Open Access

Lothar Heinrich, Malte Spiess

• A stationary Poisson cylinder process is composed by a stationary Poisson process of k-dimensional affine subspaces in a d-dimensional Euclidean space (1 <= k < d) which are dilated by a family of independent identically distributed random compact cylinder bases taken from the corresponding orthogonal complement. We study the accuracy of normal approximation of the d-volume of the union set of Poisson cylinders that covers cW when the scaling factor c > 0 becomes large. Here W denotes some fixed compact star-shaped window set containing the origin as inner point. We give lower and upper bounds of the variance of the union set in cW which exhibit long-range dependence within the union set of cylinders. Our main results are sharp estimates of the higher-order cumulants of the d-volume of all Poisson cylinders in cW under the assumption that the (d-k)-volume of the typical cylinder base possesses a finite exponential moment. These estimates enable us to apply the celebrated Lemma on largeA stationary Poisson cylinder process is composed by a stationary Poisson process of k-dimensional affine subspaces in a d-dimensional Euclidean space (1 <= k < d) which are dilated by a family of independent identically distributed random compact cylinder bases taken from the corresponding orthogonal complement. We study the accuracy of normal approximation of the d-volume of the union set of Poisson cylinders that covers cW when the scaling factor c > 0 becomes large. Here W denotes some fixed compact star-shaped window set containing the origin as inner point. We give lower and upper bounds of the variance of the union set in cW which exhibit long-range dependence within the union set of cylinders. Our main results are sharp estimates of the higher-order cumulants of the d-volume of all Poisson cylinders in cW under the assumption that the (d-k)-volume of the typical cylinder base possesses a finite exponential moment. These estimates enable us to apply the celebrated Lemma on large deviations' due to V. Statulevicius.…