ON THE HAUSDORFF MEASURE OF SHRINKING TARGET SETS ON SELF‐CONFORMAL SETS

This paper considers self-conformal iterated function systems (IFSs) on the real line whose first level cylinders overlap. In the space of self-conformal IFSs, we show that generically (in topological sense) if the attractor of such a system has Hausdorff dimension less than 1 then it has zero appropriate dimensional Hausdorff measure and its Assouad dimension is equal to 1. Our main contribution is in showing that if the cylinders intersect then the IFS generically does not satisfy the weak separation property and hence, we may apply a recent result of Angelevska, Käenmäki and Troscheit. This phenomenon holds for transversal families (in particular for the translation family) typically, in the self-similar case, in both topological and in measure theoretical sense, and in the more general self-conformal case in the topological sense.

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Does a central limit theorem hold for the k-skeleton of Poisson hyperplanes in hyperbolic space?

Probability Theory and Related Fields ◽

10.1007/s00440-021-01032-w ◽

2021 ◽

Author(s):

Felix Herold ◽

Daniel Hug ◽

Christoph Thäle

Keyword(s):

Central Limit Theorem ◽

Limit Theorem ◽

Hyperbolic Space ◽

Central Limit ◽

Hausdorff Measure ◽

Rates Of Convergence ◽

Limit Problem ◽

Dimensional Hausdorff Measure ◽

The Central Limit Theorem ◽

Order Quantities

AbstractPoisson processes in the space of $$(d-1)$$ ( d - 1 ) -dimensional totally geodesic subspaces (hyperplanes) in a d-dimensional hyperbolic space of constant curvature $$-1$$ - 1 are studied. The k-dimensional Hausdorff measure of their k-skeleton is considered. Explicit formulas for first- and second-order quantities restricted to bounded observation windows are obtained. The central limit problem for the k-dimensional Hausdorff measure of the k-skeleton is approached in two different set-ups: (i) for a fixed window and growing intensities, and (ii) for fixed intensity and growing spherical windows. While in case (i) the central limit theorem is valid for all $$d\ge 2$$ d ≥ 2 , it is shown that in case (ii) the central limit theorem holds for $$d\in \{2,3\}$$ d ∈ { 2 , 3 } and fails if $$d\ge 4$$ d ≥ 4 and $$k=d-1$$ k = d - 1 or if $$d\ge 7$$ d ≥ 7 and for general k. Also rates of convergence are studied and multivariate central limit theorems are obtained. Moreover, the situation in which the intensity and the spherical window are growing simultaneously is discussed. In the background are the Malliavin–Stein method for normal approximation and the combinatorial moment structure of Poisson U-statistics as well as tools from hyperbolic integral geometry.

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The local structure of the free boundary in the fractional obstacle problem

Advances in Calculus of Variations ◽

10.1515/acv-2019-0081 ◽

2020 ◽

Vol 0 (0) ◽

Author(s):

Matteo Focardi ◽

Emanuele Spadaro

Keyword(s):

Hausdorff Dimension ◽

Free Boundary ◽

Hausdorff Measure ◽

Local Structure ◽

Obstacle Problem ◽

List Type ◽

Minkowski Content ◽

Local Finiteness ◽

Lower Dimensional

AbstractBuilding upon the recent results in [M. Focardi and E. Spadaro, On the measure and the structure of the free boundary of the lower-dimensional obstacle problem, Arch. Ration. Mech. Anal. 230 2018, 1, 125–184] we provide a thorough description of the free boundary for the solutions to the fractional obstacle problem in {\mathbb{R}^{n+1}} with obstacle function φ (suitably smooth and decaying fast at infinity) up to sets of null {{\mathcal{H}}^{n-1}} measure. In particular, if φ is analytic, the problem reduces to the zero obstacle case dealt with in [M. Focardi and E. Spadaro, On the measure and the structure of the free boundary of the lower-dimensional obstacle problem, Arch. Ration. Mech. Anal. 230 2018, 1, 125–184] and therefore we retrieve the same results:(i)local finiteness of the {(n-1)}-dimensional Minkowski content of the free boundary (and thus of its Hausdorff measure),(ii){{\mathcal{H}}^{n-1}}-rectifiability of the free boundary,(iii)classification of the frequencies and of the blowups up to a set of Hausdorff dimension at most {(n-2)} in the free boundary.Instead, if {\varphi\in C^{k+1}(\mathbb{R}^{n})}, {k\geq 2}, similar results hold only for distinguished subsets of points in the free boundary where the order of contact of the solution with the obstacle function φ is less than {k+1}.

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Hausdorff measure of noncompactness in subspaces of continuous functions of codimension one

Nonlinear Analysis ◽

10.1016/0362-546x(94)00132-2 ◽

1995 ◽

Vol 25 (3) ◽

pp. 223-228 ◽

Cited By ~ 1

Author(s):

Andrzej Wiśnicki

Keyword(s):

Hausdorff Measure ◽

Measure Of Noncompactness ◽

Continuous Functions ◽

Hausdorff Measure Of Noncompactness ◽

Codimension One

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Standard target sets for field sensor performance measurements

10.1117/12.667002 ◽

2006 ◽

Cited By ~ 1

Author(s):

John D. O'Connor ◽

Patrick O'Shea ◽

John E. Palmer ◽

Dawne M. Deaver

Keyword(s):

Performance Measurements ◽

Sensor Performance ◽

Field Sensor ◽

Target Sets

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Transcription factor and microRNA motif discovery: The Amadeus platform and a compendium of metazoan target sets

Genome Research ◽

10.1101/gr.076117.108 ◽

2008 ◽

Vol 18 (7) ◽

pp. 1180-1189 ◽

Cited By ~ 126

Author(s):

C. Linhart ◽

Y. Halperin ◽

R. Shamir

Keyword(s):

Transcription Factor ◽

Motif Discovery ◽

Target Sets

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Graph directed Markov systems on Hilbert spaces

Mathematical Proceedings of the Cambridge Philosophical Society ◽

10.1017/s0305004109002448 ◽

2009 ◽

Vol 147 (2) ◽

pp. 455-488 ◽

Cited By ~ 11

Author(s):

R. D. MAULDIN ◽

T. SZAREK ◽

M. URBAŃSKI

Keyword(s):

Hausdorff Measure ◽

Iterated Function System ◽

Sufficient Conditions ◽

Topological Pressure ◽

Limit Set ◽

Covering Theorem ◽

Limit Sets ◽

Markov Systems ◽

Polish Spaces ◽

Iterated Function

AbstractWe deal with contracting finite and countably infinite iterated function systems acting on Polish spaces, and we introduce conformal Graph Directed Markov Systems on Polish spaces. Sufficient conditions are provided for the closure of limit sets to be compact, connected, or locally connected. Conformal measures, topological pressure, and Bowen's formula (determining the Hausdorff dimension of limit sets in dynamical terms) are introduced and established. We show that, unlike the Euclidean case, the Hausdorff measure of the limit set of a finite iterated function system may vanish. Investigating this issue in greater detail, we introduce the concept of geometrically perfect measures and provide sufficient conditions for geometric perfectness. Geometrical perfectness guarantees the Hausdorff measure of the limit set to be positive. As a by–product of the mainstream of our investigations we prove a 4r–covering theorem for all metric spaces. It enables us to establish appropriate co–Frostman type theorems.

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