NORMAL CONVERGENCE OF NONLOCALISED GEOMETRIC FUNCTIONALS AND SHOT-NOISE EXCURSIONS

NORMAL CONVERGENCE OF NONLOCALISED GEOMETRIC FUNCTIONALS AND SHOT-NOISE EXCURSIONS

This article presents a complete second-order theory for a large class of geometric functionals on homogeneous Poisson input. In particular, the results do not require the existence of a radius of stabilisation. Hence they can be applied to geometric functionals of spatial shot-noise fields excursio...

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Veröffentlicht in:The Annals of applied probability 2019-10, Vol.29 (5), p.2613-2653
1. Verfasser: Lachièze-Rey, Raphaël
Format: Artikel
Sprache:eng
Schlagworte:
Asymptotic properties
Convergence
Eulers equations
Geometry
Noise
Normality
Perturbation
Poisson distribution
Shot
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Zusammenfassung:This article presents a complete second-order theory for a large class of geometric functionals on homogeneous Poisson input. In particular, the results do not require the existence of a radius of stabilisation. Hence they can be applied to geometric functionals of spatial shot-noise fields excursions such as volume, perimeter, or Euler characteristic (the method still applies to stabilising functionals). More generally, it must be checked that a local contribution to the functional is not strongly affected under a perturbation of the input far away. In this case, the exact asymptotic variance is given, as well as the likely optimal speed of convergence in the central limit theorem. This goes through a general mixing-type condition that adapts nicely to both proving asymptotic normality and that variance is of volume order.
ISSN:1050-5164
2168-8737
DOI:10.1214/18-AAP1445