"타원곡선"의 두 판 사이의 차이

수학노트
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<h5>간단한 소개</h5>
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==개요==
  
* [[congruent number 문제]]
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* a smooth, projective algebraic curve of genus one, on which there is a specified point O
* [[사각 피라미드 퍼즐]]
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* abelian variety
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* 19세기 타원함수론과 함께 발전
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* 현대 정수론의 중요한 연구주제
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* 유리수체 위에 정의된 타원곡선에 대한 [[타니야마-시무라 추측(정리)]] 으로 [[페르마의 마지막 정리]] 가 해결
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* 타원곡선에 대한 [[Birch and Swinnerton-Dyer 추측]] 은 클레이 연구소가 선정한  7개의 밀레니엄 문제 중 하나
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==예==
  
 
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* [[합동수 문제 (congruent number problem)]] 방정식 <math>y^2=x^3-n^2x</math> 이 등장
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* [[사각 피라미드 퍼즐]]:<math>y^2=\frac{x(x+1)(2x+1)}{6}</math> 
  
<h5>격자와 타원곡선</h5>
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<math>y^2=4x^3-g_2(\tau)x-g_3</math>
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==격자와 타원곡선==
  
<math>g_2(\tau) = 60G_4=60\sum_{ (m,n) \neq (0,0)} \frac{1}{(m+n\tau )^{4}}</math>
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*  타원곡선 <math>y^2=4x^3-g_2(\tau)x-g_3(\tau)</math>:<math>g_2(\tau) = 60G_4=60\sum_{ (m,n) \neq (0,0)} \frac{1}{(m+n\tau )^{4}}</math>:<math>g_3(\tau) = 140G_6=140\sum_{ (m,n) \neq (0,0)} \frac{1}{(m+n\tau )^{6}}</math>
  
<math>g_3(\tau) = 140G_6=140\sum_{ (m,n) \neq (0,0)} \frac{1}{(m+n\tau )^{6}}</math>
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* [[아이젠슈타인 급수(Eisenstein series)]]
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* [[바이어슈트라스 타원함수 ℘|바이어슈트라스의 타원함수]]
  
* [[아이젠슈타인 급수(Eisenstein series)]]<br>
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==주기==
  
<h5>군의 구조</h5>
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*  타원곡선 <math>y^2=(x-e_1)(x-e_2)(x-e_3)</math>의 주기는 다음과 같이 정의된다:<math>\omega_1=2\int_{\infty}^{e_1}\frac{dx}{\sqrt{(x-e_1)(x-e_2)(x-e_3)}}</math>:<math>\omega_2=2\int_{e_1}^{e_2}\frac{dx}{\sqrt{(x-e_1)(x-e_2)(x-e_3)}}</math>
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* [[타원곡선의 주기]]
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==군의 구조==
  
 
* chord-tangent method
 
* chord-tangent method
*  유리수해에 대한 Mordell theorem<br>
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*  유리수해에 대한 Mordell theorem
 
** 유리수체 위에 정의된 타원의 유리수해는 유한생성아벨군의 구조를 가짐
 
** 유리수체 위에 정의된 타원의 유리수해는 유한생성아벨군의 구조를 가짐
** <math>\mathbb{Z}^r \oplus \mathbb{T}</math><br>  <br>
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** <math>E(\mathbb{Q})=\mathbb{Z}^r \oplus E(\mathbb{Q})_{\operatorname{Tor}}</math>
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** 여기서 <math>E(\mathbb{Q})_{\operatorname{Tor}}</math><math>E(\mathbb{Q})</math>의 원소 중에서 order가 유한이 되는 원소들로 이루어진 유한군
  
 
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<h5>덧셈공식</h5>
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* <math>y^2=x^3+ax^2+bx+c</math>위의 점 <math>P=(x,y)</math>에 대하여,<br><math>2P</math>의 <math>x</math>좌표는<math>\frac{x^4-2bx^2-8cx-4ac+b^2}{4y^2}</math> 로 주어진다<br>
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==덧셈공식==
  
 
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* <math>y^2=x^3+ax^2+bx+c</math>위의 점 <math>P=(x,y)</math>에 대하여, <math>2P</math>의 <math>x</math>좌표는<math>\frac{x^4-2bx^2-8cx-4ac+b^2}{4y^2}</math> 로 주어진다
  
 
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<h5>rank와 torsion</h5>
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==rank와 torsion==
  
* the only possible torsion groups for elliptic curves over Q are the cyclic groups of order 1,2,3,4,5,6,7,8,9,10,12 [sic -- 11 is not possible] and<br><math>\frac{\mathbb Z}{2\mathbb Z}\oplus \frac{\mathbb Z}{n\mathbb Z}</math> for n=1,2,3,4<br>
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* <math>E(\mathbb{Q})_{\operatorname{Tor}}</math>는 오직 다음 열다섯가지 경우만이 가능하다(B. Mazur) 크기가 1,2,3,4,5,6,7,8,9,10,12 (11은 불가)인 [[순환군]] 또는 <math>\frac{\mathbb Z}{2\mathbb Z}\oplus \frac{\mathbb Z}{n\mathbb Z}</math> for n=1,2,3,4
* 예) <math>E_n : y^2=x^3-n^2x</math>의 torsion은 <math>\{(\infty,\infty), (0,0),(n,0),(-n,0)\}</math>임
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* 예) <math>E_n : y^2=x^3-n^2x</math>의 torsion은 <math>\{(\infty,\infty), (0,0),(n,0),(-n,0)\}</math>임
  
 
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<h5>예</h5>
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==Hasse-Weil 정리==
  
* <math>y^2=x^3-x</math><br>[/pages/2061314/attachments/2299029 MSP1975197gdf732cih44i50000361d01gd578fhc4a.gif]<br>
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* <math>|\#E(\mathbb{F}_p)-p-1|\leq 2\sqrt{p}</math>
*  유리수해<br><math>E(\mathbb Q)=\{(\infty,\infty), (0,0),(1,0),(-1,0)\} \simeq \frac{\mathbb Z}{2\mathbb Z}\oplus \frac{\mathbb Z}{2\mathbb Z}</math><br>
 
