account for nontrivial reciprocity, i.e. the empirically well-documented tendency of links to occur in mutual pairs more or less often than predicted by chance. After deriving the renormalization rules for networks with arbitrary reciprocity, we consider various examples. In particular we propose the first multiscale model of the international trade network with nontrivial reciprocity and an annealed model where positive reciprocity emerges spontaneously from coarse-graining. In the latter case, the renormalization process defines a group, not only a semigroup, and therefore allows to fine-grain networks to arbitrarily small scales. These results strengthen the notion that network renormalization can be defined in a much more general way than required by geometric or spectral approaches, because it needs only node-specific (metric-free) features and can coexist with the asymmetry of directed networks.

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References (52)
  1. P. W. Anderson, More is different: Broken symmetry and the nature of the hierarchical structure of science., Science 177, 393 (1972).
  2. C. Adami, What is complexity?, BioEssays 24, 1085 (2002).
  3. L. P. Kadanoff, Statistical physics: statics, dynamics and renormalization (World Scientific Publishing Company, 2000).
  4. K. G. Wilson, The renormalization group and critical phenomena, Reviews of Modern Physics 55, 583 (1983).
  5. N. Goldenfeld, Lectures on phase transitions and the renormalization group (CRC Press, 2018).
  6. S. Fortunato and M. Barthelemy, Resolution limit in community detection, Proceedings of the national academy of sciences 104, 36 (2007).
  7. S. Fortunato, Community detection in graphs, Physics reports 486, 75 (2010).
  8. L. K. Gallos, C. Song, and H. A. Makse, A review of fractality and self-similarity in complex networks, Physica A: Statistical Mechanics and its Applications 386, 686 (2007).
  9. C. Song, S. Havlin, and H. A. Makse, Origins of fractality in the growth of complex networks, Nature physics 2, 275 (2006).
  10. G. García-Pérez, M. Boguñá, and M. Á. Serrano, Multiscale unfolding of real networks by geometric renormalization, Nature Physics 14, 583 (2018).
  11. D. Gfeller and P. De Los Rios, Spectral coarse graining of complex networks, Physical review letters 99, 038701 (2007).
  12. E. Garuccio, M. Lalli, and D. Garlaschelli, Multiscale network renormalization: scale-invariance without geometry, arXiv preprint arXiv:2009.11024  (2020).
  13. K. S. Gleditsch, Expanded trade and gdp data, Journal of Conflict Resolution 46, 712 (2002).
  14. D. Garlaschelli and M. I. Loffredo, Structure and evolution of the world trade network, Physica A: Statistical Mechanics and its Applications 355, 138 (2005).
  15. J. Scott, What is social network analysis? (Bloomsbury Academic, 2012).
  16. M. E. Newman, S. Forrest, and J. Balthrop, Email networks and the spread of computer viruses, Physical Review E 66, 035101 (2002).
  17. D. Garlaschelli and M. I. Loffredo, Patterns of link reciprocity in directed networks., Physical review letters 93 26 Pt 1, 268701 (2004a).
  18. D. Garlaschelli and M. I. Loffredo, Multispecies grand-canonical models for networks with reciprocity, Physical Review E 73, 015101 (2006).
  19. T. Squartini and D. Garlaschelli, Triadic motifs and dyadic self-organization in the world trade network, in International Workshop on Self-Organizing Systems (Springer, 2012) pp. 24–35.
  20. T. Squartini, I. Van Lelyveld, and D. Garlaschelli, Early-warning signals of topological collapse in interbank networks, Scientific reports 3, 3357 (2013b).
  21. M. Boguná and M. Á. Serrano, Generalized percolation in random directed networks, Physical Review E 72, 016106 (2005).
  22. M. A. Nowak and K. Sigmund, Evolution of indirect reciprocity, Nature 437, 1291 (2005).
  23. V. Zlatić and H. Štefančić, Influence of reciprocal edges on degree distribution and degree correlations, Physical Review E 80, 016117 (2009).
