"페르마 소수"의 두 판 사이의 차이

수학노트
둘러보기로 가기 검색하러 가기
 
(사용자 2명의 중간 판 12개는 보이지 않습니다)
1번째 줄: 1번째 줄:
<h5 style="line-height: 3.42em; margin-top: 0px; margin-right: 0px; margin-bottom: 0px; margin-left: 0px; color: rgb(34, 61, 103); font-family: 'malgun gothic', dotum, gulim, sans-serif; font-size: 1.16em; background-image: ; background-color: initial; background-position: 0px 100%;">이 항목의 스프링노트 원문주소</h5>
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==개요==
  
* [[페르마 소수|페르마소수]]
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*   페르마소수란 <math>F_n= 2^{2^n}+1</math> 형태의 소수
 
 
 
 
 
 
 
 
 
 
<h5 style="BACKGROUND-POSITION: 0px 100%; FONT-SIZE: 1.16em; MARGIN: 0px; COLOR: rgb(34,61,103); LINE-HEIGHT: 3.42em; FONT-FAMILY: 'malgun gothic', dotum, gulim, sans-serif;">개요</h5>
 
 
 
*   페르마소수란 <math>F_n= 2^{2^n}+1</math> 형태의 소수<br>
 
 
** 3,5,17,257, 65537 다섯 가지만 알려져 있음.
 
** 3,5,17,257, 65537 다섯 가지만 알려져 있음.
페르마는  <math>F_n= 2^{2^n}+1</math> 가 모두 소수일 것이라 추측하였으나, 후에 [[오일러(1707-1783)|오일러]]는 반례를 발견<br><math>F_5=641 \times 6700417</math><br>
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페르마는  <math>F_n= 2^{2^n}+1</math> 모두 소수일 것이라 추측하였으나, 후에 [[오일러(1707-1783)|오일러]]는 반례를 발견:<math>F_5=641 \times 6700417</math>
 
 
 
 
 
 
 
 
 
 
<h5>정다각형의 작도</h5>
 
 
 
* 정n각형이 자와 컴파스로 작도가능 <math>\iff</math> <math>n=2^k p_1 p_2 \cdots p_r</math>  (k ,r은 0이상의 정수, <math>p_1, p_2, \cdots, p_r</math> 은 서로 다른 페르마소수)
 
* [[정다각형의 작도]]와 [[가우스와 정17각형의 작도]] 항목을 참조
 
 
 
 
 
 
 
 
 
  
<h5 style="BACKGROUND-POSITION: 0px 100%; FONT-SIZE: 1.16em; MARGIN: 0px; COLOR: rgb(34,61,103); LINE-HEIGHT: 3.42em; FONT-FAMILY: 'malgun gothic', dotum, gulim, sans-serif;">상위 주제</h5>
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==정다각형의 작도==
  
 
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* 정n각형이 자와 컴파스로 작도가능 <math>\iff</math> <math>n=2^k p_1 p_2 \cdots p_r</math>  (k ,r은 0이상의 정수, <math>p_1, p_2, \cdots, p_r</math> 은 서로 다른 페르마소수)
 +
* [[정다각형의 작도]]와 [[가우스와 정17각형의 작도]] 항목을 참조
  
==== 하위페이지 ====
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* [[1964250|0 토픽용템플릿]]<br>
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** [[2060652|0 상위주제템플릿]]<br>
 
  
 
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==역사==
  
<h5>재미있는 사실</h5>
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* [[수학사 연표]] 
  
 
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==관련된 항목들==
 
 
<h5>역사</h5>
 
 
 
* [[수학사연표 (역사)|수학사연표]]<br>  <br>
 
 
 
<h5 style="BACKGROUND-POSITION: 0px 100%; FONT-SIZE: 1.16em; MARGIN: 0px; COLOR: rgb(34,61,103); LINE-HEIGHT: 3.42em; FONT-FAMILY: 'malgun gothic', dotum, gulim, sans-serif;">많이 나오는 질문과 답변</h5>
 
 
 
* 네이버 지식인<br>
 
**   <br>
 
** http://kin.search.naver.com/search.naver?where=kin_qna&query=
 
** http://kin.search.naver.com/search.naver?where=kin_qna&query=
 
** http://kin.search.naver.com/search.naver?where=kin_qna&query=<br>
 
 
 
<h5>관련된 고교수학 또는 대학수학</h5>
 
 
 
 
 
 
 
 
 
 
 
<h5>관련된 다른 주제들</h5>
 
  
 
* [[정다각형의 작도]]
 
* [[정다각형의 작도]]
 
* [[메르센 소수]]
 
* [[메르센 소수]]
  
 
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[[분류:소수]]
 
 
<h5>관련도서 및 추천도서</h5>
 
 
 
