Random Closed Sets

A set-valued analog of the elementary renewal theorem for Minkowski sums of random closed sets is considered. The corresponding renewal function is defined as where are Minkowski (element-wise) sums of i.i.d. random compact convex sets. In this paper we determine the limit of H(tK)/t as t tends to infinity. For K containing the origin as an interior point, where hK(u) is the support function of K and is the set of all unit vectors u with EhA(u) > 0. Other set-valued generalizations of the renewal function are also suggested.

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Random Closed Sets

An Introduction to Random Sets ◽

10.1201/9781420010619.ch5 ◽

2006 ◽

pp. 109-130

Keyword(s):

Closed Sets ◽

Random Closed Sets

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Poisson hail on a hot ground

Journal of Applied Probability ◽

10.1017/s0021900200099332 ◽

2011 ◽

Vol 48 (A) ◽

pp. 343-366

Author(s):

Francois Baccelli ◽

Sergey Foss

Keyword(s):

Euclidean Space ◽

Service Time ◽

Evolution Equations ◽

Stationary Regime ◽

Service Discipline ◽

Closed Sets ◽

Random Closed Sets ◽

Exponential Moments ◽

First In First Out ◽

Arrival Intensity

We consider a queue where the server is the Euclidean space, and the customers are random closed sets (RACSs) of the Euclidean space. These RACSs arrive according to a Poisson rain and each of them has a random service time (in the case of hail falling on the Euclidean plane, this is the height of the hailstone, whereas the RACS is its footprint). The Euclidean space serves customers at speed 1. The service discipline is a hard exclusion rule: no two intersecting RACSs can be served simultaneously and service is in the first-in–first-out order, i.e. only the hailstones in contact with the ground melt at speed 1, whereas the others are queued. A tagged RACS waits until all RACSs that arrived before it and intersecting it have fully melted before starting its own melting. We give the evolution equations for this queue. We prove that it is stable for a sufficiently small arrival intensity, provided that the typical diameter of the RACS and the typical service time have finite exponential moments. We also discuss the percolation properties of the stationary regime of the RACS in the queue.

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