*  주기<br><math>2\omega=4\int_0^1\frac{dx}{\sqrt{1-x^4}}=B(1/2,1/4)=\frac{\Gamma(\frac{1}{2})\Gamma(\frac{1}{4})}{\Gamma(\frac{3}{4})}=\frac{\Gamma(1/4)^2}{\sqrt{2\pi}}=5.24\cdots</math><br><math>2\int_0^1\frac{dx}{\sqrt{x-x^3}}=B(1/2,1/4)=\frac{\Gamma(\frac{1}{2})\Gamma(\frac{1}{4})}{\Gamma(\frac{3}{4})}=5.24\cdots</math><br>
 
* [[모듈라 군, j-invariant and the singular moduli]] 의 special values 부분과 비교
 
  
 
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<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">L-함수</h5>
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==타원곡선의 L-함수==
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*  타원 곡선 E의 conductor가 N일 때, 다음과 같이 정의됨
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:<math>L(s,E)=\prod_pL_p(s,E)^{-1}</math> 여기서 :<math>L_p(s,E)=\left\{\begin{array}{ll} (1-a_p p^{-s}+p^{1-2s}), & \mbox{if }p\nmid N \\ (1-a_pp^{-s}), & \mbox{if }p||N \\ 1, & \mbox{if }p^2|N \end{array}\right.</math>
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*  여기서 <math>a_p</math>는 유한체위에서의 해의 개수와 관련된 정수로 <math>a_p=p+1-\#E(\mathbb{F}_p)</math> (위의 하세-베유 정리)
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* [[타원곡선의 L-함수]] 항목 참조
  
<h5>타니야마-시무라 추측(정리)</h5>
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==타니야마-시무라 추측(정리)==
  
 
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* [[타니야마-시무라 추측(정리)]]
  
 
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<h5>Birch and Swinnerton-Dyer 추측</h5>
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==Birch and Swinnerton-Dyer 추측==
  
 
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* [[Birch and Swinnerton-Dyer 추측]]
  
 
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<h5>재미있는 사실</h5>
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==타원곡선의 예==
  
 
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* [[타원곡선 y²=x³-x|타원곡선 y^2=x^3-x]]
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* [[타원곡선 y²=x³+1|타원곡선 y^2=x^3+1]]
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* y^2=x^3-2x [http://www.math.leidenuniv.nl/%7Estreng/uci.pdf ][http://www.math.leidenuniv.nl/%7Estreng/uci.pdf http://www.math.leidenuniv.nl/~streng/uci.pdf]
  
<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">역사</h5>
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* [[수학사연표 (역사)|수학사연표]]
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==재미있는 사실==
  
 
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Raussen and Skau: In the introduction to your delightful book Rational Points on Elliptic Curves that you coauthored with your earlier Ph.D. student Joseph Silverman, you say, citing Serge Lang, that it is possible to write endlessly on elliptic curves. Can you comment on why the theory of elliptic curves is so rich and how it interacts and makes contact with so many different branches of mathematics? Tate: For one thing, they are very concrete objects. An elliptic curve is described by a cubic polynomial in two variables, so they are very easy to experiment with. On the other hand, elliptic curves illustrate very deep notions. They are the first nontrivial examples of abelian varieties. An elliptic curve is an abelian variety of dimension one, so you can get into this more advanced subject very easily by thinking about elliptic curves.
  
<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">관련된 다른 주제들</h5>
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On the other hand, they are algebraic curves. They are curves of genus one, the first example of a curve which isn’t birationally equivalent to a projective line. The analytic and algebraic relations which occur in the theory of elliptic curves and elliptic functions are beautiful and unbelievably fascinating. The modularity theorem stating that every elliptic curve over the rational field can be found in the Jacobian variety of the curve which parametrizes elliptic curves with level structure its conductor is mind-boggling.
  
* [[타원적분(통합됨)|타원적분]]<br>
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* [[렘니스케이트(lemniscate) 곡선의 길이와 타원적분|lemniscate 곡선의 길이와 타원적분]]<br>
 
* [[정수계수 이변수 이차형식(binary integral quadratic forms)]]<br>
 
* [[타원 모듈라 j-함수 (elliptic modular function, j-invariant)|j-invariant]]<br>
 
* [[아이젠슈타인 급수(Eisenstein series)]]<br>
 
* [[오일러 베타적분(베타함수)|베타적분]]<br>
 
* [[사각 피라미드 퍼즐]]<br>
 
* [[congruent number 문제]]<br>
 
* [[가우스의 class number one 문제]]<br>
 
* [[L-함수, 제타함수와 디리클레 급수]]<br>
 
* [[periods]]<br>
 
* [[무리수와 초월수]]<br>
 
  
 
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==역사==
  
<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">수학용어번역</h5>
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* 1908 포앵카레 E(Q) 는 아벨군이다
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* 1922 모델 E(Q)는 유한생성아벨군이다 (Weil generalized )
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* 1978 Mazur torsion part of E(Q)
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* [[수학사 연표]]
  
* [http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=&fstr= 대한수학회 수학 학술 용어집]<br>
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==관련된 항목들==
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* [[complex multiplication]]
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* [[타원적분]]
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* [[periods]]
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* [[렘니스케이트(lemniscate) 곡선의 길이와 타원적분|lemniscate 곡선의 길이와 타원적분]]
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* [[정수계수 이변수 이차형식(binary integral quadratic forms)]]
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* [[타원 모듈라 j-함수 (elliptic modular function, j-invariant)|j-invariant]]
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* [[아이젠슈타인 급수(Eisenstein series)]]
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* [[오일러 베타적분(베타함수)|베타적분]]
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* [[가우스의 class number one 문제]]
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* [[L-함수, 제타함수와 디리클레 급수]]
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* [[무리수와 초월수]]
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==수학용어번역==
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* [http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=&fstr= 대한수학회 수학 학술 용어집]
 
** http://mathnet.kaist.ac.kr/mathnet/math_list.php?mode=list&ftype=eng_term&fstr=
 
** 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=%7BD6048897-56F9-43D7-8BB6-50B362D1243A%7D&boardname=%BC%F6%C7%D0%BF%EB%BE%EE%C5%E4%B7%D0%B9%E6&globalmenu=7&localmenu=4 대한수학회 수학용어한글화 게시판]
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* [http://kms.or.kr/home/kor/board/bulletin_list_subject.asp?bulletinid=%7BD6048897-56F9-43D7-8BB6-50B362D1243A%7D&boardname=%BC%F6%C7%D0%BF%EB%BE%EE%C5%E4%B7%D0%B9%E6&globalmenu=7&localmenu=4 대한수학회 수학용어한글화 게시판]
  