*  도서내검색<br>
 
** http://books.google.com/books?q=
 
** http://book.daum.net/search/contentSearch.do?query=
 
*  도서검색<br>
 
** http://www.amazon.com/s/ref=nb_ss_gw?url=search-alias%3Dstripbooks&field-keywords=
 
** http://book.daum.net/search/mainSearch.do?query=
 
 
 
 
 
 
 
 
 
 
 
<h5 style="BACKGROUND-POSITION: 0px 100%; FONT-SIZE: 1.16em; MARGIN: 0px; COLOR: rgb(34,61,103); LINE-HEIGHT: 3.42em; FONT-FAMILY: 'malgun gothic', dotum, gulim, sans-serif;">수학용어번역</h5>
 
 
 
* [http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=&fstr= 대한수학회 수학 학술 용어집]<br>
 
** http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=eng_term&fstr=
 
* [http://kms.or.kr/home/kor/board/bulletin_list_subject.asp?bulletinid={D6048897-56F9-43D7-8BB6-50B362D1243A}&boardname=%BC%F6%C7%D0%BF%EB%BE%EE%C5%E4%B7%D0%B9%E6&globalmenu=7&localmenu=4 대한수학회 수학용어한글화 게시판]
 
 
 
 
 
 
 
<h5>참고할만한 자료</h5>
 
 
 
* http://ko.wikipedia.org/wiki/
 
* http://en.wikipedia.org/wiki/
 
* http://www.wolframalpha.com/input/?i=
 
* [http://navercast.naver.com/science/list 네이버 오늘의과학]
 
 
 
 
 
 
 
 
 
 
 
<h5>관련기사</h5>
 
 
 
*  네이버 뉴스 검색 (키워드 수정)<br>
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
 
 
 
 
 
 
 
 
 
 
 
<h5>블로그</h5>
 
 
 
* 구글 블로그 검색 http://blogsearch.google.com/blogsearch?q=
 
* 네이버 블로그 검색 http://cafeblog.search.naver.com/search.naver?where=post&sm=tab_jum&query=
 
* 트렌비 블로그 검색 http://www.trenb.com/search.qst?q=
 
* 스프링노트 http://www.springnote.com/search?stype=all&q=
 
  
 
