05818nam 22006613 450 991091579630332120240723141844.01-4704-7544-8(MiAaPQ)EBC30671911(Au-PeEL)EBL30671911(PPN)272106828(CKB)27902413300041(EXLCZ)992790241330004120230804d2023 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierOverlapping Iterated Function Systems from the Perspective of Metric Number Theory1st ed.Providence :American Mathematical Society,2023.©2023.1 online resource (108 pages)Memoirs of the American Mathematical Society Series ;v.287Print version: Baker, Simon Overlapping Iterated Function Systems from the Perspective of Metric Number Theory Providence : American Mathematical Society,c2023 9781470464400 Cover -- Title page -- Chapter 1. Introduction -- 1.1. Attractors generated by iterated function systems -- 1.2. Diophantine approximation and metric number theory -- 1.3. Two families of limsup sets -- 1.3.1. The set _{Φ}( ,Ψ) -- 1.3.2. The set _{Φ}( ,\m,ℎ) -- Chapter 2. Statement of results -- 2.1. Parameterised families with variable contraction ratios -- 2.2. Parameterised families with variable translations -- 2.3. A specific family of IFSs -- 2.3.1. New methods for distinguishing between the overlapping behaviour of IFSs -- 2.4. The CS property and absolute continuity. -- 2.5. Overlapping self-conformal sets -- 2.6. Structure of the paper -- Chapter 3. Preliminary results -- 3.1. A general framework -- 3.1.1. Verifying the hypothesis of Proposition 3.1. -- 3.1.2. The non-existence of a Khintchine like result -- 3.2. Full measure statements -- Chapter 4. Applications of Proposition 3.1 -- 4.1. Proof of Theorem 2.2 -- 4.1.1. Bernoulli convolutions -- 4.1.2. The {0,1,3} problem -- 4.2. Proof of Theorem 2.9 -- Chapter 5. A specific family of IFSs -- Chapter 6. Proof of Theorem 2.15 -- Chapter 7. Proof of Theorem 2.16 -- Chapter 8. Applications of the mass transference principle -- Chapter 9. Examples -- 9.1. IFSs satisfying the CS property -- 9.2. The non-existence of Khintchine like behaviour without exact overlaps -- Chapter 10. Final discussion and open problems -- Acknowledgments -- Bibliography -- Back Cover."In this paper we develop a new approach for studying overlapping iterated function systems. This approach is inspired by a famous result due to Khintchine from Diophantine approximation which shows that for a family of limsup sets, their Lebesgue measure is determined by the convergence or divergence of naturally occurring volume sums. For many parameterised families of overlapping iterated function systems, we prove that a typical member will exhibit similar Khintchine like behaviour. Families of iterated function systems that our results apply to include those arising from Bernoulli convolutions, the [numbers] problem, and affine contractions with varying translation parameter. As a by-product of our analysis we obtain new proofs of some well known results due to Solomyak on the absolute continuity of Bernoulli convolutions, and when the attractor in the [numbers] problem has positive Lebesgue measure. For each [equation] we let [phi]t be the iterated function system given by [equation]. We prove that either [phi]t contains an exact overlap, or we observe Khintchine like behaviour. Our analysis shows that by studying the metric properties of limsup sets, we can distinguish between the overlapping behaviour of iterated function systems in a way that is not available to us by simply studying properties of self-similar measures. Last of all, we introduce a property of an iterated function system that we call being consistently separated with respect to a measure. We prove that this property implies that the pushforward of the measure is absolutely continuous. We include several explicit examples of consistently separated iterated function systems"--Provided by publisher.Memoirs of the American Mathematical Society SeriesIterative methods (Mathematics)Number theoryMeasure theoryDiophantine approximationFractalsDynamicsMathematical modelsNumber theory -- Probabilistic theory: distribution modulo $1$; metric theory of algorithms -- Diophantine approximationmscMeasure and integration -- Classical measure theory -- FractalsmscDynamical systems and ergodic theory -- Smooth dynamical systems: general theory -- Dimension theory of dynamical systemsmscIterative methods (Mathematics)Number theory.Measure theory.Diophantine approximation.Fractals.DynamicsMathematical models.Number theory -- Probabilistic theory: distribution modulo $1$; metric theory of algorithms -- Diophantine approximation.Measure and integration -- Classical measure theory -- Fractals.Dynamical systems and ergodic theory -- Smooth dynamical systems: general theory -- Dimension theory of dynamical systems.518/.26518.2611K6028A8037C45mscBaker Simon1387917MiAaPQMiAaPQMiAaPQBOOK9910915796303321Overlapping Iterated Function Systems from the Perspective of Metric Number Theory4303367UNINA