 
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<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">사전 형태의 자료</h5>
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==사전 형태의 자료==
  
 
* [http://ko.wikipedia.org/wiki/%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://ko.wikipedia.org/wiki/타원곡선]
 
* [http://ko.wikipedia.org/wiki/%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://ko.wikipedia.org/wiki/타원곡선]
* [http://en.wikipedia.org/wiki/elliptic_curve ]http://en.wikipedia.org/wiki/elliptic_curve
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* http://en.wikipedia.org/wiki/elliptic_curve
 
* http://en.wikipedia.org/wiki/Mordell-Weil_theorem
 
* http://en.wikipedia.org/wiki/Mordell-Weil_theorem
* http://en.wikipedia.org/wiki/
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* http://en.wikipedia.org/wiki/Heegner_point
* [http://www.wolframalpha.com/input/?i=y%5E2=x%5E3-x http://www.wolframalpha.com/input/?i=y^2=x^3-x]
 
* http://www.wolframalpha.com/input/?i=
 
* [http://dlmf.nist.gov/ NIST Digital Library of Mathematical Functions]
 
  
 
 
  
 
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<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">관련논문</h5>
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==리뷰, 에세이, 강의노트==
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*  Carella, N. A. 2011. “Topic In Elliptic Curves Over Finite Fields: The Groups of Points.” <em>1103.4560</em> (March 22). http://arxiv.org/abs/1103.4560. 
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* [http://arxiv.org/abs/math/0311306 Conics - a Poor Man's Elliptic Curves]Franz Lemmermeyer, arXiv:math/0311306v1
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* [http://www.jstor.org/stable/2687483 Three Fermat Trails to Elliptic Curves] Ezra Brown, <cite style="line-height: 2em;">The College Mathematics Journal</cite>, Vol. 31, No. 3 (May, 2000), pp. 162-172
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* [http://www.jstor.org/stable/2974515 Elliptic Curves] John Stillwell, <cite style="line-height: 2em;">The American Mathematical Monthly</cite>, Vol. 102, No. 9 (Nov., 1995), pp. 831-837
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* [http://www.jstor.org/stable/2324954 Taxicabs and Sums of Two Cubes] Joseph H. SilvermanThe American Mathematical Monthly, Vol. 100, No. 4 (Apr., 1993), pp. 331-340
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* [http://www.jstor.org/stable/2690080 Why Study Equations over Finite Fields?] Neal Koblitz, <cite style="line-height: 2em;">Mathematics Magazine</cite>, Vol. 55, No. 3 (May, 1982), pp. 144-149
  
* [http://arxiv.org/abs/math/0311306 Conics - a Poor Man's Elliptic Curves]<br>
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** Franz Lemmermeyer, arXiv:math/0311306v1
 
* [http://www.jstor.org/stable/2687483 Three Fermat Trails to Elliptic Curves]<br>
 
** Ezra Brown, <cite style="line-height: 2em;">The College Mathematics Journal</cite>, Vol. 31, No. 3 (May, 2000), pp. 162-172
 
* [http://www.jstor.org/stable/2974515 Elliptic Curves]<br>
 
** John Stillwell, <cite style="line-height: 2em;">The American Mathematical Monthly</cite>, Vol. 102, No. 9 (Nov., 1995), pp. 831-837
 
* [http://www.jstor.org/stable/2324954 Taxicabs and Sums of Two Cubes]<br>
 
** Joseph H. SilvermanThe American Mathematical Monthly, Vol. 100, No. 4 (Apr., 1993), pp. 331-340
 
* [http://www.jstor.org/stable/2007967 On the Conjecture of Birch and Swinnerton-Dyer for an Elliptic Curve of Rank 3]<br>
 
** Joe P. Buhler, Benedict H. Gross and Don B. Zagier, Mathematics of Computation, Vol. 44, No. 170 (Apr., 1985), pp. 473-481
 
* [http://www.springerlink.com/content/r733tt28wr632k66/ Rational isogenies of prime degree]<br>
 
** Barry Mazur, Inventiones Math. 44 (1978), 129-162
 
* http://www.jstor.org/action/doBasicSearch?Query=elliptic+curves
 
* http://www.jstor.org/action/doBasicSearch?Query=congruent+number+problem
 
* http://www.jstor.org/action/doBasicSearch?Query=
 
  
 
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==관련논문==
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* Jennifer S. Balakrishnan, Wei Ho, Nathan Kaplan, Simon Spicer, William Stein, James Weigandt, Databases of elliptic curves ordered by height and distributions of Selmer groups and ranks, arXiv:1602.01894 [math.NT], February 05 2016, http://arxiv.org/abs/1602.01894
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* Berghoff, Christian J. “Elliptic Gau{\ss} Sums and Schoof’s Algorithm.” arXiv:1601.03227 [math], January 13, 2016. http://arxiv.org/abs/1601.03227.
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* Müller, J. Steffen, and Michael Stoll. “Computing Canonical Heights on Elliptic Curves in Quasi-Linear Time.” arXiv:1509.08748 [math], September 29, 2015. http://arxiv.org/abs/1509.08748.
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* Buckley, Anita. “Indecomposable Matrices Defining Plane Cubics.” arXiv:1510.00133 [math], October 1, 2015. http://arxiv.org/abs/1510.00133.
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* Guitart, Xavier, Marc Masdeu, and Mehmet Haluk Sengun. “Uniformization of Modular Elliptic Curves via P-Adic Periods.” arXiv:1501.02936 [math], January 13, 2015. http://arxiv.org/abs/1501.02936.
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* Alpoge, Levent. “The Average Number of Integral Points on Elliptic Curves Is Bounded.” arXiv:1412.1047 [math], December 2, 2014. http://arxiv.org/abs/1412.1047.
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* Rubin, Karl, and Alice Silverberg. “Ranks of Elliptic Curves.” Bulletin of the American Mathematical Society 39, no. 4 (2002): 455–74. doi:[http://www.ams.org/journals/bull/2002-39-04/S0273-0979-02-00952-7/ 10.1090/S0273-0979-02-00952-7].
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* [http://dx.doi.org/10.1007%2FBF01458081 Heegner points and derivatives of L-series. II]
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**  Gross, B.; Kohnen, W.; Zagier, D. (1987),  Mathematische Annalen 278 (1–4): 497–562
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* [http://dx.doi.org/10.1007%2FBF01388809 Heegner points and derivatives of L-series]
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**  Gross, Benedict H.; Zagier, Don B. (1986),  Inventiones Mathematicae 84 (2): 225–320
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* [http://www.jstor.org/stable/2007967 On the Conjecture of Birch and Swinnerton-Dyer for an Elliptic Curve of Rank 3]
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** Joe P. Buhler, Benedict H. Gross and Don B. Zagier, Mathematics of Computation, Vol. 44, No. 170 (Apr., 1985), pp. 473-481
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* [http://www.springerlink.com/content/r733tt28wr632k66/ Rational isogenies of prime degree]
 +
** Barry Mazur, Inventiones Math. 44 (1978), 129-162
  
