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Self-similar sets and measures on the line

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... We finish this discussion on iterated function systems, and in particular on overlapping iterated functions systems, by emphasising that the study of these objects is currently a very active area of research. We refer the reader to the articles [21,22,34,35,39,40] for recent advances in the study of overlapping iterated function systems and their associated self-affine sets. ...
... The probability measure µ λ is known as the Bernoulli convolution corresponding to λ. Determining the dimension of µ λ , and determining those λ for which the corresponding Bernoulli convolution is absolutely continuous are two important problems that have attracted much attention. We refer the reader to [21,22,34,37,39,40] for a more detailed survey of Bernoulli convolutions and for an overview of some recent results. ...
Preprint
In this paper we study quantitative recurrence and the shrinking target problem for dynamical systems coming from overlapping iterated function systems. Such iterated function systems have the important property that a point often has several distinct choices of forward orbit. As is demonstrated in this paper, this non-uniqueness leads to different behaviour to that observed in the traditional setting where every point has a unique forward orbit. We prove several almost sure results on the Lebesgue measure of the set of points satisfying a given recurrence rate, and on the Lebesgue measure of the set of points returning to a shrinking target infinitely often. In certain cases, when the Lebesgue measure is zero, we also obtain Hausdorff dimension bounds. One interesting aspect of our approach is that it allows us to handle targets that are not simply balls, but may have a more exotic geometry.
... Using Hochman's result, Varjú showed that dim(ν Ber λ ) = 1 for transcendental λ ∈ (0.5, 1) [24]. The best resources to study the respective proofs are [12] and [25]. ...
... As before, for ψ ∈ G 2 and y ∈ G 2 , ψ(y) = e Φ(y)Ψ(ψ) 25 . ...
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In this paper, we consider the self-similar measure νλ=law(j0ξjλj)\nu_\lambda=\mathrm{law}\left(\sum_{j \geq 0} \xi_j \lambda^j\right) on R\mathbb{R}, where λ<1|\lambda|<1 and the ξjν\xi_j \sim \nu are independent, identically distributed with respect to a measure ν\nu finitely supported on Z\mathbb{Z}. One example of this is the classical Bernoulli convolution. It is known that for certain combinations of algebraic λ\lambda and ν\nu uniform on an interval, νλ\nu_\lambda is absolutely continuous and its Fourier transform has power decay (\cite{garsia1}, \cite{feng}); in the proof, it is exploited that for these combinations, a quantity called the Garsia entropy hλ(ν)h_{\lambda}(\nu) is maximal. We show that absolute continuity and power Fourier decay occur when λ\lambda and ν\nu are such that hλ(ν)h_{\lambda}(\nu) is maximal and classify all combinations for which this is the case. We find that if an algebraic λ\lambda without a Galois conjugate of modulus exactly one has a ν\nu such that hλ(ν)h_{\lambda}(\nu) is maximal, then all Galois conjugates of λ\lambda must be smaller in modulus than one and ν\nu must satisfy a certain finite set of linear equations in terms of λ\lambda.
... One of the most challenging problems in Fractal Geometry is to understand how a stationary measure distributes mass when the underlying iterated function system is overlapping. The exact overlaps conjecture and the study of Bernoulli convolutions are two particular instances of this problem (see [28,29,43,44,46,50,51] and the references therein). In this paper, we show that for self-conformal and self-similar measures, it is possible to disintegrate these measures over a family of measures for which we have lots of control over how mass is distributed. ...
Preprint
In this paper we prove disintegration results for self-conformal measures and affinely irreducible self-similar measures. The measures appearing in the disintegration resemble self-conformal/self-similar measures for iterated function systems satisfying the strong separation condition. As an application of our results, we prove the following Diophantine statements: 1. Using a result of Pollington and Velani, we show that if μ\mu is a self-conformal measure in R\mathbb{R} or an affinely irreducible self-similar measure, then there exists α>0\alpha>0 such that for all β>α\beta>\alpha we have μ({xRd:max1idxipi/q1qd+1d(logq)β for i.m. (p1,,pd,q)Zd×N})=0.\mu\left(\left\{\mathbf{x}\in \mathbb{R}^{d}:\max_{1\leq i\leq d}|x_{i}-p_i/q|\leq \frac{1}{q^{\frac{d+1}{d}}(\log q)^{\beta}}\textrm{ for i.m. }(p_1,\ldots,p_d,q)\in \mathbb{Z}^{d}\times \mathbb{N}\right\}\right)=0. 2. Using a result of Kleinbock and Weiss, we show that if μ\mu is an affinely irreducible self-similar measure, then μ\mu almost every x\mathbf{x} is not a singular vector.