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== 노트 ==
  
<h5>이미지 검색</h5>
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===말뭉치===
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# In fact, it is known that numbers of this form are not prime for values of n from 5 through 30, placing doubt on the existence of any Fermat primes for values of n > 4.<ref name="ref_edbed968">[https://www.britannica.com/science/Fermat-prime Fermat prime | mathematics]</ref>
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# Fermat conjectured in 1650 that every Fermat number is prime and Eisenstein in 1844 proposed as a problem the proof that there are an infinite number of Fermat primes (Ribenboim 1996, p. 88).<ref name="ref_21863434">[https://mathworld.wolfram.com/FermatPrime.html Fermat Prime -- from Wolfram MathWorld]</ref>
 +
# Based on these results, one might conjecture (as did Fermat) that all Fermat numbers are prime.<ref name="ref_77005ae2">[https://artofproblemsolving.com/wiki/index.php/Fermat_prime Art of Problem Solving]</ref>
 +
# To find the Fermat number F n for an integer n , you first find m = 2 n , and then calculate 2 m + 1.<ref name="ref_7c2c701e">[https://www.techtarget.com/whatis/definition/Fermat-prime Definition from WhatIs.com]</ref>
 +
# Surprisingly, Fermat primes arise in deciding whether a regular n-gon (a convex polygon with n equal sides) can be constructed with a compass and a straightedge.<ref name="ref_a529a8a6">[https://sites.millersville.edu/bikenaga/number-theory/fermat-numbers/fermat-numbers.pdf Fermat numbers]</ref>
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# No fermat primes beyond (cid:8)4 have been found.<ref name="ref_a8ac433d">[http://www.math.ualberta.ca/~isaac/math324/s12/fermat_numbers.pdf Math 324 summer 2012]</ref>
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# There are in(cid:12)nitely many distinct Fermat numbers, each of which is divisible by an odd prime, and since any two Fermat numbers are relatively prime, these odd primes must all be distinct.<ref name="ref_a8ac433d" />
 +
# + 1 is a Fermat number; such primes are called Fermat primes.<ref name="ref_44f407e6">[https://en.wikipedia.org/wiki/Fermat_number Fermat number]</ref>
 +
# From the second equation, we can deduce Goldbach's theorem (named after Christian Goldbach): no two Fermat numbers share a common integer factor greater than 1.<ref name="ref_44f407e6" />
 +
# The sum of the reciprocals of all the Fermat numbers (sequence A051158 OEIS) is irrational.<ref name="ref_44f407e6" />
 +
# Indeed, the first five Fermat numbers F 0 , ..., F 4 are easily shown to be prime.<ref name="ref_44f407e6" />
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# The only known Fermat primes are the first five Fermat numbers: F 0 =3, F 1 =5, F 2 =17, F 3 =257, and F 4 =65537.<ref name="ref_fbf82f86">[https://primes.utm.edu/glossary/xpage/FermatNumber.html The Prime Glossary: Fermat number]</ref>
 +
# It only takes two trial divisions to find this factor because Euler showed that every divisor of a Fermat number F n with n greater than 2 has the form k.2n+1+1 (exponent improved to n+2 by Lucas).<ref name="ref_fbf82f86" />
 +
# Now we know that all of the Fermat numbers are composite for the other n less than 31.<ref name="ref_fbf82f86" />
 +
# In other words, every prime of the form 2k + 1 (other than 2 = 20 + 1 ) is a Fermat number, and such primes are called Fermat primes.<ref name="ref_e81de8fb">[http://www.scientificlib.com/en/Mathematics/LX/FermatNumber.html Fermat number]</ref>
 +
# From the last equation, we can deduce Goldbach's theorem (named after Christian Goldbach): no two Fermat numbers share a common integer factor greater than 1.<ref name="ref_e81de8fb" />
 +
# The sum of the reciprocals of all the Fermat numbers (sequence A051158 in OEIS) is irrational.<ref name="ref_e81de8fb" />
 +
# Indeed, the first five Fermat numbers F 0 ,...,F 4 are easily shown to be prime.<ref name="ref_e81de8fb" />
 +
# Indeed, even today, no other Fermat numbers are known to be prime!<ref name="ref_c596120d">[https://johncarlosbaez.wordpress.com/2019/02/05/fermat-primes-and-pascals-triangle/ Fermat Primes and Pascal’s Triangle]</ref>
 +
# Also show that every product of distinct Fermat numbers corresponds to a row of Pascal’s triangle mod 2.<ref name="ref_c596120d" />
 +
# Now, Gauss showed that we can construct a regular n-gon using straight-edge and compass if n is a prime Fermat number.<ref name="ref_c596120d" />
 +
# Wantzel went further and showed that if n is odd, we can construct a regular n-gon using straight-edge and compass if and only if n is a product of distinct Fermat primes.<ref name="ref_c596120d" />
 +
# There are two definitions of the Fermat number.<ref name="ref_25205313">[https://mathworld.wolfram.com/FermatNumber.html Fermat Number -- from Wolfram MathWorld]</ref>
 +
# The much more commonly encountered Fermat numbers are a special case, given by the binomial number of the form .<ref name="ref_25205313" />
 +
# Fermat conjectured in 1650 that every Fermat number is prime and Eisenstein proposed as a problem in 1844 the proof that there are an infinite number of Fermat primes (Ribenboim 1996, p. 88).<ref name="ref_25205313" />
 +
# At present, however, only composite Fermat numbers are known for .<ref name="ref_25205313" />
 +
# In other words, every prime of the form 2 n +1 is a Fermat number, and such primes are called Fermat primes.<ref name="ref_17d186c1">[https://www.rieselprime.de/ziki/Fermat_number Fermat number]</ref>
 +
