von Neumann, John - définition. Qu'est-ce que von Neumann, John
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Qu'est-ce (qui) est von Neumann, John - définition

HUNGARIAN-AMERICAN MATHEMATICIAN AND POLYMATH (1903–1957)
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  • [[Flow chart]] from von Neumann's "Planning and coding of problems for an electronic computing instrument", published in 1947
  • Implosion mechanism
  • Los Alamos]] ID badge photo
  • Von Neumann's gravestone
  • History of approaches that led to NBG set theory
  • Friedrich-Wilhelms-Universität Berlin]] announcing Neumann's lectures on the theory of functions II, axiomatic set theory and mathematical logic, the mathematical colloquium, review of recent work in quantum mechanics, special functions of mathematical physics and Hilbert's proof theory. He also lectured on the theory of relativity, set theory, integral equations and analysis of infinitely many variables.
  • Von Neumann's birthplace, at 16 Báthory Street, Budapest. Since 1968, it has housed the [[John von Neumann Computer Society]].
  • pmid=8942052}}</ref> Three generations of machine are shown: the second has nearly finished constructing the third. The lines running to the right are the tapes of genetic instructions, which are copied along with the body of the machines.
  • [[Operation Redwing]] nuclear test in July 1956
  • A simple configuration in von Neumann's cellular automaton. A binary signal is passed repeatedly around the blue wire loop, using excited and quiescent ''ordinary transmission states''. A confluent cell duplicates the signal onto a length of red wire consisting of ''special transmission states''. The signal passes down this wire and constructs a new cell at the end. This particular signal (1011) codes for an east-directed special transmission state, thus extending the red wire by one cell each time. During construction, the new cell passes through several sensitised states, directed by the binary sequence.
  • The von Neumann crater, on the far side of the Moon

von Neumann, John      
John von Neumann         
<person> /jon von noy'mahn/ Born 1903-12-28, died 1957-02-08. A Hungarian-born mathematician who did pioneering work in quantum physics, game theory, and computer science. He contributed to the USA's Manhattan Project that built the first atomic bomb. von Neumann was invited to Princeton University in 1930, and was a mathematics professor at the {Institute for Advanced Studies} from its formation in 1933 until his death. From 1936 to 1938 Alan Turing was a visitor at the Institute and completed a Ph.D. dissertation under von Neumann's supervision. This visit occurred shortly after Turing's publication of his 1934 paper "On Computable Numbers with an Application to the Entscheidungs-problem" which involved the concepts of logical design and the universal machine. von Neumann must have known of Turing's ideas but it is not clear whether he applied them to the design of the IAS Machine ten years later. While serving on the BRL Scientific Advisory Committee, von Neumann joined the developers of ENIAC and made some critical contributions. In 1947, while working on the design for the successor machine, EDVAC, von Neumann realized that ENIAC's lack of a centralized control unit could be overcome to obtain a rudimentary stored program computer. He also proposed the fetch-execute cycle. His ideas led to what is now often called the von Neumann architecture. John von Neumannmbsclass/is2000/hall_of_fame/vonneuma.htm">http://sis.pitt.edu/John von Neumannmbsclass/is2000/hall_of_fame/vonneuma.htm. John von Neumannhistory/VonNeumann.html">http://ei.cs.vt.edu/John von Neumannhistory/VonNeumann.html. John von Neumannmike/comphist/54nord/">http://ftp.arl.mil/John von Neumannmike/comphist/54nord/. (2004-01-14)
John von Neumann Theory Prize         
AWARD
John Von Neumann Theory Prize; Von Neumann Theory Prize; John von neumann prize
The John von Neumann Theory Prize of the Institute for Operations Research and the Management Sciences (INFORMS)

Wikipédia

John von Neumann

John von Neumann ( von NOY-mən; Hungarian: Neumann János Lajos [ˈnɒjmɒn ˈjaːnoʃ ˈlɒjoʃ]; December 28, 1903 – February 8, 1957) was a Hungarian-American mathematician, physicist, computer scientist, engineer and polymath. He was regarded as having perhaps the widest coverage of any mathematician of his time and was said to have been "the last representative of the great mathematicians who were equally at home in both pure and applied mathematics". He integrated pure and applied sciences.

Von Neumann made major contributions to many fields, including mathematics (mathematical logic, measure theory, functional analysis, ergodic theory, group theory, lattice theory, representation theory, operator algebras, matrix theory, geometry, and numerical analysis), physics (quantum mechanics, hydrodynamics & ballistics, nuclear physics and quantum statistical mechanics), economics (game theory and general equilibrium theory), computing (Von Neumann architecture, linear programming, numerical meteorology, scientific computing, self-replicating machines, stochastic computing), and statistics. He was a pioneer of the application of operator theory to quantum mechanics in the development of functional analysis, and a key figure in the development of game theory and the concepts of cellular automata, the universal constructor and the digital computer.

Von Neumann published over 150 papers: about 60 in pure mathematics, 60 in applied mathematics, 20 in physics, and the remainder on special mathematical subjects or non-mathematical subjects. His last work, an unfinished manuscript written while he was dying, was later published in book form as The Computer and the Brain.

His analysis of the structure of self-replication preceded the discovery of the structure of DNA. In a shortlist of facts about his life he submitted to the National Academy of Sciences, he wrote, "The part of my work I consider most essential is that on quantum mechanics, which developed in Göttingen in 1926, and subsequently in Berlin in 1927–1929. Also, my work on various forms of operator theory, Berlin 1930 and Princeton 1935–1939; on the ergodic theorem, Princeton, 1931–1932."

During World War II, von Neumann worked on the Manhattan Project with theoretical physicist Edward Teller, mathematician Stanislaw Ulam and others, problem-solving key steps in the nuclear physics involved in thermonuclear reactions and the hydrogen bomb. He developed the mathematical models behind the explosive lenses used in the implosion-type nuclear weapon and coined the term "kiloton" (of TNT) as a measure of the explosive force generated. During this time and after the war, he consulted for a vast number of organizations including the Office of Scientific Research and Development, the Army's Ballistic Research Laboratory, the Armed Forces Special Weapons Project and the Oak Ridge National Laboratory.

At the peak of his influence in the 1950s he was the chair for a number of critical Defense Department committees including the Strategic Missile Evaluation Committee and the ICBM Scientific Advisory Committee. He was also a member of the influential Atomic Energy Commission in charge of all atomic energy development in the country. He played a key role alongside Bernard Schriever and Trevor Gardner in contributing to the design and development of the United States' first ICBM programs. During this time he was considered the nation's foremost expert on nuclear weaponry and the leading defense scientist at the Pentagon. As a Hungarian émigré, concerned that the Soviets would achieve nuclear superiority, he designed and promoted the policy of mutually assured destruction to limit the arms race.

In honor of his achievements and contributions to the modern world, he was named in 1999 the Financial Times Person of the Century, as a representative of the century's characteristic ideal that the power of the mind could shape the physical world, and of the "intellectual brilliance and human savagery" that defined the 20th century.