<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">관련도서 및 추천도서</h5>
+
==관련도서==
  
* [http://books.google.com/books?id=99v9XcOjhO4C&printsec=frontcover&dq=elliptic+curves&ei=cODSSvy2Coi0kASl5b2MDg Introduction to elliptic curves and modular forms‎]<br>
+
* [http://books.google.com/books?id=99v9XcOjhO4C&printsec=frontcover&dq=elliptic+curves&ei=cODSSvy2Coi0kASl5b2MDg Introduction to elliptic curves and modular forms‎]
 
** Neal Koblitz - 1993
 
** Neal Koblitz - 1993
* [http://books.google.com/books?id=mAJei2-JcE4C&printsec=frontcover&dq=rational+points+on+elliptic+curves&ei=3NfSSqfuKIGEkgTmqsgK&hl=ko#v=onepage&q=&f=false Rational points on elliptic curves‎]<br>
+
* [http://books.google.com/books?id=mAJei2-JcE4C&printsec=frontcover&dq=rational+points+on+elliptic+curves&ei=3NfSSqfuKIGEkgTmqsgK&hl=ko#v=onepage&q=&f=false Rational points on elliptic curves‎]
 
** Joseph H. Silverman, John Torrence Tate - 1992
 
** Joseph H. Silverman, John Torrence Tate - 1992
 
** 학부생의 입문용으로 좋은 책
 
** 학부생의 입문용으로 좋은 책
* [http://books.google.com/books?hl=ko&lr=&id=Z90CA_EUCCkC&oi=fnd&pg=PR5&dq=%22Silverman%22+%22The+arithmetic+of+elliptic+curves%22+&ots=3K5hjqYj17&sig=zDmIXkvS7EaFwu4bnEbxmWUpFys#v=onepage&q=&f=false The Arithmetic of Elliptic Curves]<br>
+
* [http://books.google.com/books?hl=ko&lr=&id=Z90CA_EUCCkC&oi=fnd&pg=PR5&dq=%22Silverman%22+%22The+arithmetic+of+elliptic+curves%22+&ots=3K5hjqYj17&sig=zDmIXkvS7EaFwu4bnEbxmWUpFys#v=onepage&q=&f=false The Arithmetic of Elliptic Curves]
**  Silverman, Joseph H. (1986), Graduate Texts in Mathematics, 106, Springer-Verlag<br>
+
**  Silverman, Joseph H. (1986), Graduate Texts in Mathematics, 106, Springer-Verlag
*  도서내검색<br>
+
*  도서내검색
 
** [http://books.google.com/books?q=%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://books.google.com/books?q=타원곡선]
 
** [http://books.google.com/books?q=%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://books.google.com/books?q=타원곡선]
 
** [http://book.daum.net/search/contentSearch.do?query=%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://book.daum.net/search/contentSearch.do?query=타원곡선]
 
** [http://book.daum.net/search/contentSearch.do?query=%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://book.daum.net/search/contentSearch.do?query=타원곡선]
** http://book.daum.net/search/contentSearch.do?query=
+
[[분류:리만곡면론]]
*  도서검색<br>
 
** http://books.google.com/books?q=elliptic+curves
 
** http://books.google.com/books?q=
 
** 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="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">관련기사</h5>
 
  
*  네이버 뉴스 검색 (키워드 수정)<br>
+
==메타데이터==
** [http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=%ED%83%80%EC%9B%90%EA%B3%A1%EC%84%A0 http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=타원곡선]
+
===위키데이터===
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
+
* ID :  [https://www.wikidata.org/wiki/Q268493 Q268493]
** http://news.search.naver.com/search.naver?where=news&x=0&y=0&sm=tab_hty&query=
+
===Spacy 패턴 목록===
 +
* [{'LOWER': 'elliptic'}, {'LEMMA': 'curve'}]
  
