Sierpinski-type fractals are differentiably trivial

IF 0.9 4区数学 Q2 Mathematics

Annales Academiae Scientiarum Fennicae-Mathematica Pub Date : 2019-06-01 DOI:10.5186/AASFM.2019.4460

E. Durand-Cartagena, Jasun Gong, J. Jaramillo

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引用次数: 0

Abstract

In this note we study generalized differentiability of functions on a class of fractals in Euclidean spaces. Such sets are not necessarily self-similar, but satisfy a weaker “scale-similar” property; in particular, they include the non self similar carpets introduced by Mackay–Tyson– Wildrick [12] but with different scale ratios. Specifically we identify certain geometric criteria for these fractals and, in the case that they have zero Lebesgue measure, we show that such fractals cannot support nonzero derivations in the sense of Weaver [16]. As a result (Theorem 26) such fractals cannot support Alberti representations and in particular, they cannot be Lipschitz differentiability spaces in the sense of Cheeger [3] and Keith [9]. 1. Motivation First order differentiable calculus has been extended from smooth manifolds to abstract metric spaces in many ways, by many authors. In this context, one important property of a metric space is the validity of Rademacher’s theorem, i.e. that Lipschitz functions are almost everywhere (a.e.) differentiable with respect to a choice of coordinates on that space. (For this reason, such spaces are known as Lipschitz differentiability spaces in the recent literature, e.g. [1, 2, 4] and said to have a measurable differentiable structure in earlier literature, e.g. [9, 11, 14].) The search for such a property naturally leads to questions of compatibility between a metric space and the choice of a Borel measure on that space. Even the case of Euclidean spaces has been addressed only recently. A result of De Phillipis and Rindler [5, Thm. 1.14] states that if Rademacher’s Theorem is true for a Radon measure μ on R, then μ must be absolutely continuous to m-dimensional Lebesgue measure. Here we address the case when μ is singular. As we will see, there is a large class of fractal sets, which we call Sierpiński-type fractals, for which Lipschitz functions do not even enjoy partial a.e. differentiability on the support of their natural measures. https://doi.org/10.5186/aasfm.2019.446

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sierpinski型分形是可微平凡的

本文研究了欧氏空间中一类分形函数的广义可微性。这样的集合不一定是自相似的，但满足一个较弱的“尺度相似”性质;其中特别包括Mackay-Tyson - Wildrick[12]推出的不同尺度比例的非自相似地毯。具体来说，我们确定了这些分形的某些几何准则，并且在它们具有零勒贝格测度的情况下，我们表明这些分形不能支持Weaver意义上的非零衍生[16]。因此(定理26)这样的分形不能支持Alberti表示，特别是它们不能是Cheeger[3]和Keith[9]意义上的Lipschitz可微空间。1. 动机一阶可微微积分已被许多作者以多种方式从光滑流形推广到抽象度量空间。在这种情况下，度量空间的一个重要性质是Rademacher定理的有效性，即Lipschitz函数对于该空间上的坐标选择几乎处处(即)可微。(因此，在最近的文献中，这样的空间被称为Lipschitz微导空间，例如[1,2,4]，并且在早期的文献中被认为具有可测量的微导结构，例如[9,11,14]。)寻找这样的性质自然会导致度量空间和在该空间上选择Borel度量之间的兼容性问题。即使是欧几里得空间的情况也只是最近才得到解决。De Phillipis和Rindler [5, Thm. 1.14]的结果表明，如果Rademacher定理对R上的Radon测度μ成立，则μ必须绝对连续于m维勒贝格测度。这里我们讨论μ是单数的情况。正如我们将看到的，有一大类分形集合，我们称之为Sierpiński-type分形，对于这些分形集合，Lipschitz函数在其自然测度的支持下甚至不具有部分a.e.可微性。https://doi.org/10.5186/aasfm.2019.446

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来源期刊

Annales Academiae Scientiarum Fennicae-Mathematica 数学-数学

CiteScore

1.30

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Annales Academiæ Scientiarum Fennicæ Mathematica is published by Academia Scientiarum Fennica since 1941. It was founded and edited, until 1974, by P.J. Myrberg. Its editor is Olli Martio. AASF publishes refereed papers in all fields of mathematics with emphasis on analysis.