Fluctuations of λ-geodesic Poisson hyperplanes in hyperbolic space
Abstract
Poisson processes of so-called λ-geodesic hyperplanes in d-dimensional hyperbolic space are studied for 0≤λ≤ 1. The case λ=0 corresponds to genuine geodesic hyperplanes, the case λ=1 to horospheres and λ∈(0,1) to λ-equidistants. In the focus are the fluctuations of the centred and normalized total surface area of the union of all λ-geodesic hyperplanes in the Poisson process within a hyperbolic ball of radius R centred at some fixed point, as R∞. It is shown that for λ<1 these random variables satisfy a quantitative central limit theorem precisely for d=2 and d=3. The exact form of the non-Gaussian, infinitely divisible limiting distribution is determined for all higher space dimensions d≥ 4. The special case λ=1 is in sharp contrast to this behaviour. In fact, for the total surface area of Poisson processes of horospheres, a non-standard central limit theorem with limiting variance 1/2 is established for all space dimensions d≥ 2. We discuss the analogy between the problem studied here and the Random Energy Model whose partition function exhibits a similar structure of possible limit laws.
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