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Revision as of 10:34, 24 October 2020 editYoyomaya (talk | contribs)67 edits Changed 35 to numerous because only some of the challenges Guy poses are coincidences, many are not.← Previous edit Latest revision as of 14:06, 14 April 2024 edit undoVziel (talk | contribs)444 editsNo edit summary 
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{{Other uses|Law of small numbers (disambiguation)}} {{Other uses|Law of small numbers (disambiguation)}}


In ], the "'''Strong Law of Small Numbers'''" is the humorous law that proclaims, in the words of ] (1988):<ref>{{Cite journal In ], the "'''strong law of small numbers'''" is the ]ous law that proclaims, in the words of ] (1988):<ref>{{cite journal
| last = Guy | first = Richard K. | author-link = Richard K. Guy
|last=Guy
| doi = 10.2307/2322249
|first=Richard K.
| issue = 8
|authorlink=Richard K. Guy
| journal = ]
|year=1988
| jstor = 2322249
|title=The Strong Law of Small Numbers
| pages = 697–712
|journal=]
| title = The strong law of small numbers
|volume=95
| url = https://www.maa.org/sites/default/files/pdf/upload_library/22/Ford/Guy697-712.pdf
|issue=8
| volume = 95
|pages=697–712
| year = 1988}}</ref>
|issn=0002-9890
|pmid=
|pmc=
|doi=10.2307/2322249
|bibcode=
|oclc=
|id=
|url=http://www.maa.org/sites/default/files/pdf/upload_library/22/Ford/Guy697-712.pdf
|accessdate=2009-08-30
|jstor=2322249
}}
</ref>
{{quote|There aren't enough small numbers to meet the many demands made of them.}} {{quote|There aren't enough small numbers to meet the many demands made of them.}}
In other words, any given small number appears in far more contexts than may seem reasonable, leading to many apparently surprising coincidences in mathematics, simply because small numbers appear so often and yet are so few. Earlier (1980) this "law" was reported by ].<ref>Gardner, M. "Mathematical Games: Patterns in Primes are a Clue to the Strong Law of Small Numbers." Sci. Amer. 243, 18-28, Dec. 1980.</ref> Guy's paper gives numerous examples in support of this thesis. In other words, any given small number appears in far more contexts than may seem reasonable, leading to many apparently surprising coincidences in mathematics, simply because small numbers appear so often and yet are so few. Earlier (1980) this "law" was reported by ].<ref>{{cite journal
| last = Gardner | first = Martin | author-link = Martin Gardner
| date = December 1980
| department = Mathematical Games
| issue = 6
| journal = ]
| jstor = 24966473
| pages = 18–28
| title = Patterns in primes are a clue to the strong law of small numbers
| volume = 243}}</ref> Guy's subsequent 1988 paper of the same title gives numerous examples in support of this thesis. (This paper earned him the MAA ].)


==Second strong law of small numbers==
Guy also formulated the '''Second Strong Law of Small Numbers''':
] as an example. The number of {{nowrap|points (''n''),}} {{nowrap|chords (''c'')}} and {{nowrap|regions (''r<sub>G</sub>'')}}. The first five terms for the number of regions follow a simple sequence, broken by the sixth term.]]
{{quote|When two numbers look equal, it ain't necessarily so!<ref name=SSL>{{Cite journal

|last=Guy
Guy also formulated a '''second strong law of small numbers''':
|first=Richard K.
{{quote|When two numbers look equal, it ain't necessarily so!<ref name=SSL>{{cite journal
|authorlink=Richard K. Guy
| last = Guy | first = Richard K. | author-link = Richard K. Guy
|year=1990
| doi = 10.2307/2691503
|title=The Second Strong Law of Small Numbers
| issue = 1
|journal=] | journal = ]
|volume=63
| jstor = 2691503
|issue=1
|pages=3–20 | pages = 3–20
| title = The second strong law of small numbers
|doi=10.2307/2691503
| volume = 63
|jstor=2691503
| year = 1990}}</ref>}}
}}

</ref>}}
Guy explains the latter law by the way of examples: he cites numerous sequences for which observing a subset of the first few members may lead to a wrong guess about the generating formula or law for the sequence. Many of the examples are the observations of other mathematicians.<ref name=SSL/> Guy explains this latter law by the way of examples: he cites numerous sequences for which observing the first few members may lead to a wrong guess about the generating formula or law for the sequence. Many of the examples are the observations of other mathematicians.<ref name=SSL/>

One example Guy gives is the conjecture that <math>2^p-1</math> is prime—in fact, a ]—when <math>p</math> is prime; but this conjecture, while true for <math>p</math> = 2, 3, 5 and 7, fails for <math>p</math> = 11 (and for many other values).

Another relates to the ]: primes congruent to 3 modulo 4 appear to be more numerous than those congruent to 1; however this is false, and first ceases being true at 26861.

A geometric example concerns ] (pictured), which appears to have the solution of <math>2^{n-1}</math> for <math>n</math> points, but this pattern breaks at and above <math>n=6</math>.


==See also== ==See also==

Latest revision as of 14:06, 14 April 2024

Humorous mathematical law For other uses, see Law of small numbers (disambiguation).

In mathematics, the "strong law of small numbers" is the humorous law that proclaims, in the words of Richard K. Guy (1988):

There aren't enough small numbers to meet the many demands made of them.

In other words, any given small number appears in far more contexts than may seem reasonable, leading to many apparently surprising coincidences in mathematics, simply because small numbers appear so often and yet are so few. Earlier (1980) this "law" was reported by Martin Gardner. Guy's subsequent 1988 paper of the same title gives numerous examples in support of this thesis. (This paper earned him the MAA Lester R. Ford Award.)

Second strong law of small numbers

Guy gives Moser's circle problem as an example. The number of points (n), chords (c) and regions (rG). The first five terms for the number of regions follow a simple sequence, broken by the sixth term.

Guy also formulated a second strong law of small numbers:

When two numbers look equal, it ain't necessarily so!

Guy explains this latter law by the way of examples: he cites numerous sequences for which observing the first few members may lead to a wrong guess about the generating formula or law for the sequence. Many of the examples are the observations of other mathematicians.

One example Guy gives is the conjecture that 2 p 1 {\displaystyle 2^{p}-1} is prime—in fact, a Mersenne prime—when p {\displaystyle p} is prime; but this conjecture, while true for p {\displaystyle p} = 2, 3, 5 and 7, fails for p {\displaystyle p} = 11 (and for many other values).

Another relates to the prime number race: primes congruent to 3 modulo 4 appear to be more numerous than those congruent to 1; however this is false, and first ceases being true at 26861.

A geometric example concerns Moser's circle problem (pictured), which appears to have the solution of 2 n 1 {\displaystyle 2^{n-1}} for n {\displaystyle n} points, but this pattern breaks at and above n = 6 {\displaystyle n=6} .

See also

Notes

  1. Guy, Richard K. (1988). "The strong law of small numbers" (PDF). The American Mathematical Monthly. 95 (8): 697–712. doi:10.2307/2322249. JSTOR 2322249.
  2. Gardner, Martin (December 1980). "Patterns in primes are a clue to the strong law of small numbers". Mathematical Games. Scientific American. 243 (6): 18–28. JSTOR 24966473.
  3. ^ Guy, Richard K. (1990). "The second strong law of small numbers". Mathematics Magazine. 63 (1): 3–20. doi:10.2307/2691503. JSTOR 2691503.

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