# From the last equation, we can deduce Goldbach's theorem: no two Fermat numbers share a common factor.<ref name="ref_17d186c1" />
 +
# Indeed, the first five Fermat numbers F 0 ,..., F 4 are easily shown to be prime.<ref name="ref_17d186c1" />
 +
# Although it is widely believed that there are only finitely many Fermat primes, it should be noted that there are some experts who disagree (John Cosgrave: "Fermat 6").<ref name="ref_17d186c1" />
 +
# A019434 List of Fermat primes: primes of form, for someIt is conjectured that there are only 5 terms.<ref name="ref_b3f9ea5b">[https://oeis.org/wiki/Fermat_primes Fermat primes]</ref>
 +
# Numbers of the form F n =22n+1 are now called Fermat numbers*, and when they’re prime, they’re called Fermat primes.<ref name="ref_bfc52e99">[https://blogs.scientificamerican.com/roots-of-unity/extrapolation-gone-wrong-the-case-of-the-fermat-primes/ Extrapolation Gone Wrong: the Case of the Fermat Primes]</ref>
 +
# Fermat conjectured that all Fermat numbers are prime.<ref name="ref_bfc52e99" />
 +
# In 1732, about 70 years after Fermat's death, Leonhard Euler factored the 5th Fermat number into 641×6,700,417, disproving Fermat’s conjecture.<ref name="ref_bfc52e99" />
 +
# So far, the only known Fermat primes are the ones that were known to Fermat.<ref name="ref_bfc52e99" />
 +
# Is there a formula or a way to know which of the Fermat numbers are prime?.<ref name="ref_dc7c427d">[https://math.stackexchange.com/questions/563390/fermat-numbers-are-they-all-prime Fermat numbers. Are they all prime?]</ref>
 +
# Prologue What are the known Fermat primes?<ref name="ref_b2c9d49a">[https://arxiv.org/pdf/1605.01371 This is the extended version of a paper that has appeared in the Mathematical Intelligencer. The final publication is available]</ref>
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# Taking Fermat prime to mean prime of the form 2n + 1, there are six known Fermat primes, namely those for n = 0, 1, 2, 4, 8, 16.<ref name="ref_b2c9d49a" />
 +
# We shall pronounce the last letter of Fermats name, as he did, when we include 2 among the Fermat primes, as he did.<ref name="ref_b2c9d49a" />
 +
# The Fermat number Fn is either prime or not prime: the question of how to approximate the probability of primality for a general n is delicate.<ref name="ref_b2c9d49a" />
 +
# Fb;n = b2n + 1 and are particularly interesting since they have many characteristics of the heavily studied standard Fermat numbers Fn = F2;n.<ref name="ref_a10cb56f">[https://www.ams.org/journals/mcom/2002-71-238/S0025-5718-01-01350-3/S0025-5718-01-01350-3.pdf Mathematics of computation]</ref>
 +
# The \Proth" program was created in 1997 to extend the search for large factors of Fermat numbers.<ref name="ref_a10cb56f" />
 +
# They are called Fermat numbers, named after the French mathematician Pierre de Fermat (1601 1665) who first studied numbers in this form.<ref name="ref_8f117ada">[https://wstein.org/edu/2010/414/projects/tsang.pdf Fermat]</ref>
 +
# We will not be able to answer this question in this paper, but we will prove some basic properties of Fermat numbers and discuss their primality and divisibility.<ref name="ref_8f117ada" />
 +
# Primes in this form are called Fermat primes.<ref name="ref_8f117ada" />
 +
# Up-to-date there are only five known Fermat primes.<ref name="ref_8f117ada" />
 +
# Moreover, no other Fermat number is known to be prime for n > 4 , so now it is conjectured that those are all prime Fermat numbers.<ref name="ref_6428f90c">[https://planetmath.org/fermatnumbers Fermat numbers]</ref>
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# In honour of the inspired pioneers, the numbers of the form 2n-1 are now called the Mersenne numbers and the numbers of the form 2n+1 the Fermat numbers.<ref name="ref_e35d89c0">[http://yves.gallot.pagesperso-orange.fr/primes/ Generalized Fermat Primes Search]</ref>
 +
# The search for Mersenne and Fermat primes has been greatly extended since the 17th century.<ref name="ref_e35d89c0" />
 +
# Today, all the Mersenne primes having less than 2,000,000 digits are known and all the Fermat primes up to 2,000,000,000 digits!<ref name="ref_e35d89c0" />
 +
# In 1994, R. Crandall and B. Fagin discovered that the Discrete Weighted Transforms could be used to double the speed of the search for Mersenne and Fermat numbers.<ref name="ref_e35d89c0" />
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# Those are the only primes below 100,000 that I could show must be primitive for all but finitely many Fermat primes.<ref name="ref_9d437e74">[https://www.ocf.berkeley.edu/~wwu/cgi-bin/yabb/YaBB.cgi?board=riddles_putnam;action=display;num=1204796915 Fermat Primes and the number 7]</ref>
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# Fermat numbers are named after Pierre de Fermat.<ref name="ref_a462b554">[https://kids.kiddle.co/Fermat_number Fermat number facts for kids]</ref>
 +
# Every prime of the form 2n + 1 is a Fermat number, and such primes are called Fermat primes.<ref name="ref_a462b554" />
 +
# Fermat numbers can be calculated recursively: To get the Nth number, multiply all Fermat numbers before it, and add two to the result.<ref name="ref_a462b554" />
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# Two previous posts (here and here) present an alternative proof that there are infinitely many prime numbers using the Fermat numbers.<ref name="ref_e5ed5592">[https://exploringnumbertheory.wordpress.com/2016/10/25/fermat-numbers/ Exploring Number Theory]</ref>
