Turing and the discovery of computability

Turing's Legacy Pub Date : 2014-05-01 DOI:10.1017/CBO9781107338579.014

R. Soare

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引用次数: 2

Abstract

Abstract . In §1 we give a short overview for a general audience of Godel, Church, Turing, and the discovery of computability in the 1930s. In the later sections we mention a series of our previous papers where a more detailed analysis of computability, Turing's work, and extensive lists of references can be found. The sections from §2—§9 challenge the conventional wisdom and traditional ideas found in many books and papers on computability theory. They are based on a half century of my study of the subject beginning with Church at Princeton in the 1960s, and on a careful rethinking of these traditional ideas. The references in all my papers and books are given in the format, author [year], as in Turing [1936], in order that the references are easily identified without consulting the bibliography and are uniform over all papers. A complete bibliography of historical articles from all my books and papers on computabilityis given on the page as explained in §10. §1. A very brief overview of computability . 1.1. Hilbert's programs . Around 1880 Georg Cantor, a German mathematician, invented naive set theory. A small fraction of this is sometimes taught to elementary school children. It was soon discovered that this naive set theory was inconsistent because it allowed unbounded set formation, such as the set of all sets. David Hilbert, the world's foremost mathematician from 1900 to 1930, defended Cantor's set theory but suggested a formal axiomatic approach to eliminate the inconsistencies. He proposed two programs.

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图灵和可计算性的发现

摘要在§1中，我们为一般读者简要概述了哥德尔、丘奇、图灵和20世纪30年代可计算性的发现。在后面的章节中，我们提到了我们之前的一系列论文，其中可以找到更详细的可计算性分析，图灵的工作和广泛的参考文献列表。从§2 -§9的部分挑战了许多关于可计算性理论的书籍和论文中的传统智慧和传统思想。它们是基于我从20世纪60年代在普林斯顿大学的丘奇开始的半个世纪的研究，以及对这些传统观念的仔细反思。我所有的论文和书籍中的参考文献都以作者[年份]的格式给出，就像图灵[1936]一样，以便在不查阅参考书目的情况下很容易识别参考文献，并且在所有论文中都是统一的。我所有关于可计算性的书籍和论文的历史文章的完整参考书目在§10中给出。§1。对可计算性的简要概述。1.1. 希尔伯特的程序。大约在1880年，德国数学家乔治·康托尔发明了朴素集合论。其中的一小部分有时会教授给小学生。人们很快发现这种朴素集合论是不一致的，因为它允许无界集合的形成，比如集合的集合。大卫·希尔伯特(David Hilbert)是1900年至1930年间世界上最重要的数学家，他为康托尔的集合论辩护，但提出了一种正式的公理化方法来消除不一致性。他提出了两个方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Turing's Legacy

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