... Moreover, due to an improvement by Shmerkin [Shm] the set of exceptional values of the parameter λ is in fact of zero Hausdorff dimension. For general surveys we refer the reader to [PSS,Va1,Va2]. For recent results on a lower bound on the Hausdorff dimension of ν λ see [FF,KPV,Va3]. ...
Preprint
We consider smooth random dynamical systems defined by a distribution with a finite moment of the norm of the differential, and prove that under suitable non-degeneracy conditions any stationary measure must be H\"older continuous. The result is a vast generalization of the classical statement on H\"older continuity of stationary measures of random walks on linear groups.
... Finally we mention recent papers of Feng and Feng and of Kleptsyn, Pollicott and Vytnova which give remarkable lower bounds for the dim H (ν β ) which hold for all β ∈ (1, 2) [7,13]. For a recent summary see [17]. ...
Preprint
We show how to turn the question of the absolute continuity of Bernoulli convolutions into one of counting the growth of the number of overlaps in the system. When the contraction parameter is a hyperbolic algebraic integer, we turn this question of absolute continuity into a question involving the ergodic theory of cocycles over domain exchange transformations.
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We study the law of random self-similar series defined above an irrational rotation on the Circle. This provides a natural class of continuous singular non-Rajchman measures.
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We show that for Lebesgue almost all d -tuples (\theta_1,\ldots,\theta_d) , with |\theta_j|>1 , any self-affine measure for a homogeneous non-degenerate iterated function system \{Ax+a_j\}_{j=1}^m in \mathbb{R}^d , where A^{-1} is a diagonal matrix with the entries (\theta_1,\ldots,\theta_d) , has power Fourier decay at infinity.
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Baker (2019), Bárány and Käenmäki (2019) independently showed that there exist iterated function systems without exact overlaps and there are super-exponentially close cylinders at all small levels. We adapt the method of Baker and obtain further examples of this type. We prove that for any algebraic number β2\beta\ge 2 there exist real numbers s,ts, t such that the iterated function system {xβ,x+1β,x+sβ,x+tβ}\left \{\frac{x}{\beta}, \frac{x+1}{\beta}, \frac{x+s}{\beta}, \frac{x+t}{\beta}\right \} satisfies the above property.
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We introduce a parameter space containing all algebraic integers β∈(1,2] that are not Pisot or Salem numbers, and a sequence of increasing piecewise continuous function on this parameter space which gives a lower bound for the Garsia entropy of the Bernoulli convolution νβ. This allows us to show that dimH(νβ)=1 for all β with representations in certain open regions of the parameter space.
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Let μ\mu be a Borel probability measure on SL2(R)\mathrm{SL}_2(\mathbb R) with a finite exponential moment, and assume that the subgroup Γμ\Gamma_{\mu} generated by the support of μ\mu is Zariski dense. Let ν\nu be the unique μ\mu-stationary measure on PR1\mathbb P^1_{\mathbb R}. We prove that the Fourier coefficients ν^(k)\widehat{\nu}(k) of ν\nu converge to 0 as k|k| tends to infinity. Our proof relies on a generalized renewal theorem for the Cartan projection.
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In this note we present some one-parameter families of homogeneous self-similar measures on the line such that - the similarity dimension is greater than 1 for all parameters and - the singularity of some of the self-similar measures from this family is not caused by exact overlaps between the cylinders. We can obtain such a family as the angle-α\alpha projections of the natural measure of the Sierpi\'nski carpet. We present more general one-parameter families of self-similar measures να\nu_\alpha, such that the set of parameters α\alpha for which να\nu_\alpha is singular is a dense GδG_\delta set but this "exceptional" set of parameters of singularity has zero Hausdorff dimension.