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# Specifically, the proof is accomplished by pointing out that the prime factors of the Fermat numbers form an infinite set.<ref name="ref_e5ed5592" />
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# The numbers grow very rapidly since each Fermat number is obtained by raising 2 to a power of 2.<ref name="ref_e5ed5592" />
 +
# He demonstrated that the first 5 Fermat numbers , , , , are prime and conjectured that all Fermat numbers are prime.<ref name="ref_e5ed5592" />
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# Chapter 4 Fermat and Mersenne Primes 4.1 Fermat primes Theorem 4.1.<ref name="ref_7befcda2">[https://www.maths.tcd.ie/pub/Maths/Courseware/NumberTheory/FermatMersenne.pdf Chapter 4]</ref>
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# Fermat conjectured that the Fermat numbers are all prime.<ref name="ref_7befcda2" />
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# We will come back to their solution shortly as we must first introduce the notion of a Fermat prime!<ref name="ref_62f9f1ec">[https://vrs.amsi.org.au/fermat-primes-gauss-wantzel/ Fermat Primes and the Gauss-Wantzel Theorem]</ref>
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# In the 1600s, a mathematician and lawyer named Pierre de Fermat studied numbers of the form 2^n+1 (where n=2^k) which are now called Fermat numbers.<ref name="ref_62f9f1ec" />
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# So, he conjectured that all Fermat numbers are prime.<ref name="ref_62f9f1ec" />
 +
# Funnily enough, it was shown by Leonhard Euler in 1732 (another famous mathematician), that only the next Fermat number is not prime.<ref name="ref_62f9f1ec" />
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# It is still open whether there exist innitely many Fermat primes or innitely many composite Fermat numbers.<ref name="ref_0b05fdb4">[https://arxiv.org/pdf/2204.08302 MINIMALITY CONDITIONS EQUIVALENT TO THE FINITUDE OF FERMAT AND MERSENNE PRIMES]</ref>
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# Especially, the formula for modulo Fermat primes is given. MSC2010: 11A07.<ref name="ref_9c963bc5">[https://arxiv.org/pdf/1601.06509 The largest cycles consist by the quadratic residues and Fermat primes]</ref>
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# For the Fermat primes, i.e., the prime numbers of the form p 22k ` 1, we have Lppq 1. Proof.<ref name="ref_9c963bc5" />
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# We have veried it for k 0, 1, 2, 3, 4, the known Fermat primes.<ref name="ref_9c963bc5" />
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# As of 2021, the only known Fermat primes are F0 = 3, F1 = 5, F2 = 17, F3 = 257, and F4 = 65537.<ref name="ref_49cdcbc7">[https://arxiv.org/pdf/1912.12088 MINIMALITY OF TOPOLOGICAL MATRIX GROUPS AND FERMAT PRIMES]</ref>
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# For an odd prime p the following conditions are equivalent: (1) p is a Fermat prime; (2) SL(p 1, (Q, p)) is minimal; (3) SL(p 1, Q(i)) is minimal.<ref name="ref_49cdcbc7" />
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# We determine all the Carmichael numbers m with a Fermat prime factor such that L = 2P 2, where k N and P is an odd prime number.<ref name="ref_f1f90697">[https://arxiv.org/pdf/1710.01321 On the finiteness of Carmichael numbers with Fermat factors and L = 2αP 2.]</ref>
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# We assume that m is divisible by at least one of the known Fermat prime numbers.<ref name="ref_f1f90697" />
 +
# If m is divisible by one of the known Fermat primes, then m must be one of the following 11 Carmichael numbers.<ref name="ref_f1f90697" />
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# Let 2 R R 22, there exists a generalized Fermat prime p = r2 2 be an integer.<ref name="ref_25a71c73">[https://arxiv.org/pdf/1502.02800 FAST INTEGER MULTIPLICATION USING GENERALIZED FERMAT PRIMES]</ref>
 +
# The key concept of our algorithm is the use of a chain of generalized Fermat primes (of the form r2 +1) to handle recursive calls.<ref name="ref_25a71c73" />
 +
# First, we encode integers to be multiplied as integers modulo generalized Fermat primes, and not as polynomials.<ref name="ref_25a71c73" />
 +
# Section 4 studies generalized Fermat primes, and their relation to the Bateman-Horn conjecture.<ref name="ref_25a71c73" />
 +
# 1. Introduction + 1 for n The Fermat numbers are given by Fn = 22n 0.<ref name="ref_4a2a6fd4">[https://arxiv.org/pdf/2102.00906 ON UPPER BOUNDS FOR THE COUNT OF ELITE PRIMES Matthew Just]</ref>
 +
# Notice that the rst ve Fermat numbers are prime, and it was initially conjectured (by Fermat) that all such num- bers are prime.<ref name="ref_4a2a6fd4" />
 +
# The sixth Fermat number is not prime, and no other Fermat primes are known.<ref name="ref_4a2a6fd4" />
 +
# An ecient test exists to determine whether or not a Fermat number is prime, called Pepins test.<ref name="ref_4a2a6fd4" />
 +
# This characterization uses uniquely values at most equal to tested Fermat number.<ref name="ref_bca905b7">[https://arxiv.org/pdf/2104.04875 A NEW CHARACTERIZATION OF PRIME FERMAT’S NUMBERS]</ref>
 +
# We actually are able to establish the direct implication which is a real important result in the primality tests for Fermat numbers.<ref name="ref_bca905b7" />
 +
# Condition 2m + = pn requires p to be either a Mersenne or Fermat prime.<ref name="ref_4393ff84">[https://arxiv.org/pdf/1809.03328 On Upper Bounds with ABC = 2mpn and ABC = 2mpnqr with p and q as Mersenne or Fermat]</ref>
  