 
+
== 노트 ==
  
 
+
===말뭉치===
 +
# An elliptic curve is an algebraic function (y2 = x3 + ax + b) which looks like a symmetrical curve parallel to the x axis when plotted.<ref name="ref_07100c74">[https://pkic.org/2014/06/10/benefits-of-elliptic-curve-cryptography/ Benefits of Elliptic Curve Cryptography]</ref>
 +
# Have you heard of elliptic curves before?<ref name="ref_96d3aebb">[https://prateekvjoshi.com/2015/02/07/why-are-they-called-elliptic-curves/ Why Are They Called “Elliptic” Curves?]</ref>
 +
# The reason elliptic curve cryptography is gaining popularity is because it’s fundamentally much stronger than the RSA algorithm, the algorithm that we all love and adore.<ref name="ref_96d3aebb" />
 +
# Okay I’m going to assume that you know what elliptic curves look like.<ref name="ref_96d3aebb" />
 +
# These curves are called elliptic curves.<ref name="ref_96d3aebb" />
 +
# The Weierstrass elliptic function describes how to get from this torus to the algebraic form of an elliptic curve.<ref name="ref_c9cf5406">[https://mathworld.wolfram.com/EllipticCurve.html Elliptic Curve -- from Wolfram MathWorld]</ref>
 +
# Elliptic curves are illustrated above for various values of and .<ref name="ref_c9cf5406" />
 +
# An elliptic curve of the form for an integer is known as a Mordell curve.<ref name="ref_c9cf5406" />
 +
# Whereas conic sections can be parameterized by the rational functions, elliptic curves cannot.<ref name="ref_c9cf5406" />
 +
# Elliptic curves have been studied for many years by pure mathematicians with no intention to apply the results to anything outside math itself.<ref name="ref_566a3494">[https://www.johndcook.com/blog/2019/02/21/what-is-an-elliptic-curve/ What is an elliptic curve? Informal and formal definition]</ref>
 +
# And yet elliptic curves have become a critical part of applied cryptography.<ref name="ref_566a3494" />
 +
# The other day I wrote about Curve1174, a particular elliptic curve used in cryptography.<ref name="ref_566a3494" />
 +
# There is a connection between elliptic curves and ellipses, but it’s indirect.<ref name="ref_566a3494" />
 +
# Elliptic curves are also used in several integer factorization algorithms based on elliptic curves that have applications in cryptography, such as Lenstra elliptic-curve factorization.<ref name="ref_fe9f81e6">[https://en.wikipedia.org/wiki/Elliptic-curve_cryptography Elliptic-curve cryptography]</ref>
 +
# The security of elliptic curve cryptography depends on the ability to compute a point multiplication and the inability to compute the multiplicand given the original and product points.<ref name="ref_fe9f81e6" />
 +
# Elliptic curve cryptography algorithms entered wide use in 2004 to 2005.<ref name="ref_fe9f81e6" />
 +
# Elliptic curves are especially important in number theory, and constitute a major area of current research; for example, they were used in Andrew Wiles's proof of Fermat's Last Theorem.<ref name="ref_d8906515">[https://en.wikipedia.org/wiki/Elliptic_curve#:~:text=In%20mathematics%2C%20an%20elliptic%20curve,product%20of%20K%20with%20itself. Elliptic curve]</ref>
 +
# An elliptic curve is not an ellipse in the sense of a projective conic, which has genus zero: see elliptic integral for the origin of the term.<ref name="ref_d8906515" />
 +
# However, there is a natural representation of real elliptic curves with shape invariant j ≥ 1 as ellipses in the hyperbolic plane H 2 {\displaystyle \mathbb {H} ^{2}} .<ref name="ref_d8906515" />
 +
# The group law on an elliptic curve is what makes the theory of elliptic curves so special and interesting.<ref name="ref_a3eea923">[https://brilliant.org/wiki/elliptic-curves/ Brilliant Math & Science Wiki]</ref>
 +
# 2) Implementation of elliptic curves in cryptography requires smaller chip size, less power consumption, increase in speed, etc.<ref name="ref_1193c6d6">[http://www.umsl.edu/~siegelj/information_theory/projects/EllipticCurveEncyiption.pdf Elliptic curve cryptography methods]</ref>
 +
# However, this is hard given the large parameters of our elliptic curve seven tuple.<ref name="ref_1193c6d6" />
 +
# Various aspects of elliptic curve cryptography have been patented by a variety of people and companies around the world.<ref name="ref_1193c6d6" />
 +
# The only difference is that elliptic curve cryptography has been at its full strength since it was developed.<ref name="ref_1193c6d6" />
 +
# Elliptic curves have genus 1.<ref name="ref_ed2da65b">[https://math.mit.edu/classes/18.783/2017/Lecture1.pdf 18.783 elliptic curves]</ref>
 +
# This equation denes an elliptic curve.<ref name="ref_ed2da65b" />
 +
# Denition (more precise) An elliptic curve (over a eld k) is a smooth projective curve of genus 1 (dened over k) with a distinguished (k-rational) point.<ref name="ref_ed2da65b" />
 +
# Not every smooth projective curve of genus 1 corresponds to an elliptic curve, it needs to have at least one rational point!<ref name="ref_ed2da65b" />
 +
# With a series of blog posts I'm going to give you a gentle introduction to the world of elliptic curve cryptography.<ref name="ref_fac29407">[https://andrea.corbellini.name/2015/05/17/elliptic-curve-cryptography-a-gentle-introduction/ Elliptic Curve Cryptography: a gentle introduction]</ref>
 +
# The equation above is what is called Weierstrass normal form for elliptic curves.<ref name="ref_fac29407" />
 +
# With a pencil and a ruler we are able to perform addition involving every point of any elliptic curve.<ref name="ref_fac29407" />
 +
# It generates security between key pairs for public key encryption by using the mathematics of elliptic curves.<ref name="ref_d35136a4">[https://avinetworks.com/glossary/elliptic-curve-cryptography/ What is Elliptic Curve Cryptography? Definition & FAQs]</ref>
 +
# RSA does something similar with prime numbers instead of elliptic curves, but ECC has gradually been growing in popularity recently due to its smaller key size and ability to maintain security.<ref name="ref_d35136a4" />
 +
# This is why it is so important to understand elliptic curve cryptography in context.<ref name="ref_d35136a4" />
 +
# More sites using ECC to secure data means a greater need for this kind of quick guide to elliptic curve cryptography.<ref name="ref_d35136a4" />
 +
# Each choice of the numbers a and b yields a different elliptic curve.<ref name="ref_12385278">[https://www.certicom.com/content/certicom/en/20-elliptic-curve-groups-over-real-numbers.html 2.0 Elliptic Curve Groups over Real Numbers]</ref>
 +
# One relatively newer class of encryption are the so-called “elliptic curve” algorithms, which derive their security from the mathematic principles of (you guessed it) elliptic curves.<ref name="ref_82135df3">[https://www.sciencedirect.com/topics/computer-science/elliptic-curve Elliptic Curve - an overview]</ref>
 +
# Elliptic curves have many remarkable properties, and their deeper arithmetic study is one of the most profound subjects in present-day mathematics.<ref name="ref_39b730e4">[https://ncatlab.org/nlab/show/elliptic+curve elliptic curve in nLab]</ref>
 +
# Elliptic curves over the complex numbers are also interpreted as those worldsheets in string theory whose correlators are the superstring‘s partition function, which is the Witten genus.<ref name="ref_39b730e4" />
 +
# Via the string orientation of tmf this connects to to the role of elliptic curves in elliptic cohomology theory.<ref name="ref_39b730e4" />
 +
# Otherwise the height equals 1 and the elliptic curve is called ordinary.<ref name="ref_39b730e4" />
 +
# A goal of the theory of elliptic curves is to nd all the -rational points on curves of genus one.<ref name="ref_5a13f3ce">[https://www.ams.org/journals/notices/201703/rnoti-p241.pdf The gra d uate stude nt secti on]</ref>
 +
# The study of elliptic curves grew in the 1980s.<ref name="ref_5a13f3ce" />
 +
# An elliptic curve is a smooth projective2 curve of genus 1 dened over a eld , with at least one - rational point (i.e., there is at least one point on with coordinates in ).<ref name="ref_5a13f3ce" />
 +
# We then call = / the rank of the elliptic curve /.<ref name="ref_5a13f3ce" />
 +
# What is elliptic curve cryptography, and how does it work?<ref name="ref_3f12ac8e">[https://matt-rickard.com/elliptic-curve-cryptography/ Elliptic Curve Cryptography for Beginners]</ref>
 +
# You might be curious about what happens at the edge cases of the group law on elliptic curves.<ref name="ref_3f12ac8e" />
 +
# Readers are reminded that elliptic curve cryptography is a set of algorithms for encrypting and decrypting data and exchanging cryptographic keys.<ref name="ref_3b449f50">[https://arstechnica.com/information-technology/2013/10/a-relatively-easy-to-understand-primer-on-elliptic-curve-cryptography/ A (relatively easy to understand) primer on elliptic curve cryptography]</ref>
 +
