Abstract
In the series of models with interacting particles in stochastic geometry, a further contribution presents the facet process which is defined in arbitrary Euclidean dimension. In 2D, 3D specially it is a process of interacting segments, flat surfaces, respectively. Its investigation is based on the theory of functionals of finite spatial point processes given by a density with respect to a Poisson process. The methodology based on L 2 expansion of the covariance of functionals of Poisson process is developed for U-statistics of facet intersections which are building blocks of the model. The importance of the concept of correlation functions of arbitrary order is emphasized. Some basic properties of facet processes, such as local stability and repulsivness are shown and a standard simulation algorithm mentioned. Further the situation when the intensity of the process tends to infinity is studied. In the case of Poisson processes a central limit theorem follows from recent results of Wiener-Ito theory. In the case of non-Poisson processes we restrict to models with finitely many orientations. Detailed analysis of correlation functions exhibits various asymptotics for different combination of U-statistics and submodels of the facet process.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Baddeley A (2007) Spatial point processes and their applications, Stochastic geometry, Lecture Notes in Math., vol. 1892, vol 1. Springer, Berlin, pp 96–75
Beneš V, Zikmundová M (2014) Functionals of spatial point processes having a density with respect to the Poisson process. Kybernetika 50:896–913
Decreusefond L, Flint I (2014) Moment formulae for general point processes. J Funct Anal 267:452–476
Georgii HO, Yoo HJ (2005) Conditional intensity and Gibbsianness of determinantal point processes. J Statist Phys 118:55–83
Geyer CJ, Møller J (1994) Simulation and likelihood inference for spatial point processes. Scand J Stat 21:359–373
Kendall WS, van Lieshout M, Baddeley A (1999) Quermass-interaction processes: conditions for stability. Adv Appl Prob 31:315–342
Last G, Penrose MD (2011) Poisson process Fock space representation, chaos expansion and covariance inequalities. Probab Th Relat Fields 150:663–690
Last G, Penrose MD, Schulte M, Thäle C (2014) Moments and central limit theorems for some multivariate Poisson functionals. Adv Appl Probab 46:348–364
Møller J, Helisová K (2008) Power diagrams and interaction processes for unions of discs. Adv Appl Probab 40:321–347
Pawlas Z (2014) Self-crossing points of a line segment process. Methodol Comp Appl Probab 16:295–309
Peccati G, Taqqu MS (2011) Wiener chaos: Moments, Cumulants and Diagrams, Bocconi Univ Press. Springer, Milan
Reitzner M, Schulte M (2013) Central limit theorems for U-statistics of Poisson point processes. Ann Probab 41:3879–3909
Schneider R, Weil W (2008) Stochastic and integral geometry. Springer, Berlin
Schreiber T, Yukich J (2013) Limit theorems for geometric functionals of Gibbs point processes. Ann de l’Inst Henri Poincaré - Probab et Statist 49:1158–1182
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Večeřa, J., Beneš, V. Interaction Processes for Unions of Facets, the Asymptotic Behaviour with Increasing Intensity. Methodol Comput Appl Probab 18, 1217–1239 (2016). https://doi.org/10.1007/s11009-016-9485-8
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11009-016-9485-8