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Denote by μa the distribution of the random sum (1 - a), where P(ωj = 0) = P(ωj = 1) = 1/2 and all the choices are independent. For 0 < a < 1/2, the measure μa is supported on Ca, the central Cantor set obtained by starting with the closed united interval, removing an open central interval of length (1 - 2a), and iterating this process inductively on each of the remaining intervals. We investigate the convolutions μa* (μb {ring operator} Sλ-1), where Sλ(x) = λx is a rescaling map. We prove that if the ratio log b/ log a is irrational and λ ≠ 0, then, where D denotes any of correlation, Hausdorff or packing dimension of a measure. We also show that, perhaps surprisingly, for uncountably many values of λ the convolution μ1/4* (μ1/3 {ring operator} Sλ-1) is a singular measure, although dimH(C1/4) + dimH(C1/3) > 1 and log(1/3)/ log(1/4) is irrational.
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Let {F} be a self-similar set on \mathbb{R} associated to contractions {f_j(x) = r_j x + b_j} , {j \in \mathcal{A}} , for some finite \mathcal{A} , such that {F} is not a singleton. We prove that if {\log r_i / {\log r_j}} is irrational for some {i \neq j} , then {F} is a set of multiplicity, that is, trigonometric series are not in general unique in the complement of {F} . No separation conditions are assumed on {F} . We establish our result by showing that every self-similar measure {\mu} on {F} is a Rajchman measure: the Fourier transform {\widehat{\mu}(\xi) \to 0} as {|\xi| \to \infty} . The rate of {\widehat{\mu}(\xi) \to 0} is also shown to be logarithmic if {\log r_i / {\log r_j}} is diophantine for some {i \neq j} . The proof is based on quantitative renewal theorems for stopping times of random walks on \mathbb{R} .
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We establish a complete algebraic characterization of self-similar iterated function systems Φ on Rd, for which there exists a positive probability vector p so that the Fourier transform of the self-similar measure corresponding to Φ and p does not tend to 0 at infinity.
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We consider one-parameter families of smooth uniformly contractive iterated function systems {fjλ} on the real line. Given a family of parameter dependent measures {μλ} on the symbolic space, we study geometric and dimensional properties of their images under the natural projection maps Πλ. The main novelty of our work is that the measures μλ depend on the parameter, whereas up till now it has been usually assumed that the measure on the symbolic space is fixed and the parameter dependence comes only from the natural projection. This is especially the case in the question of absolute continuity of the projected measure (Πλ)⁎μλ, where we had to develop a new approach in place of earlier attempt which contains an error. Our main result states that if μλ are Gibbs measures for a family of Hölder continuous potentials ϕλ, with Hölder continuous dependence on λ and {Πλ} satisfy the transversality condition, then the projected measure (Πλ)⁎μλ is absolutely continuous for Lebesgue a.e. λ, such that the ratio of entropy over the Lyapunov exponent is strictly greater than 1. We deduce it from a more general almost sure lower bound on the Sobolev dimension for families of measures with regular enough dependence on the parameter. Under less restrictive assumptions, we also obtain an almost sure formula for the Hausdorff dimension. As applications of our results, we study stationary measures for iterated function systems with place-dependent probabilities (place-dependent Bernoulli convolutions and the Blackwell measure for binary channel) and equilibrium measures for hyperbolic IFS with overlaps (in particular: natural measures for non-homogeneous self-similar IFS and certain systems corresponding to random continued fractions).
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In this note we present an algorithm to obtain a uniform lower bound on Hausdorff dimension of the stationary measure of an affine iterated function scheme with similarities, the best known example of which is Bernoulli convolution. The Bernoulli convolution measure μλ is the probability measure corresponding to the law of the random variableξ=∑k=0∞ξkλk, where ξk are i.i.d. random variables assuming values −1 and 1 with equal probability and 12<λ<1. In particular, for Bernoulli convolutions we give a uniform lower bound dimH⁡(μλ)≥0.96399 for all 12<λ<1.
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Let Φ be a C1+γ smooth IFS on R, where γ>0. We provide mild conditions on the derivative cocycle that ensure that every self conformal measure is supported on points x that are absolutely normal. That is, for every integer p≥2 the sequence {pkx}k∈N equidistributes modulo 1. We thus extend several state of the art results of Hochman and Shmerkin [29] about the prevalence of normal numbers in fractals. When Φ is self-similar we show that the set of absolutely normal numbers has full Hausdorff dimension in its attractor, unless Φ has an explicit structure that is associated with some integer n≥2. These conditions on the derivative cocycle are also shown to imply that every self conformal measure is a Rajchman measure, that is, its Fourier transform decays to 0 at infinity. When Φ is self similar and satisfies a certain Diophantine condition, we establish a logarithmic rate of decay.