# The purpose of this article will be to go into elliptic curve pairings in detail, and explain a general outline of how they work.<ref name="ref_bcad9c44">[https://medium.com/@VitalikButerin/exploring-elliptic-curve-pairings-c73c1864e627 Exploring Elliptic Curve Pairings]</ref>
 +
# p * G = P), then whereas traditional elliptic curve math lets you check linear constraints on the numbers (eg.<ref name="ref_bcad9c44" />
 +
# This is where elliptic curves and elliptic curve pairings come in.<ref name="ref_bcad9c44" />
 +
# And it is these kinds of supercharged modular complex numbers that elliptic curve pairings are built on.<ref name="ref_bcad9c44" />
 +
# But historically the theory of elliptic curves arose as a part of analysis, as the theory of elliptic integrals and elliptic functions (cf.<ref name="ref_4c3c698c">[https://encyclopediaofmath.org/wiki/Elliptic_curve Encyclopedia of Mathematics]</ref>
 +
# Rather than relying on large numbers alone, elliptic curves obtain their security by combining points on mathematical curves.<ref name="ref_eff2d50d">[https://medium.loopring.io/learning-cryptography-elliptic-curves-4cfd0bdcb05a Learning Cryptography, Part 3: Elliptic Curves]</ref>
 +
# Real-world elliptic curves aren’t too different from this, although this is just used as an example.<ref name="ref_eff2d50d" />
 +
# Our goal was to introduce you to the basics of elliptic curves, how they’re formed and the types of operations we can do on them.<ref name="ref_eff2d50d" />
 +
# Upcoming parts will talk about how we utilize the properties of elliptic curves for the public key and private key cryptography in today’s world.<ref name="ref_eff2d50d" />
 +
# What do elliptic curves look like?<ref name="ref_c31febed">[https://www.maths.ox.ac.uk/outreach/oxford-mathematics-alphabet/e-elliptic-curves E is for Elliptic Curves]</ref>
 +
# In 1994, Wiles and Taylor-Wiles proved this result for semistable elliptic curves over the rationals and, in so doing, proved Fermat's Last Theorem.<ref name="ref_c31febed" />
 +
# This correspondence between elliptic curves and cusp forms - through the theory of Galois representations - now motivates an exciting area of research known as the Langlands problem.<ref name="ref_c31febed" />
 +
# Abelian Varieties can be viewed as generalizations of elliptic curves.<ref name="ref_63a251d1">[https://archive.lib.msu.edu/crcmath/math/math/e/e083.htm Elliptic Curve]</ref>
 +
# General purpose Elliptic Curve Cryptography (ECC) support, including types and traits for representing various elliptic curve forms, scalars, points, and public/secret keys composed thereof.<ref name="ref_c77da268">[https://docs.rs/elliptic-curve elliptic_curve]</ref>
 +
# This crate provides traits for describing elliptic curves, along with types which are generic over elliptic curves which can be used as the basis of curve-agnostic code.<ref name="ref_c77da268" />
 +
# Elliptic curves are a very important new area of mathematics which has been greatly explored over the past few decades.<ref name="ref_f5675afb">[https://plus.maths.org/content/elliptic-cryptography Elliptic cryptography]</ref>
 +
# In 1994 Andrew Wiles, together with his former student Richard Taylor, solved one of the most famous maths problems of the last 400 years, Fermat's Last Theorem, using elliptic curves.<ref name="ref_f5675afb" />
 +
# In the last few decades there has also been a lot of research into using elliptic curves instead of what is called RSA encryption to keep data transfer safe online.<ref name="ref_f5675afb" />
 +
# The elliptic curves corresponding to whole number values of a between -2 and 1 and whole number values of values of b between -1 and 2.<ref name="ref_f5675afb" />
 +
# This book is an introduction to the theory of elliptic curves, ranging from elementary topics to current research.<ref name="ref_5241ae6e">[https://link.springer.com/book/10.1007/b97292 Elliptic Curves]</ref>
 +
# The two additional chapters concern higher-dimensional analogues of elliptic curves, including K3 surfaces and Calabi-Yau manifolds.<ref name="ref_5241ae6e" />
 +
# Two new appendices explore recent applications of elliptic curves and their generalizations.<ref name="ref_5241ae6e" />
 +
# Please see our tracking issue for additional elliptic curves if you are interested in curves beyond the ones listed here.<ref name="ref_30c50300">[https://github.com/RustCrypto/elliptic-curves RustCrypto/elliptic-curves: Collection of pure Rust elliptic curve implementations: NIST P-256, P-384, secp256k1]</ref>
 +
# Each elliptic curve point is associated with a particular parameter set.<ref name="ref_b2b1e717">[https://tools.ietf.org/html/rfc6090 Fundamental Elliptic Curve Cryptography Algorithms]</ref>
 +
# We use elliptic curves because they provide a cryptographic group, i.e. a group in which the discrete logarithm problem (discussed below) is hard.<ref name="ref_c16e3bd5">[https://zcash.github.io/halo2/background/curves.html Elliptic curves]</ref>
 +
# By convention, elliptic curve groups are written additively.<ref name="ref_c16e3bd5" />
 +
# This is called the elliptic curve discrete log assumption.<ref name="ref_c16e3bd5" />
 +
# In the case of a cryptographically secure elliptic curve, the isomorphism is hard to compute in the G→Fq​ direction because the elliptic curve discrete log problem is hard.<ref name="ref_c16e3bd5" />
 +
# Elliptic Curves Elliptic curves are groups created by de(cid:12)ning a binary operation (addition) on the points of the graph of certain polynomial equations in two variables.<ref name="ref_d89fcff4">[https://www.cs.purdue.edu/homes/ssw/cs655/ec.pdf Elliptic curves]</ref>
 +
# Choosing random coe(cid:14)cients results in groups with random orders near p. 1 One can use elliptic curves to factor integers, although probably not RSA moduli.<ref name="ref_d89fcff4" />
 +
# There is a probabilistic algorithm for proving primality that uses elliptic curves.<ref name="ref_d89fcff4" />
 +
# discrete logarithm problem is harder for elliptic curve groups than for the integers modulo p, permitting smaller parameters and faster algo- rithms.<ref name="ref_d89fcff4" />
 +
# The use of elliptic curves in cryptography was independently suggested by Neal Koblitz and Victor Miller in 1985.<ref name="ref_b7cdf521">[https://www.cryptopp.com/wiki/Elliptic_Curve_Cryptography Elliptic Curve Cryptography]</ref>
 +
# From a high level, Crypto++ offers a numbers of schemes and alogrithms which operate over elliptic curves.<ref name="ref_b7cdf521" />
 +
# For cryptographic computational purposes, elliptic curves are represented in several different forms.<ref name="ref_49ba2964">[https://hackage.haskell.org/package/elliptic-curve elliptic-curve]</ref>
 +
# You don't need to know much algebra to understand how elliptic curve cryptography works.<ref name="ref_ca00aa2a">[https://crypto.stackexchange.com/questions/83312/how-are-points-on-an-elliptic-curve-discretized How are points on an elliptic curve discretized?]</ref>
 +
# This method can give all such functions and only them; it's not hard to see that only meromorphic functions with this property are allowed on elliptic curve.<ref name="ref_323a240c">[https://mathoverflow.net/questions/6870/why-is-an-elliptic-curve-a-group Why is an elliptic curve a group?]</ref>
 +
# In particular, elliptic curves coincide with their Jacobian and that's another explanation for the additive law.<ref name="ref_323a240c" />
 +
# Indeed elliptic curves are dominating the cryptography landscape but for people other than Mathematicians the logic behind this may not be so obvious.<ref name="ref_e07f00f6">[https://infosecwriteups.com/demystifying-elliptic-curves-for-cryptography-5e02060da51d Demystifying Elliptic Curve Cryptography]</ref>
 +
# I am therefore writing this post to give a gentle introduction in elliptic curves for people with basic mathematical background and explain why they are so popular amongst cryptographers.<ref name="ref_e07f00f6" />
 +
# This is exactly where elliptic curves become relevant in cryptography.<ref name="ref_e07f00f6" />
 +
# These groups formed by elliptic curves are the groups used for building elliptic curve cryptosystems.<ref name="ref_e07f00f6" />
 +
# Elliptic curve cryptography (ECC) uses the mathematical properties of elliptic curves to produce public key cryptographic systems.<ref name="ref_e71d134a">[https://www.ssl.com/faqs/what-is-elliptic-curve-cryptography-ecc/ What is Elliptic curve cryptography (ECC)?]</ref>
 +
===소스===
 +
<references />
  