* http://commons.wikimedia.org/w/index.php?title=Special%3ASearch&search=
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===소스===
* http://images.google.com/images?q=
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<references />
* [http://www.artchive.com/ http://www.artchive.com]
 
  
 
 
  
<h5>동영상</h5>
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== 메타데이터 ==
  
* http://www.youtube.com/results?search_type=&search_query=
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===위키데이터===
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* ID :  [https://www.wikidata.org/wiki/Q207264 Q207264]
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===Spacy 패턴 목록===
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* [{'LOWER': 'fermat'}, {'LEMMA': 'prime'}]
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* [{'LOWER': 'fermat'}, {'LEMMA': 'number'}]

2022년 9월 16일 (금) 03:47 기준 최신판

개요

  • 페르마소수란 \(F_n= 2^{2^n}+1\) 형태의 소수
    • 3,5,17,257, 65537 다섯 가지만 알려져 있음.
  • 페르마는 \(F_n= 2^{2^n}+1\) 가 모두 소수일 것이라 추측하였으나, 후에 오일러는 반례를 발견\[F_5=641 \times 6700417\]



정다각형의 작도




역사


관련된 항목들

노트

말뭉치

  1. In fact, it is known that numbers of this form are not prime for values of n from 5 through 30, placing doubt on the existence of any Fermat primes for values of n > 4.[1]
  2. Fermat conjectured in 1650 that every Fermat number is prime and Eisenstein in 1844 proposed as a problem the proof that there are an infinite number of Fermat primes (Ribenboim 1996, p. 88).[2]
  3. Based on these results, one might conjecture (as did Fermat) that all Fermat numbers are prime.[3]
  4. To find the Fermat number F n for an integer n , you first find m = 2 n , and then calculate 2 m + 1.[4]
  5. Surprisingly, Fermat primes arise in deciding whether a regular n-gon (a convex polygon with n equal sides) can be constructed with a compass and a straightedge.[5]
  6. No fermat primes beyond (cid:8)4 have been found.[6]
  7. There are in(cid:12)nitely many distinct Fermat numbers, each of which is divisible by an odd prime, and since any two Fermat numbers are relatively prime, these odd primes must all be distinct.[6]
  8. + 1 is a Fermat number; such primes are called Fermat primes.[7]
  9. From the second equation, we can deduce Goldbach's theorem (named after Christian Goldbach): no two Fermat numbers share a common integer factor greater than 1.[7]
  10. The sum of the reciprocals of all the Fermat numbers (sequence A051158 OEIS) is irrational.[7]
  11. Indeed, the first five Fermat numbers F 0 , ..., F 4 are easily shown to be prime.[7]
  12. The only known Fermat primes are the first five Fermat numbers: F 0 =3, F 1 =5, F 2 =17, F 3 =257, and F 4 =65537.[8]
  13. It only takes two trial divisions to find this factor because Euler showed that every divisor of a Fermat number F n with n greater than 2 has the form k.2n+1+1 (exponent improved to n+2 by Lucas).[8]
  14. Now we know that all of the Fermat numbers are composite for the other n less than 31.[8]
  15. In other words, every prime of the form 2k + 1 (other than 2 = 20 + 1 ) is a Fermat number, and such primes are called Fermat primes.[9]
  16. From the last equation, we can deduce Goldbach's theorem (named after Christian Goldbach): no two Fermat numbers share a common integer factor greater than 1.[9]
  17. The sum of the reciprocals of all the Fermat numbers (sequence A051158 in OEIS) is irrational.[9]
  18. Indeed, the first five Fermat numbers F 0 ,...,F 4 are easily shown to be prime.[9]
  19. Indeed, even today, no other Fermat numbers are known to be prime![10]
  20. Also show that every product of distinct Fermat numbers corresponds to a row of Pascal’s triangle mod 2.[10]
  21. Now, Gauss showed that we can construct a regular n-gon using straight-edge and compass if n is a prime Fermat number.[10]
  22. Wantzel went further and showed that if n is odd, we can construct a regular n-gon using straight-edge and compass if and only if n is a product of distinct Fermat primes.[10]
  23. There are two definitions of the Fermat number.[11]
  24. The much more commonly encountered Fermat numbers are a special case, given by the binomial number of the form .[11]
  25. Fermat conjectured in 1650 that every Fermat number is prime and Eisenstein proposed as a problem in 1844 the proof that there are an infinite number of Fermat primes (Ribenboim 1996, p. 88).[11]
  26. At present, however, only composite Fermat numbers are known for .[11]
  27. In other words, every prime of the form 2 n +1 is a Fermat number, and such primes are called Fermat primes.[12]
  28. From the last equation, we can deduce Goldbach's theorem: no two Fermat numbers share a common factor.[12]
  29. Indeed, the first five Fermat numbers F 0 ,..., F 4 are easily shown to be prime.[12]
  30. Although it is widely believed that there are only finitely many Fermat primes, it should be noted that there are some experts who disagree (John Cosgrave: "Fermat 6").[12]
  31. A019434 List of Fermat primes: primes of form, for someIt is conjectured that there are only 5 terms.[13]
  32. Numbers of the form F n =22n+1 are now called Fermat numbers*, and when they’re prime, they’re called Fermat primes.[14]
  33. Fermat conjectured that all Fermat numbers are prime.[14]
  34. In 1732, about 70 years after Fermat's death, Leonhard Euler factored the 5th Fermat number into 641×6,700,417, disproving Fermat’s conjecture.[14]
  35. So far, the only known Fermat primes are the ones that were known to Fermat.[14]
  36. Is there a formula or a way to know which of the Fermat numbers are prime?.[15]