  24. L. D. Molm, The structure of reciprocity, Social psychology quarterly 73, 119 (2010).
  25. A. Allard, M. Serrano, and M. Boguñá, Geometric description of clustering in directed networks, arXiv preprint arXiv:2302.09055  (2023).
  26. B. Kovács and G. Palla, Model-independent embedding of directed networks into euclidean and hyperbolic spaces, Communications Physics 6, 28 (2023).
  27. D. McDonald and S. He, Hyperbolic embedding of attributed and directed networks, IEEE Transactions on Knowledge and Data Engineering 35, 7003 (2023).
  28. T. Squartini and D. Garlaschelli, Analytical maximum-likelihood method to detect patterns in real networks, New Journal of Physics 13, 083001 (2011).
  29. T. Squartini, R. Mastrandrea, and D. Garlaschelli, Unbiased sampling of network ensembles, New Journal of Physics 17, 023052 (2015).
  30. T. Squartini and D. Garlaschelli, Maximum-Entropy Networks: Pattern Detection, Network Reconstruction and Graph Combinatorics (Springer, 2017).
  31. J. Väisälä, Gromov hyperbolic spaces, Expositiones Mathematicae 23, 187 (2005).
  32. T. Das, D. Simmons, and M. Urbański, Geometry and dynamics in Gromov hyperbolic metric spaces, Vol. 218 (American Mathematical Soc., 2017).
  33. P. Hitzler and A. K. Seda, Dislocated topologies, J. Electr. Eng 51, 3 (2000).
  34. R. Rammal, G. Toulouse, and M. A. Virasoro, Ultrametricity for physicists, Reviews of Modern Physics 58, 765 (1986).
  35. P. W. Holland and S. Leinhardt, An exponential family of probability distributions for directed graphs, Journal of the american Statistical association 76, 33 (1981).
  36. E. P. Wigner, On the distribution of the roots of certain symmetric matrices, Annals of Mathematics , 325 (1958).
  37. V. Girko, Elliptic law, Theory of Probability & Its Applications 30, 677 (1986).
  38. D. Garlaschelli and M. I. Loffredo, Fitness-dependent topological properties of the world trade web, Physical review letters 93, 188701 (2004b).
  39. A. Almog, T. Squartini, and D. Garlaschelli, A gdp-driven model for the binary and weighted structure of the international trade network, New Journal of Physics 17, 013009 (2015).
  40. A. Almog, T. Squartini, and D. Garlaschelli, The double role of gdp in shaping the structure of the international trade network, International Journal of Computational Economics and Econometrics 7, 381 (2017).
  41. A. Almog, R. Bird, and D. Garlaschelli, Enhanced gravity model of trade: reconciling macroeconomic and network models, Frontiers in Physics 7, 55 (2019).
  42. J. Tinbergen, Shaping the world economy; suggestions for an international economic policy, ””  (1962).
  43. M. Di Vece, D. Garlaschelli, and T. Squartini, Gravity models of networks: Integrating maximum-entropy and econometric approaches, Physical Review Research 4, 033105 (2022).
  44. T. Mayer and S. Zignago, Notes on cepii’s distances measures: The geodist database, ””  (2011).
  45. K. Penson and K. Górska, Exact and explicit probability densities for one-sided lévy stable distributions, Physical review letters 105, 210604 (2010).
  46. S. Wasserman and K. Faust, Social network analysis: Methods and applications (Cambridge university press, 1994).
  47. J. Park and M. E. Newman, Statistical mechanics of networks, Physical Review E 70, 066117 (2004).
  48. R. Summers and A. Heston, The penn world table (mark 5): an expanded set of international comparisons, 1950–1988, The Quarterly Journal of Economics 106, 327 (1991).
  49. C. I. Agency, World factbook (1998).
  50. I. M. F. G. S. Division, Direction of trade statistics (International Monetary Fund, 1993).
  51. https://www.world-gazetteer.com.
  52. D. Müllner, Modern hierarchical, agglomerative clustering algorithms, arXiv preprint arXiv:1109.2378  (2011).
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