<h5 style="margin: 0px; line-height: 3.428em; color: rgb(34, 61, 103); font-family: 'malgun gothic',dotum,gulim,sans-serif; font-size: 1.166em; background-position: 0px 100%;">블로그</h5>
+
== 메타데이터 ==
  
* 구글 블로그 검색 http://blogsearch.google.com/blogsearch?q=
+
===위키데이터===
* [http://navercast.naver.com/science/list 네이버 오늘의과학]
+
* ID :  [https://www.wikidata.org/wiki/Q268493 Q268493]
 +
===Spacy 패턴 목록===
 +
* [{'LOWER': 'elliptic'}, {'LEMMA': 'curve'}]

2022년 7월 6일 (수) 19:33 기준 최신판

개요




격자와 타원곡선

  • 타원곡선 \(y^2=4x^3-g_2(\tau)x-g_3(\tau)\)\[g_2(\tau) = 60G_4=60\sum_{ (m,n) \neq (0,0)} \frac{1}{(m+n\tau )^{4}}\]\[g_3(\tau) = 140G_6=140\sum_{ (m,n) \neq (0,0)} \frac{1}{(m+n\tau )^{6}}\]



주기

  • 타원곡선 \(y^2=(x-e_1)(x-e_2)(x-e_3)\)의 주기는 다음과 같이 정의된다\[\omega_1=2\int_{\infty}^{e_1}\frac{dx}{\sqrt{(x-e_1)(x-e_2)(x-e_3)}}\]\[\omega_2=2\int_{e_1}^{e_2}\frac{dx}{\sqrt{(x-e_1)(x-e_2)(x-e_3)}}\]
  • 타원곡선의 주기



군의 구조

  • chord-tangent method
  • 유리수해에 대한 Mordell theorem
    • 유리수체 위에 정의된 타원의 유리수해는 유한생성아벨군의 구조를 가짐
    • \(E(\mathbb{Q})=\mathbb{Z}^r \oplus E(\mathbb{Q})_{\operatorname{Tor}}\)
    • 여기서 \(E(\mathbb{Q})_{\operatorname{Tor}}\)는 \(E(\mathbb{Q})\)의 원소 중에서 order가 유한이 되는 원소들로 이루어진 유한군



덧셈공식

  • \(y^2=x^3+ax^2+bx+c\)위의 점 \(P=(x,y)\)에 대하여, \(2P\)의 \(x\)좌표는\(\frac{x^4-2bx^2-8cx-4ac+b^2}{4y^2}\) 로 주어진다



rank와 torsion

  • \(E(\mathbb{Q})_{\operatorname{Tor}}\)는 오직 다음 열다섯가지 경우만이 가능하다(B. Mazur) 크기가 1,2,3,4,5,6,7,8,9,10,12 (11은 불가)인 순환군 또는 \(\frac{\mathbb Z}{2\mathbb Z}\oplus \frac{\mathbb Z}{n\mathbb Z}\) for n=1,2,3,4
  • 예) \(E_n : y^2=x^3-n^2x\)의 torsion은 \(\{(\infty,\infty), (0,0),(n,0),(-n,0)\}\)임



Hasse-Weil 정리

  • \(|\#E(\mathbb{F}_p)-p-1|\leq 2\sqrt{p}\)




