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John Myhill was born on 11 August, 1923 in Birmingham, United Kingdom, is a British mathematician. Discover John Myhill's Biography, Age, Height, Physical Stats, Dating/Affairs, Family and career updates. Learn How rich is he in this year and how he spends money? Also learn how he earned most of networth at the age of 63 years old?

Popular As N/A
Occupation N/A
Age 63 years old
Zodiac Sign Leo
Born 11 August 1923
Birthday 11 August
Birthplace Birmingham, United Kingdom
Date of death 15 February, 1987
Died Place N/A
Nationality United Kingdom

We recommend you to check the complete list of Famous People born on 11 August. He is a member of famous mathematician with the age 63 years old group.

John Myhill Height, Weight & Measurements

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Who Is John Myhill's Wife?

His wife is Akiko Kino (died 1983)

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Wife Akiko Kino (died 1983)
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John Myhill Net Worth

His net worth has been growing significantly in 2023-2024. So, how much is John Myhill worth at the age of 63 years old? John Myhill’s income source is mostly from being a successful mathematician. He is from United Kingdom. We have estimated John Myhill's net worth, money, salary, income, and assets.

Net Worth in 2024 $1 Million - $5 Million
Salary in 2024 Under Review
Net Worth in 2023 Pending
Salary in 2023 Under Review
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Source of Income mathematician

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Timeline

1902

The Russell–Myhill Paradox or Russell–Myhill antinomy, discovered by Bertrand Russell in 1902 (and discussed in his The Principles of Mathematics, 1903) and rediscovered by Myhill in 1958, concerns systems of logic in which logical propositions can be members of classes, and can also be about classes; for instance, a proposition P can "state the product" of a class C, meaning that proposition P asserts that all propositions contained in class C are true.

In such a system, the class of propositions that state the product of classes that do not include them is paradoxical.

For, if proposition P states the product of this class, an inconsistency arises regardless of whether P does or does not belong to the class it describes.

In music theory, Myhill's property is a mathematical property of musical scales described by John Clough and Gerald Myerson and named by them after Myhill.

1923

John R. Myhill Sr. (11 August 1923 – 15 February 1987) was a British mathematician.

1949

Myhill received his Ph.D. from Harvard University under Willard Van Orman Quine in 1949.

1966

He was professor at SUNY Buffalo from 1966 until his death in 1987.

He also taught at several other universities.

His son, also called John Myhill, is a professor of linguistics in the English department of the University of Haifa in Israel.

In the theory of formal languages, the Myhill–Nerode theorem, proven by Myhill and Anil Nerode, characterizes the regular languages as the languages that have only finitely many inequivalent prefixes.

In computability theory, the Rice–Myhill–Shapiro theorem, more commonly known as Rice's theorem, states that, for any nontrivial property P of partial functions, it is undecidable to determine whether a given Turing machine computes a function with property P.

The Myhill isomorphism theorem is a computability-theoretic analogue of the Cantor–Bernstein–Schroeder theorem that characterizes the recursive isomorphisms of pairs of sets.

In the theory of cellular automata, Myhill is known for proving (along with E. F. Moore) the Garden of Eden theorem, stating that a cellular automaton has a configuration with no predecessor if and only if it has two different asymptotic configurations which evolve to the same configuration.

He is also known for posing the firing squad synchronization problem of designing an automaton that, starting from a single non-quiescent cell, evolves to a configuration in which all cells reach the same non-quiescent state at the same time; this problem was again solved by Moore.

In constructive set theory, Myhill is known for proposing an axiom system that avoids the axiom of choice and the law of the excluded middle, known as intuitionistic Zermelo–Fraenkel.

He also developed a constructive set theory based on natural numbers, functions, and sets, rather than (as in many other foundational theories) basing it purely on sets.