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Dynamics of network growth and evolution: integrating non-constant edge growth, mixed attachment and reciprocity

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Abstract

Advancements in network science research have enriched our understanding of the mechanisms shaping the topological properties of networks over the past two decades. However, the existing models still grapple with limitations in fully capturing the diverse structures and behaviours observed in real-world networks. This paper addresses these limitations by examining network growth in networks characterised by a distinct in-degree distribution, exhibiting expected new edges in the head and an extended exponential or power-law behaviour in the tail. To overcome these complexities, we propose a comprehensive model encompassing non-constant edge establishment driven by mixed attachment and reciprocal mechanisms. This extension offers a more accurate representation of real-world networks. Utilising various discrete probability distributions, including Poisson, binomial, zeta and log-series, our model accommodates variations in the number of new edges, providing a realistic depiction of network evolution. Analytical expressions for the limit in- and out-degree distributions and evolving dynamics of cumulative complementary in- and out-degree distributions are derived. These findings enable a detailed assessment of each mechanism’s contribution to the head and tail of the in- and out-degree distributions. Furthermore, we validate the practical relevance of our model by fitting it to real-world networks, emphasising the impact of the number of new edges and reciprocity.

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Acknowledgements

This research was supported in part by the Colombian ‘Fondo de Ciencia, Tecnología e Innovación del Sistema General de Regalías FCTeI-SGR’ of the Cauca Department throughout the project ‘Fortalecimiento de las Capacidades de las EBT-TIC del Cauca para Competir en un Mercado Global-Cluster CreaTIC’ under Grant No. TH 2017-01.

Author information

Authors and Affiliations

  1. Department of Electronics and Computer Sciences, Pontificia Universidad Javeriana Cali, Cali, Colombia

    Jan Medina-López

  2. Department of Mathematics, Universidad del Cauca, Popayán, Colombia

    Diego Ruiz

Corresponding author

Correspondence to Jan Medina-López.

Appendix A. Additional simulations

Appendix A. Additional simulations

In this appendix, we present additional simulations to complement the main analysis discussed in the preceding sections. The supplementary figures included here showcase simulations based on different probability distributions, including Poisson (figure 5), geometric (figure 6) and logarithmic series (figure 7). These simulations provide further validation for the theoretical analysis conducted in the main text. Each figure offers insights into how the simulated networks align with theoretical predictions across various probability distributions. By examining these additional simulations, we gain a comprehensive understanding of the robustness and applicability of our theoretical framework.

Figures 5a, 5c, 6a, 6c and 7a illustrate how the simulated network converges with the theoretical predictions as the number of iterations increases. In figures 5b, 5d, 6b, 6d and 7b, you can observe the dynamics of  and  for nodes with in-degree and out-degree values of . The results show that the simulated values of F(k),  and  gradually approach the corresponding theoretical values as the number of iterations increases.

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Medina-López, J., Ruiz, D. Dynamics of network growth and evolution: integrating non-constant edge growth, mixed attachment and reciprocity. Pramana – J Phys 99, 102 (2025). https://doi.org/10.1007/s12043-025-02935-2

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  • Published 
  • DOI  https://doi.org/10.1007/s12043-025-02935-2

Keywords

  • Network modelling
  • formation models
  • power-law
  • preferential attachment
  • uniform attachment
  • reciprocity
  • non-constant edge growth
  • structural analysis
  • degree distribution
  • stability

PACS

  • 02.10.Ox; 02.50.−r; 89.75.Fb
  • 05.45.−a

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