Alonzo Church (nonfiction): Difference between revisions
No edit summary |
No edit summary |
||
| Line 1: | Line 1: | ||
[[File:Alonzo_Church.jpg|thumb|Alonzo Church.]]'''Alonzo Church''' (June 14, 1903 – August 11, 1995) was an American [[Mathematician (nonfiction)|mathematician]] and logician who made major contributions to mathematical logic and the foundations of theoretical computer science. | [[File:Alonzo_Church.jpg|thumb|Alonzo Church.]]'''Alonzo Church''' (June 14, 1903 – August 11, 1995) was an American [[Mathematician (nonfiction)|mathematician]] and logician who made major contributions to mathematical logic and the foundations of theoretical computer science. He is best known for the [[Lambda calculus (nonfiction)|lambda calculus]], Church–Turing thesis, proving the undecidability of the Entscheidungsproblem, Frege–Church ontology, and the Church–Rosser theorem. | ||
Church attended Princeton University where he was an exceptional student, publishing his first paper, on Lorentz transformations, and graduating in 1924 with a degree in mathematics. He stayed at Princeton, earning a Ph.D. in mathematics in three years under [[Oswald Veblen (nonfiction)|Oswald Veblen]]. | Church attended Princeton University where he was an exceptional student, publishing his first paper, on Lorentz transformations, and graduating in 1924 with a degree in mathematics. He stayed at Princeton, earning a Ph.D. in mathematics in three years under [[Oswald Veblen (nonfiction)|Oswald Veblen]]. | ||
| Line 7: | Line 7: | ||
Church made important contributions to mathematics and logic, including: | Church made important contributions to mathematics and logic, including: | ||
* His [[Lambda calculus (nonfiction)|lambda calculus]]. | |||
* His proof that the Entscheidungsproblem, which asks for a decision procedure to determine the truth of arbitrary propositions in a first-order mathematical theory, is undecidable. This is known as Church's theorem. | * His proof that the Entscheidungsproblem, which asks for a decision procedure to determine the truth of arbitrary propositions in a first-order mathematical theory, is undecidable. This is known as Church's theorem. | ||
* His proof that Peano arithmetic is undecidable. | * His proof that Peano arithmetic is undecidable. | ||
| Line 13: | Line 14: | ||
He was the founding editor of the ''Journal of Symbolic Logic'', editing its reviews section until 1979. | He was the founding editor of the ''Journal of Symbolic Logic'', editing its reviews section until 1979. | ||
The lambda calculus emerged in his 1936 paper showing the unsolvability of the Entscheidungsproblem. This result preceded [[Alan Turing (nonfiction)|Alan Turing]]'s work on the halting problem, which also demonstrated the existence of a problem unsolvable by mechanical means. Church and Turing then showed that the lambda calculus and the Turing machine used in Turing's halting problem were equivalent in capabilities, and subsequently demonstrated a variety of alternative "mechanical processes for computation." This resulted in the Church–Turing thesis. | The [[Lambda calculus (nonfiction)|lambda calculus]] emerged in his 1936 paper showing the unsolvability of the Entscheidungsproblem. This result preceded [[Alan Turing (nonfiction)|Alan Turing]]'s work on the halting problem, which also demonstrated the existence of a problem unsolvable by mechanical means. Church and Turing then showed that the lambda calculus and the Turing machine used in Turing's halting problem were equivalent in capabilities, and subsequently demonstrated a variety of alternative "mechanical processes for computation." This resulted in the Church–Turing thesis. | ||
The efforts for automatically generating a controller implementation from specifications originates from his ideas. | The efforts for automatically generating a controller implementation from specifications originates from his ideas. | ||
| Line 37: | Line 38: | ||
* [[Alan Turing (nonfiction)]] | * [[Alan Turing (nonfiction)]] | ||
* [[Lambda calculus (nonfiction)]] | |||
* [[Mathematician (nonfiction)]] | * [[Mathematician (nonfiction)]] | ||
* [[Oswald Veblen (nonfiction)]] - Teacher | * [[Oswald Veblen (nonfiction)]] - Teacher | ||
Revision as of 11:41, 18 November 2017
Alonzo Church (June 14, 1903 – August 11, 1995) was an American mathematician and logician who made major contributions to mathematical logic and the foundations of theoretical computer science. He is best known for the lambda calculus, Church–Turing thesis, proving the undecidability of the Entscheidungsproblem, Frege–Church ontology, and the Church–Rosser theorem.
Church attended Princeton University where he was an exceptional student, publishing his first paper, on Lorentz transformations, and graduating in 1924 with a degree in mathematics. He stayed at Princeton, earning a Ph.D. in mathematics in three years under Oswald Veblen.
He married Mary Julia Kuczinski in 1925 and the couple had three children, Alonzo Church, Jr. (1929), Mary Ann (1933) and Mildred (1938).
Church made important contributions to mathematics and logic, including:
- His lambda calculus.
- His proof that the Entscheidungsproblem, which asks for a decision procedure to determine the truth of arbitrary propositions in a first-order mathematical theory, is undecidable. This is known as Church's theorem.
- His proof that Peano arithmetic is undecidable.
- His articulation of what has come to be known as the Church–Turing thesis.
He was the founding editor of the Journal of Symbolic Logic, editing its reviews section until 1979.
The lambda calculus emerged in his 1936 paper showing the unsolvability of the Entscheidungsproblem. This result preceded Alan Turing's work on the halting problem, which also demonstrated the existence of a problem unsolvable by mechanical means. Church and Turing then showed that the lambda calculus and the Turing machine used in Turing's halting problem were equivalent in capabilities, and subsequently demonstrated a variety of alternative "mechanical processes for computation." This resulted in the Church–Turing thesis.
The efforts for automatically generating a controller implementation from specifications originates from his ideas.
The lambda calculus influenced the design of the LISP programming language and functional programming languages in general.
The Church encoding is named in his honor.
Many of Church's doctoral students have led distinguished careers, including C. Anthony Anderson, Peter B. Andrews, George A. Barnard, David Berlinski, William W. Boone, Martin Davis, Alfred L. Foster, Leon Henkin, John G. Kemeny, Stephen C. Kleene, Simon B. Kochen, Maurice L'Abbé, Isaac Malitz, Gary R. Mar, Michael O. Rabin, Nicholas Rescher, Hartley Rogers, Jr., J. Barkley Rosser, Dana Scott, Raymond Smullyan, and [[Alan Turing.
He also worked on philosophy of language (see e. g. Church 1970).
In the News
Fiction cross-reference
Nonfiction cross-reference
- Alan Turing (nonfiction)
- Lambda calculus (nonfiction)
- Mathematician (nonfiction)
- Oswald Veblen (nonfiction) - Teacher
External links:
- Alonzo Church @ Wikipedia