Intrinsic density, asymptotic computability, and stochasticity

Justin Miller
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引用次数: 1

Abstract

Abstract There are many computational problems which are generally “easy” to solve but have certain rare examples which are much more difficult to solve. One approach to studying these problems is to ignore the difficult edge cases. Asymptotic computability is one of the formal tools that uses this approach to study these problems. Asymptotically computable sets can be thought of as almost computable sets, however every set is computationally equivalent to an almost computable set. Intrinsic density was introduced as a way to get around this unsettling fact, and which will be our main focus. Of particular interest for the first half of this dissertation are the intrinsically small sets, the sets of intrinsic density $0$ . While the bulk of the existing work concerning intrinsic density was focused on these sets, there were still many questions left unanswered. The first half of this dissertation answers some of these questions. We proved some useful closure properties for the intrinsically small sets and applied them to prove separations for the intrinsic variants of asymptotic computability. We also completely separated hyperimmunity and intrinsic smallness in the Turing degrees and resolved some open questions regarding the relativization of intrinsic density. For the second half of this dissertation, we turned our attention to the study of intermediate intrinsic density. We developed a calculus using noncomputable coding operations to construct examples of sets with intermediate intrinsic density. For almost all $r\in (0,1)$ , this construction yielded the first known example of a set with intrinsic density r which cannot compute a set random with respect to the r-Bernoulli measure. Motivated by the fact that intrinsic density coincides with the notion of injection stochasticity, we applied these techniques to study the structure of the more well-known notion of MWC-stochasticity. Abstract prepared by Justin Miller. E-mail: jmille74@nd.edu URL: https://curate.nd.edu/show/6t053f4938w
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内禀密度,渐近可计算性和随机性
有许多计算问题通常很容易解决,但有一些罕见的例子很难解决。研究这些问题的一种方法是忽略困难的边缘情况。渐近可计算性是使用这种方法研究这些问题的形式化工具之一。渐近可计算的集合可以被认为是几乎可计算的集合,然而每一个集合在计算上都等价于一个几乎可计算的集合。引入内在密度是为了绕过这个令人不安的事实,这将是我们的主要关注点。本文的前半部分特别关注本质小集,即本质密度$0$的集合。虽然现有的关于内在密度的大部分工作都集中在这些集合上,但仍然有许多问题没有得到解答。本文的前半部分回答了其中的一些问题。我们证明了固有小集的一些有用的闭包性质,并将它们应用于证明渐近可计算的固有变分的分离。我们还在图灵度中完全分离了超免疫和本征小,解决了本征密度相对化的一些开放性问题。在本文的后半部分,我们将重点放在了中间本征密度的研究上。我们发展了一种微积分,使用不可计算的编码操作来构造具有中间内禀密度的集合的例子。对于几乎所有的$r\in(0,1)$,这种构造产生了第一个已知的具有本征密度r的集合的例子,它不能计算相对于r-伯努利测度的随机集合。由于内禀密度与注入随机性的概念一致,我们应用这些技术来研究更著名的mwc -随机性概念的结构。摘要由Justin Miller准备。电子邮件:jmille74@nd.edu URL: https://curate.nd.edu/show/6t053f4938w
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POUR-EL’S LANDSCAPE CATEGORICAL QUANTIFICATION POINCARÉ-WEYL’S PREDICATIVITY: GOING BEYOND A TOPOLOGICAL APPROACH TO UNDEFINABILITY IN ALGEBRAIC EXTENSIONS OF John MacFarlane, Philosophical Logic: A Contemporary Introduction, Routledge Contemporary Introductions to Philosophy, Routledge, New York, and London, 2021, xx + 238 pp.
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