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Church-Turing thesis : ウィキペディア英語版
Church–Turing thesis

In computability theory, the Church–Turing thesis (also known as the Turing–Church thesis, the Church–Turing conjecture, Church's thesis, Church's conjecture, and Turing's thesis) is a hypothesis ("thesis") about the nature of computable functions. In simple terms, the Church–Turing thesis states that a function on the natural numbers is computable in an informal sense (i.e., computable by a human being using a pencil-and-paper method, ignoring resource limitations) if and only if it is computable by a Turing machine. The thesis is named after American mathematician Alonzo Church and the British mathematician Alan Turing.
Before the precise definition of computable function, mathematicians often used the informal term effectively calculable to describe functions that are computable by paper-and-pencil methods. In the 1930s, several independent attempts were made to formalize the notion of computability:
* In 1933, Austrian-American mathematician Kurt Gödel, with Jacques Herbrand, created a formal definition of a class called general recursive functions. The class of general recursive functions is the smallest class of functions (possibly with more than one argument) which includes all constant functions, projections, the successor function, and which is closed under function composition and recursion.
* In 1936, Alonzo Church created a method for defining functions called the λ-calculus. Within λ-calculus, he defined an encoding of the natural numbers called the Church numerals. A function on the natural numbers is called λ-computable if the corresponding function on the Church numerals can be represented by a term of the λ-calculus.
* Also in 1936, before learning of Church's work, Alan Turing created a theoretical model for machines, now called Turing machines, that could carry out calculations from inputs by manipulating symbols on a tape. Given a suitable encoding of the natural numbers as sequences of symbols, a function on the natural numbers is called Turing computable if some Turing machine computes the corresponding function on encoded natural numbers.
Church〔Church 1934:90 footnote in Davis 1952〕 and Turing〔Turing 1936–7 in Davis 1952:149〕 proved that these three formally defined classes of computable functions coincide: a function is λ-computable if and only if it is Turing computable if and only if it is ''general recursive''. This has led mathematicians and computer scientists to believe that the concept of computability is accurately characterized by these three equivalent processes. Other formal attempts to characterize computability have subsequently strengthened this belief (see below).
On the other hand, the Church–Turing thesis states that the above three formally-defined classes of computable functions coincide with the ''informal'' notion of an effectively calculable function. Since, as an informal notion, the concept of effective calculability does not have a formal definition, the thesis, although it has near-universal acceptance, cannot be formally proven.
Since its inception, variations on the original thesis have arisen, including statements about what can physically be realized by a computer in our universe (Physical Church-Turing Thesis) and what can be efficiently computed (Complexity-Theoretic Church–Turing Thesis). These variations are not due to Church or Turing, but arise from later work in complexity theory and digital physics. The thesis also has implications for the philosophy of mind.
==Statement in Church's and Turing's words==

J. B. Rosser (1939) addresses the notion of "effective computability" as follows: "Clearly the existence of CC and RC (Church's and Rosser's proofs) presupposes a precise definition of 'effective'. 'Effective method' is here used in the rather special sense of a method each step of which is precisely predetermined and which is certain to produce the answer in a finite number of steps".〔Rosser 1939 in Davis 1965:225〕 Thus the adverb-adjective "effective" is used in a sense of "1a: producing a decided, decisive, or desired effect", and "capable of producing a result".〔Merriam Webster's Ninth New Collegiate Dictionary〕〔"See also" (Merriam-Webster's Online Dictionary, 11th Edition ) (accessed July 26, 2014), which also gives these definitions for "effective" -- the first (a decided, decisive, or desired effect" ) as the definition for sense "1a" of the word "effective", and the second (of producing a result" ) as part of the "Synonym Discussion of EFFECTIVE" there, (in the introductory part, where it summarizes the similarities between the meanings of the words "effective", "effectual", "efficient", and "efficacious").〕
In the following, the words "effectively calculable" will mean "produced by any intuitively 'effective' means whatsoever" and "effectively computable" will mean "produced by a Turing-machine or equivalent mechanical device". Turing's "definitions" given in a footnote in his 1939 Ph.D. thesis ''Systems of Logic Based on Ordinals'', supervised by Church, are virtually the same:
:" We shall use the expression 'computable function' to mean a function calculable by a machine, and let 'effectively calculable' refer to the intuitive idea without particular identification with any one of these definitions."〔A. M. Turing (1939), (''Systems of Logic Based on Ordinals'' ) (Ph.D. thesis). Princeton University. p. 8.〕
The thesis can be stated as follows:
:''Every effectively calculable function is a computable function''.〔Gandy (Gandy 1980 in Barwise 1980:123) states it this way: ''What is effectively calculable is computable.'' He calls this "Church's Thesis", a peculiar choice of moniker.〕
Turing stated it this way:
:"It was stated ... that 'a function is effectively calculable if its values can be found by some purely mechanical process.' We may take this literally, understanding that by a purely mechanical process one which could be carried out by a machine. The development ... leads to ... an identification of computability with effective calculability." († is the footnote above, ibid.)

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