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We prove that, after removing a zero Hausdorff dimension exceptional set of parameters, all self-similar measures on the line have a power decay of the Fourier transform at infinity. In the homogeneous case, when all contraction ratios are equal, this is essentially due to Erdős and Kahane. In the non-homogeneous case the difficulty we have to overcome is the apparent lack of convolution structure.
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We exhibit self-similar sets on the line which are not exponentially separated and do not generate any exact overlaps. Our result shows that the exponential separation, introduced by Hochman in his groundbreaking theorem on the dimension of self-similar sets, is too weak to describe the full theory.
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Several important conjectures in Fractal Geometry can be summarised as follows: If the dimension of a self-similar measure in R does not equal its expected value, then the underlying iterated function system contains an exact overlap. In recent years significant progress has been made towards these conjectures. Hochman proved that if the Hausdorff dimension of a self-similar measure in R does not equal its expected value, then there are cylinders which are super-exponentially close at all small scales. Several years later, Shmerkin proved an analogous statement for the Lq dimension of self-similar measures in R. With these statements in mind, it is natural to wonder whether there exist iterated function systems that do not contain exact overlaps, yet there are cylinders which are super-exponentially close at all small scales. In this paper we show that such iterated function systems do exist. In fact we prove much more. We prove that for any sequence (ϵn)n=1∞ of positive real numbers, there exists an iterated function system {ϕi}i∈I that does not contain exact overlaps andmin⁡{|ϕa(0)−ϕb(0)|:a,b∈In,a≠b,ra=rb}≤ϵn for all n∈N.
Chapter
We present a self-contained proof of a formula for the LqL^q dimensions of self-similar measures on the real line under exponential separation (up to the proof of an inverse theorem for the LqL^q norm of convolutions). This is a special case of a more general result of the author from Shmerkin (Ann Math, 2019), and one of the goals of this survey is to present the ideas in a simpler, but important, setting. We also review some applications of the main result to the study of Bernoulli convolutions and intersections of self-similar Cantor sets.
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The Bernoulli convolution νλ with parameter λ ϵ (0, 1) is the probability measure supported on R that is the law of the random variable ∑±λn, where the ± are independent fair coin-tosses. We prove that dim νλ = 1 for all transcendental λ ϵ (1/2, 1).
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We give an expression for the Garsia entropy of Bernoulli convolutions in terms of products of matrices. This gives an explicit rate of convergence of the Garsia entropy and shows that one can calculate the Hausdorff dimension of the Bernoulli convolution νβ\nu_\beta to arbitrary given accuracy whenever β\beta is algebraic. In particular, if the Garsia entropy H(β)H(\beta) is not equal to log(β)\log(\beta) then we have a finite time algorithm to determine whether or not dimH(νβ)=1\mathrm{dim}_\mathrm{H} (\nu_\beta)=1.
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This paper is concerned with the Diophantine properties of the sequence{ξθⁿ}, where1 ≤ ξ < θ and θ is a rational or an algebraic integer. We establish a combinatorial proposition which can be used to study such two cases in the same manner. It is shown that the decay rate of the Fourier transforms of self-similar measuresμλ withλ = θ⁻¹ as the uniform contractive ratio is logarithmic. This generalizes some results of Kershner and Bufetov-Solomyak, who consider the case of Bernoulli convolutions. As an application, we prove thatμλ almost every x is normal to any base b ≥ 2, which implies that there exist infinitely many absolute normal numbers on the corresponding self-similar set. This can be seen as a complementary result of the well-known Cassels-Schmidt theorem.
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The Bernoulli convolution with parameter λ(0,1)\lambda\in(0,1) is the probability measure that is the law of the random variable n0±λn\sum_{n\ge0}\pm\lambda^n, where the signs are independent unbiased coin tosses. We prove that each parameter λ(1/2,1)\lambda\in(1/2,1) with dimμλ<1\dim\mu_\lambda<1 can be approximated by algebraic parameters ξ(1/2,1)\xi\in(1/2,1) within an error of order exp(deg(ξ)A)\exp(-deg(\xi)^{A}) for any number A, such that dimμξ<1\dim\mu_\xi<1. As a corollary, we conclude that dimμλ=1\dim\mu_\lambda=1 for each of λ=ln2,e1/2,π/4\lambda=\ln 2, e^{-1/2}, \pi/4. These are the first explicit examples of such transcendental parameters. Moreover, we show that Lehmer's conjecture implies the existence of a constant a<1a<1 such that dimμλ=1\dim\mu_\lambda=1 for all λ(a,1)\lambda\in(a,1).
