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Statistical inference for continuous‐time Markov processes with block structure based on discrete‐time network data

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  • Michael Schweinberger

Abstract

A widely used approach to modeling discrete‐time network data assumes that discrete‐time network data are generated by an unobserved continuous‐time Markov process. While such models can capture a wide range of network phenomena and are popular in social network analysis, the models are based on the homogeneity assumption that all nodes share the same parameters. We remove the homogeneity assumption by allowing nodes to belong to unobserved subsets of nodes, called blocks, and assuming that nodes in the same block have the same parameters, whereas nodes in distinct blocks have distinct parameters. The resulting models capture unobserved heterogeneity across nodes and admit model‐based clustering of nodes based on network properties chosen by researchers. We develop Bayesian data‐augmentation methods and apply them to discrete‐time observations of an ownership network of non‐financial companies in Slovenia in its critical transition from a socialist economy to a market economy. We detect a small subset of shadow‐financial companies that outpaces others in terms of the rate of change and the desire to accumulate stocks of other companies.

Suggested Citation

  • Michael Schweinberger, 2020. "Statistical inference for continuous‐time Markov processes with block structure based on discrete‐time network data," Statistica Neerlandica, Netherlands Society for Statistics and Operations Research, vol. 74(3), pages 342-362, August.
    • Handle: RePEc:bla:stanee:v:74:y:2020:i:3:p:342-362
    DOI: 10.1111/stan.12196
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    References listed on IDEAS

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    1. Schweinberger, Michael & Snijders, Tom A.B., 2007. "Markov models for digraph panel data: Monte Carlo-based derivative estimation," Computational Statistics & Data Analysis, Elsevier, vol. 51(9), pages 4465-4483, May.
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    3. Michael Schweinberger & Mark S. Handcock, 2015. "Local dependence in random graph models: characterization, properties and statistical inference," Journal of the Royal Statistical Society Series B, Royal Statistical Society, vol. 77(3), pages 647-676, June.
    4. Nowicki K. & Snijders T. A. B., 2001. "Estimation and Prediction for Stochastic Blockstructures," Journal of the American Statistical Association, American Statistical Association, vol. 96, pages 1077-1087, September.
    5. Daniel K. Sewell & Yuguo Chen, 2015. "Latent Space Models for Dynamic Networks," Journal of the American Statistical Association, Taylor & Francis Journals, vol. 110(512), pages 1646-1657, December.
    6. Pavel N. Krivitsky & Mark S. Handcock, 2014. "A separable model for dynamic networks," Journal of the Royal Statistical Society Series B, Royal Statistical Society, vol. 76(1), pages 29-46, January.
    7. Leo Katz & Charles Proctor, 1959. "The concept of configuration of interpersonal relations in a group as a time-dependent stochastic process," Psychometrika, Springer;The Psychometric Society, vol. 24(4), pages 317-327, December.
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