John von Neumann citáty

John von Neumann bol maďarský matematik židovského pôvodu, ktorý značnou mierou prispel k vedným odborom ako sú kvantová fyzika, funkcionálna analýza, teória množín, ekonomika, informatika, numerická analýza, hydrodynamika, štatistika a mnoho ďalších matematických disciplín.

Bol jedným z najväčších matematikov dvadsiateho storočia, vypracovaním princípov fungovania počítačov mal rozhodujúci vplyv na vývoj sveta. Je považovaný za otca jednej z najdôležitejších oblastí dnešných ekonomických vied a matematiky, a tým je teória hier.

Iné jeho známe objavy sú aplikácia operačnej teórie v kvantovej mechanike a celulárny automat.

Spolu s Edwardom Tellerom a Stanislawom Ulmanom sa zaoberal aj jadrovou fyzikou a vytvorili základné predpoklady termonukleárnych reakcií a vodíkovej bomby.

Jeho osobnosť a myslenie - spoločne s jeho priateľmi: L.Szilárdom, E.Wignerom, E.Tellerom, P.Erdősom a ďalšími, výrazne prispeli k vzniku zvláštnej legendy, podľa ktorej mimozemšťania pristáli v centre Budapešti a pohybovali sa po svete ako maďarskí vedci. Ich americkí kolegovia ich preto prezývali "The Martians" . Wikipedia  

✵ 28. december 1903 – 8. február 1957
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John von Neumann: Citáty v angličtine

“If people do not believe that mathematics is simple, it is only because they do not realize how complicated life is.”

Remark made by von Neumann as keynote speaker at the first national meeting of the Association for Computing Machinery in 1947, as mentioned by Franz L. Alt at the end of "Archaeology of computers: Reminiscences, 1945--1947", Communications of the ACM, volume 15, issue 7, July 1972, special issue: Twenty-fifth anniversary of the Association for Computing Machinery, p. 694.

“Young man, in mathematics you don't understand things. You just get used to them.”

Reply, according to Dr. Felix T. Smith of Stanford Research Institute, to a physicist friend who had said "I'm afraid I don't understand the method of characteristics," as quoted in The Dancing Wu Li Masters: An Overview of the New Physics (1979) by Gary Zukav, Bantam Books, p. 208, footnote.

“You don't have to be responsible for the world that you're in.”

Advice given by von Neumann to Richard Feynman as quoted in "Los Alamos from Below" in Surely You're Joking, Mr. Feynman! (1985).

“I think that it is a relatively good approximation to truth — which is much too complicated to allow anything but approximations — that mathematical ideas originate in empirics.”

"The Mathematician", in The Works of the Mind (1947) edited by R. B. Heywood, University of Chicago Press, Chicago
Kontext: I think that it is a relatively good approximation to truth — which is much too complicated to allow anything but approximations — that mathematical ideas originate in empirics. But, once they are conceived, the subject begins to live a peculiar life of its own and is … governed by almost entirely aesthetical motivations. In other words, at a great distance from its empirical source, or after much "abstract" inbreeding, a mathematical subject is in danger of degeneration. Whenever this stage is reached the only remedy seems to me to be the rejuvenating return to the source: the reinjection of more or less directly empirical ideas.

“In the second place, and more important, no one really knows what entropy really is, so in a debate you will always have the advantage.”

Suggesting to Claude Shannon a name for his new uncertainty function, as quoted in Scientific American Vol. 225 No. 3, (1971), p. 180.
Kontext: You should call it entropy, for two reasons. In the first place your uncertainty function has been used in statistical mechanics under that name, so it already has a name. In the second place, and more important, no one really knows what entropy really is, so in a debate you will always have the advantage.

“Any one who considers arithmetical methods of producing random digits is, of course, in a state of sin.”

On mistaking pseudorandom number generators for being truly "random" — this quote is often erroneously interpreted to mean that von Neumann was against the use of pseudorandom numbers, when in reality he was cautioning about misunderstanding their true nature while advocating their use. From "Various techniques used in connection with random digits" by John von Neumann in Monte Carlo Method (1951) edited by A.S. Householder, G.E. Forsythe, and H.H. Germond <!-- National Bureau of Standards Applied Mathematics Series, 12 (Washington, D.C.: U.S. Government Printing Office, 1951): 36-38. -->
Kontext: Any one who considers arithmetical methods of producing random digits is, of course, in a state of sin. For, as has been pointed out several times, there is no such thing as a random number — there are only methods to produce random numbers, and a strict arithmetic procedure of course is not such a method.

“A large part of mathematics which becomes useful developed with absolutely no desire to be useful, and in a situation where nobody could possibly know in what area it would become useful; and there were no general indications that it ever would be so.”

"The Role of Mathematics in the Sciences and in Society" (1954) an address to Princeton alumni, published in John von Neumann : Collected Works (1963) edited by A. H. Taub <!-- Macmillan, New York -->; also quoted in Out of the Mouths of Mathematicians : A Quotation Book for Philomaths (1993) by R. Schmalz
Kontext: A large part of mathematics which becomes useful developed with absolutely no desire to be useful, and in a situation where nobody could possibly know in what area it would become useful; and there were no general indications that it ever would be so. By and large it is uniformly true in mathematics that there is a time lapse between a mathematical discovery and the moment when it is useful; and that this lapse of time can be anything from 30 to 100 years, in some cases even more; and that the whole system seems to function without any direction, without any reference to usefulness, and without any desire to do things which are useful.

“If you say why not bomb them tomorrow, I say why not today? If you say today at five o' clock, I say why not one o' clock?”

As quoted in "The Passing of a Great Mind" by Clay Blair, Jr., in LIFE Magazine (25 February 1957), p. 96

“When we talk mathematics, we may be discussing a secondary language built on the primary language of the nervous system.”

As quoted in John von Neumann, 1903-1957 (1958) by John C. Oxtoby and B. J. Pettis, p. 128

“The goys have proven the following theorem…”

Statement at the start of a classroom lecture, as quoted in 1,911 Best Things Anyone Ever Said (1988) by Robert Byrne.

“There probably is a God. Many things are easier to explain if there is than if there isn't.”

As quoted in John Von Neumann : The Scientific Genius Who Pioneered the Modern Computer, Game Theory, Nuclear Deterrence and Much More (1992) by Norman Macrae, p. 379

“With four parameters I can fit an elephant, and with five I can make him wiggle his trunk.”

Attributed to von Neumann by Enrico Fermi, as quoted by Freeman Dyson in "A meeting with Enrico Fermi" in Nature 427 (22 January 2004) p. 297 http://dx.doi.org/10.1038/427297a

“It is just as foolish to complain that people are selfish and treacherous as it is to complain that the magnetic field does not increase unless the electric field has a curl. Both are laws of nature.”

As quoted "John von Neumann (1903 - 1957)" by Eugene Wigner, in Year book of the American Philosophical Society (1958); later in Symmetries and Reflections : Scientific Essays of Eugene P. Wigner (1967), p. 261

“You wake me up early in the morning to tell me that I'm right? Please wait until I'm wrong.”

As quoted by Jacob Bronowski in The Ascent of Man TV series

“Some people confess guilt to claim credit for the sin.”

As quoted in John Von Neumann: The Scientific Genius Who Pioneered the Modern Computer, Game Theory, Nuclear Deterrence, and Much More (2016) by Norman Macrae, p. 352 in response to Oppenheimer's 'destroyer of worlds' quote.