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We study a class of measures on the real line with a kind of self-similar structure, which we call dynamically driven self-similar measures, and contain proper self-similar measures such as Bernoulli convolutions as special cases. Our main result gives an expression for the LqL^q-dimensions of such dynamically driven self-similar measures, under certain conditions. As an application, we settle Furstenberg's long-standing conjecture on the dimension of the intersections of ×p\times p and ×q\times q-invariant sets. Among several other applications, we also show that Bernoulli convolutions have an LqL^q density for all finite q, outside of a zero-dimensional set of exceptions. The proof of the main result is inspired by M. Hochman's approach to the dimensions of self-similar measures and his inverse theorem for entropy. Our method can be seen as an extension of Hochman's theory from entropy to LqL^q norms, and likewise relies on an inverse theorem for the decay of LqL^q norms of discrete measures under convolution. This central piece of our approach may be of independent interest, and is an application of well-known methods and results in additive combinatorics: the asymmetric version of the Balog-Szemer\'{e}di-Gowers Theorem due to Tao-Vu, and some constructions of Bourgain.
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The Bernoulli convolution with parameter λ(0,1)\lambda\in(0,1) is the measure on R\bf R that is the distribution of the random power series ±λn\sum\pm\lambda^n, where ±\pm are independent fair coin-tosses. This paper surveys recent progress on our understanding of the regularity properties of these measures.
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We prove that Bernoulli convolutions are absolutely continuous provided the parameter lambda is an algebraic number sufficiently close to 1 depending on the Mahler measure of lambda.
Chapter
Absolute continuity and singularity play a very important role in the study of measures in infinite-dimensional spaces, for example, Hubert space. Although there can be no theory treating such questions for finite-dimensional spaces which of great interest, such a theory for infinite-dimensional spaces is possible. It contains such topics as the investigation of the absolute continuity and singularity of various concrete classes of measures, the finding of general conditions for absolute continuity or singularity in terms of finite-dimensional distributions, and other characteristics defining the measures. An important problem is the calculation of the density of a measure w.r.t. another when the measures are absolutely continuous and the determination of the non-overlapping sets on which singular measures are concentrated.
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The exponential growth rate of non polynomially growing subgroups of GLdGL_d is conjectured to admit a uniform lower bound. This is known for non-amenable subgroups, while for amenable subgroups it is known to imply the Lehmer conjecture from number theory. In this note, we show that it is equivalent to the Lehmer conjecture. This is done by establishing a lower bound for the entropy of the random walk on the semigroup generated by the maps xλx±1x\mapsto \lambda\cdot x\pm 1, where λ\lambda is an algebraic number. We give a bound in terms of the Mahler measure of λ\lambda. We also derive a bound on the dimension of Bernoulli convolutions.
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We study products of random isometries acting on Euclidean space. Building on previous work of the second author, we prove a local limit theorem for balls of shrinking radius with exponential speed under the assumption that a Markov operator associated to the rotation component of the isometries has spectral gap. We also prove that certain self-similar measures are absolutely continuous with smooth densities. These families of self-similar measures give higher dimensional analogues of Bernoulli convolutions on which absolute continuity can be established for contraction ratios in an open set.
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We prove that the set of exceptional λ(1/2,1)\lambda\in (1/2,1) such that the associated Bernoulli convolution is singular has zero Hausdorff dimension, and likewise for biased Bernoulli convolutions, with the exceptional set independent of the bias. This improves previous results by Erd\"os, Kahane, Solomyak, Peres and Schlag, and Hochman. A theorem of this kind is also obtained for convolutions of homogeneous self-similar measures. The proofs are very short, and rely on old and new results on the dimensions of self-similar measures and their convolutions, and the decay of their Fourier transform.
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The paper gives first quantitative estimates on the modulus of continuity of the spectral measure for weakly mixing suspension flows over substitution automorphisms. The main results are, first, a Hoelder estimate for the spectral measure of almost all suspension flows with a piecewise constant roof function; second, a log-Hoelder estimate for self-similar suspension flows; and, third, a Hoelder asymptotic expansion of the spectral measure at zero for such flows. The second result implies log-Hoelder estimates for the spectral measures of translation flows along stable foliations of pseudo-Anosov automorphisms. The Appendix explains the connection of these results with the theory of Bernoulli convolutions.