  37. Prologue What are the known Fermat primes?[16]
  38. Taking Fermat prime to mean prime of the form 2n + 1, there are six known Fermat primes, namely those for n = 0, 1, 2, 4, 8, 16.[16]
  39. We shall pronounce the last letter of Fermats name, as he did, when we include 2 among the Fermat primes, as he did.[16]
  40. The Fermat number Fn is either prime or not prime: the question of how to approximate the probability of primality for a general n is delicate.[16]
  41. Fb;n = b2n + 1 and are particularly interesting since they have many characteristics of the heavily studied standard Fermat numbers Fn = F2;n.[17]
  42. The \Proth" program was created in 1997 to extend the search for large factors of Fermat numbers.[17]
  43. They are called Fermat numbers, named after the French mathematician Pierre de Fermat (1601 1665) who first studied numbers in this form.[18]
  44. We will not be able to answer this question in this paper, but we will prove some basic properties of Fermat numbers and discuss their primality and divisibility.[18]
  45. Primes in this form are called Fermat primes.[18]
  46. Up-to-date there are only five known Fermat primes.[18]
  47. Moreover, no other Fermat number is known to be prime for n > 4 , so now it is conjectured that those are all prime Fermat numbers.[19]
  48. In honour of the inspired pioneers, the numbers of the form 2n-1 are now called the Mersenne numbers and the numbers of the form 2n+1 the Fermat numbers.[20]
  49. The search for Mersenne and Fermat primes has been greatly extended since the 17th century.[20]
  50. Today, all the Mersenne primes having less than 2,000,000 digits are known and all the Fermat primes up to 2,000,000,000 digits![20]
  51. In 1994, R. Crandall and B. Fagin discovered that the Discrete Weighted Transforms could be used to double the speed of the search for Mersenne and Fermat numbers.[20]
  52. Those are the only primes below 100,000 that I could show must be primitive for all but finitely many Fermat primes.[21]
  53. Fermat numbers are named after Pierre de Fermat.[22]
  54. Every prime of the form 2n + 1 is a Fermat number, and such primes are called Fermat primes.[22]
  55. Fermat numbers can be calculated recursively: To get the Nth number, multiply all Fermat numbers before it, and add two to the result.[22]
  56. Two previous posts (here and here) present an alternative proof that there are infinitely many prime numbers using the Fermat numbers.[23]
  57. Specifically, the proof is accomplished by pointing out that the prime factors of the Fermat numbers form an infinite set.[23]
  58. The numbers grow very rapidly since each Fermat number is obtained by raising 2 to a power of 2.[23]
  59. He demonstrated that the first 5 Fermat numbers , , , , are prime and conjectured that all Fermat numbers are prime.[23]
  60. Chapter 4 Fermat and Mersenne Primes 4.1 Fermat primes Theorem 4.1.[24]
  61. Fermat conjectured that the Fermat numbers are all prime.[24]
  62. We will come back to their solution shortly as we must first introduce the notion of a Fermat prime![25]
  63. In the 1600s, a mathematician and lawyer named Pierre de Fermat studied numbers of the form 2^n+1 (where n=2^k) which are now called Fermat numbers.[25]
  64. So, he conjectured that all Fermat numbers are prime.[25]
  65. Funnily enough, it was shown by Leonhard Euler in 1732 (another famous mathematician), that only the next Fermat number is not prime.[25]
  66. It is still open whether there exist innitely many Fermat primes or innitely many composite Fermat numbers.[26]
  67. Especially, the formula for modulo Fermat primes is given. MSC2010: 11A07.[27]
  68. For the Fermat primes, i.e., the prime numbers of the form p 22k ` 1, we have Lppq 1. Proof.[27]
  69. We have veried it for k 0, 1, 2, 3, 4, the known Fermat primes.[27]
  70. As of 2021, the only known Fermat primes are F0 = 3, F1 = 5, F2 = 17, F3 = 257, and F4 = 65537.[28]
  71. For an odd prime p the following conditions are equivalent: (1) p is a Fermat prime; (2) SL(p 1, (Q, p)) is minimal; (3) SL(p 1, Q(i)) is minimal.[28]
  72. We determine all the Carmichael numbers m with a Fermat prime factor such that L = 2P 2, where k N and P is an odd prime number.[29]
  73. We assume that m is divisible by at least one of the known Fermat prime numbers.[29]
  74. If m is divisible by one of the known Fermat primes, then m must be one of the following 11 Carmichael numbers.[29]
  75. Let 2 R R 22, there exists a generalized Fermat prime p = r2 2 be an integer.[30]
  76. The key concept of our algorithm is the use of a chain of generalized Fermat primes (of the form r2 +1) to handle recursive calls.[30]
  77. First, we encode integers to be multiplied as integers modulo generalized Fermat primes, and not as polynomials.[30]
  78. Section 4 studies generalized Fermat primes, and their relation to the Bateman-Horn conjecture.[30]
  79. 1. Introduction + 1 for n The Fermat numbers are given by Fn = 22n 0.[31]
  80. Notice that the rst ve Fermat numbers are prime, and it was initially conjectured (by Fermat) that all such num- bers are prime.[31]
  81. The sixth Fermat number is not prime, and no other Fermat primes are known.[31]
  82. An ecient test exists to determine whether or not a Fermat number is prime, called Pepins test.[31]
  83. This characterization uses uniquely values at most equal to tested Fermat number.[32]
  84. We actually are able to establish the direct implication which is a real important result in the primality tests for Fermat numbers.[32]
  85. Condition 2m + = pn requires p to be either a Mersenne or Fermat prime.[33]