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We study the Hausdorff dimension of self-similar sets and measures on the line. We show that if the dimension is smaller than the minimum of 1 and the similarity dimension, then at small scales there are super-exponentially close cylinders. This is a step towards the folklore conjecture that such a drop in dimension is explained only by exact overlaps, and confirms the conjecture in cases where the contraction parameters are algebraic. It also gives an affirmative answer to a conjecture of Furstenberg, showing that the projections of the "1-dimensional Sierpinski gasket" in irrational directions are all of dimension 1. As another consequence, if a family of self-similar sets or measures is parametrized in a real-analytic manner, then, under an extremely mild non-degeneracy condition, the set of "exceptional" parameters has Hausdorff dimension 0. Thus, for example, there is at most a zero-dimensional set of parameters 1/2<r<1 such that the corresponding Bernoulli convolution has dimension <1, and similarly for Sinai's problem on iterated function systems that contract on average. A central ingredient of the proof is an inverse theorem for the growth of Shannon entropy of convolutions of probability measures. For the dyadic partition D_n of the line into intervals of length 1/2^n, we show that if H(nu*mu,D_n)/n < H(mu,D_n)/n + delta for small delta and large n, then, when restricted to random element of a partition D_i, 0<i<n, either mu is close to uniform or nu is close to atomic. This should be compared to results in additive combinatorics that give the global structure of measures satisfying H(nu*mu,D_n)/n < H(mu,D_n)/n + O(1/n).
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Refinable functions and distributions with integer dilations have been studied extensively since the pioneer work of Daubechies on wavelets. However, very little is known about refinable functions and distributions with non-integer dilations, particularly concerning its regularity. In this paper we study the decay of the Fourier transform of refinable functions and distributions. We prove that uniform decay can be achieved for any dilation. This leads to the existence of refinable functions that can be made arbitrarily smooth for any given dilation factor. We exploit the connection between algebraic properties of dilation factors and the regularity of refinable functions and distributions. Our work can be viewed as a continuation of the work of Erdös [P. Erdös, On the smoothness properties of a family of Bernoulli convolutions, Amer. J. Math. 62 (1940) 180–186], Kahane [J.-P. Kahane, Sur la distribution de certaines séries aléatoires, in: Colloque de Théorie des Nombres, Univ. Bordeaux, Bordeaux, 1969, Mém. Soc. Math. France 25 (1971) 119–122 (in French)] and Solomyak [B. Solomyak, On the random series ∑±λn (an Erdös problem), Ann. of Math. (2) 142 (1995) 611–625] on Bernoulli convolutions. We also construct explicitly a class of refinable functions whose dilation factors are certain algebraic numbers, and whose Fourier transforms have uniform decay. This extends a classical result of Garsia [A.M. Garsia, Arithmetic properties of Bernoulli convolutions, Trans. Amer. Math. Soc. 102 (1962) 409–432].
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Let {Si}i=1\{S_i\}_{i=1}^\ell be an iterated function system (IFS) on Rd\R^d with attractor K. Let (Σ,σ)(\Sigma,\sigma) denote the one-sided full shift over the alphabet {1,...,}\{1,..., \ell\}. We define the projection entropy function hπh_\pi on the space of invariant measures on Σ\Sigma associated with the coding map π:ΣK\pi: \Sigma\to K, and develop some basic ergodic properties about it. This concept turns out to be crucial in the study of dimensional properties of invariant measures on K. We show that for any conformal IFS (resp., the direct product of finitely many conformal IFS), without any separation condition, the projection of an ergodic measure under π\pi is always exactly dimensional and, its Hausdorff dimension can be represented as the ratio of its projection entropy to its Lyapunov exponent (resp., the linear combination of projection entropies associated with several coding maps). Furthermore, for any conformal IFS and certain affine IFS, we prove a variational principle between the Hausdorff dimension of the attractors and that of projections of ergodic measures. Comment: 60 pages
Article
In this paper we study the absolute continuity of self-similar measures defined by iterated function systems (IFS) whose contraction ratios are not uniform. We introduce a transversality condition for a multi-parameter family of IFS and study the absolute continuity of the corresponding self-similar measures. Our study is a natural extension of the study of Bernoulli convolutions by Solomyak, Peres, et al.