소스

  1. Fermat prime | mathematics
  2. Fermat Prime -- from Wolfram MathWorld
  3. Art of Problem Solving
  4. Definition from WhatIs.com
  5. Fermat numbers
  6. 6.0 6.1 Math 324 summer 2012
  7. 7.0 7.1 7.2 7.3 Fermat number
  8. 8.0 8.1 8.2 The Prime Glossary: Fermat number
  9. 9.0 9.1 9.2 9.3 Fermat number
  10. 10.0 10.1 10.2 10.3 Fermat Primes and Pascal’s Triangle
  11. 11.0 11.1 11.2 11.3 Fermat Number -- from Wolfram MathWorld
  12. 12.0 12.1 12.2 12.3 Fermat number
  13. Fermat primes
  14. 14.0 14.1 14.2 14.3 Extrapolation Gone Wrong: the Case of the Fermat Primes
  15. Fermat numbers. Are they all prime?
  16. 16.0 16.1 16.2 16.3 This is the extended version of a paper that has appeared in the Mathematical Intelligencer. The final publication is available
  17. 17.0 17.1 Mathematics of computation
  18. 18.0 18.1 18.2 18.3 Fermat
  19. Fermat numbers
  20. 20.0 20.1 20.2 20.3 Generalized Fermat Primes Search
  21. Fermat Primes and the number 7
  22. 22.0 22.1 22.2 Fermat number facts for kids
  23. 23.0 23.1 23.2 23.3 Exploring Number Theory
  24. 24.0 24.1 Chapter 4
  25. 25.0 25.1 25.2 25.3 Fermat Primes and the Gauss-Wantzel Theorem
  26. MINIMALITY CONDITIONS EQUIVALENT TO THE FINITUDE OF FERMAT AND MERSENNE PRIMES
  27. 27.0 27.1 27.2 The largest cycles consist by the quadratic residues and Fermat primes
  28. 28.0 28.1 MINIMALITY OF TOPOLOGICAL MATRIX GROUPS AND FERMAT PRIMES
  29. 29.0 29.1 29.2 On the finiteness of Carmichael numbers with Fermat factors and L = 2αP 2.
  30. 30.0 30.1 30.2 30.3 FAST INTEGER MULTIPLICATION USING GENERALIZED FERMAT PRIMES
  31. 31.0 31.1 31.2 31.3 ON UPPER BOUNDS FOR THE COUNT OF ELITE PRIMES Matthew Just
  32. 32.0 32.1 A NEW CHARACTERIZATION OF PRIME FERMAT’S NUMBERS
  33. On Upper Bounds with ABC = 2mpn and ABC = 2mpnqr with p and q as Mersenne or Fermat


메타데이터

위키데이터

Spacy 패턴 목록

  • [{'LOWER': 'fermat'}, {'LEMMA': 'prime'}]
  • [{'LOWER': 'fermat'}, {'LEMMA': 'number'}]
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