타원곡선의 L-함수

  • 타원 곡선 E의 conductor가 N일 때, 다음과 같이 정의됨

\[L(s,E)=\prod_pL_p(s,E)^{-1}\] 여기서 \[L_p(s,E)=\left\{\begin{array}{ll} (1-a_p p^{-s}+p^{1-2s}), & \mbox{if }p\nmid N \\ (1-a_pp^{-s}), & \mbox{if }p||N \\ 1, & \mbox{if }p^2|N \end{array}\right.\]

  • 여기서 \(a_p\)는 유한체위에서의 해의 개수와 관련된 정수로 \(a_p=p+1-\#E(\mathbb{F}_p)\) (위의 하세-베유 정리)
  • 타원곡선의 L-함수 항목 참조

타니야마-시무라 추측(정리)



Birch and Swinnerton-Dyer 추측



타원곡선의 예



재미있는 사실

Raussen and Skau: In the introduction to your delightful book Rational Points on Elliptic Curves that you coauthored with your earlier Ph.D. student Joseph Silverman, you say, citing Serge Lang, that it is possible to write endlessly on elliptic curves. Can you comment on why the theory of elliptic curves is so rich and how it interacts and makes contact with so many different branches of mathematics? Tate: For one thing, they are very concrete objects. An elliptic curve is described by a cubic polynomial in two variables, so they are very easy to experiment with. On the other hand, elliptic curves illustrate very deep notions. They are the first nontrivial examples of abelian varieties. An elliptic curve is an abelian variety of dimension one, so you can get into this more advanced subject very easily by thinking about elliptic curves.

On the other hand, they are algebraic curves. They are curves of genus one, the first example of a curve which isn’t birationally equivalent to a projective line. The analytic and algebraic relations which occur in the theory of elliptic curves and elliptic functions are beautiful and unbelievably fascinating. The modularity theorem stating that every elliptic curve over the rational field can be found in the Jacobian variety of the curve which parametrizes elliptic curves with level structure its conductor is mind-boggling.



역사

  • 1908 포앵카레 E(Q) 는 아벨군이다
  • 1922 모델 E(Q)는 유한생성아벨군이다 (Weil generalized )
  • 1978 Mazur torsion part of E(Q)
  • 수학사 연표



관련된 항목들



수학용어번역



사전 형태의 자료



리뷰, 에세이, 강의노트



관련논문

관련도서

메타데이터

위키데이터

Spacy 패턴 목록

  • [{'LOWER': 'elliptic'}, {'LEMMA': 'curve'}]

노트

말뭉치

  1. An elliptic curve is an algebraic function (y2 = x3 + ax + b) which looks like a symmetrical curve parallel to the x axis when plotted.[1]
  2. Have you heard of elliptic curves before?[2]
  3. The reason elliptic curve cryptography is gaining popularity is because it’s fundamentally much stronger than the RSA algorithm, the algorithm that we all love and adore.[2]
  4. Okay I’m going to assume that you know what elliptic curves look like.[2]
  5. These curves are called elliptic curves.[2]
  6. The Weierstrass elliptic function describes how to get from this torus to the algebraic form of an elliptic curve.[3]
  7. Elliptic curves are illustrated above for various values of and .[3]
  8. An elliptic curve of the form for an integer is known as a Mordell curve.[3]
  9. Whereas conic sections can be parameterized by the rational functions, elliptic curves cannot.[3]
  10. Elliptic curves have been studied for many years by pure mathematicians with no intention to apply the results to anything outside math itself.[4]
  11. And yet elliptic curves have become a critical part of applied cryptography.[4]
  12. The other day I wrote about Curve1174, a particular elliptic curve used in cryptography.[4]
  13. There is a connection between elliptic curves and ellipses, but it’s indirect.[4]
  14. Elliptic curves are also used in several integer factorization algorithms based on elliptic curves that have applications in cryptography, such as Lenstra elliptic-curve factorization.[5]
  15. The security of elliptic curve cryptography depends on the ability to compute a point multiplication and the inability to compute the multiplicand given the original and product points.[5]
  16. Elliptic curve cryptography algorithms entered wide use in 2004 to 2005.[5]
  17. Elliptic curves are especially important in number theory, and constitute a major area of current research; for example, they were used in Andrew Wiles's proof of Fermat's Last Theorem.[6]
  18. An elliptic curve is not an ellipse in the sense of a projective conic, which has genus zero: see elliptic integral for the origin of the term.[6]
  19. However, there is a natural representation of real elliptic curves with shape invariant j ≥ 1 as ellipses in the hyperbolic plane H 2 {\displaystyle \mathbb {H} ^{2}} .[6]
  20. The group law on an elliptic curve is what makes the theory of elliptic curves so special and interesting.[7]
  21. 2) Implementation of elliptic curves in cryptography requires smaller chip size, less power consumption, increase in speed, etc.[8]
  22. However, this is hard given the large parameters of our elliptic curve seven tuple.[8]
  23. Various aspects of elliptic curve cryptography have been patented by a variety of people and companies around the world.[8]
  24. The only difference is that elliptic curve cryptography has been at its full strength since it was developed.[8]
  25. Elliptic curves have genus 1.[9]
  26. This equation denes an elliptic curve.[9]
  27. Denition (more precise) An elliptic curve (over a eld k) is a smooth projective curve of genus 1 (dened over k) with a distinguished (k-rational) point.[9]
  28. Not every smooth projective curve of genus 1 corresponds to an elliptic curve, it needs to have at least one rational point![9]
  29. With a series of blog posts I'm going to give you a gentle introduction to the world of elliptic curve cryptography.[10]
  30. The equation above is what is called Weierstrass normal form for elliptic curves.[10]
  31. With a pencil and a ruler we are able to perform addition involving every point of any elliptic curve.[10]
  32. It generates security between key pairs for public key encryption by using the mathematics of elliptic curves.[11]
  33. RSA does something similar with prime numbers instead of elliptic curves, but ECC has gradually been growing in popularity recently due to its smaller key size and ability to maintain security.[11]
  34. This is why it is so important to understand elliptic curve cryptography in context.[11]
  35. More sites using ECC to secure data means a greater need for this kind of quick guide to elliptic curve cryptography.[11]
  36. Each choice of the numbers a and b yields a different elliptic curve.[12]
  37. One relatively newer class of encryption are the so-called “elliptic curve” algorithms, which derive their security from the mathematic principles of (you guessed it) elliptic curves.[13]
  38. Elliptic curves have many remarkable properties, and their deeper arithmetic study is one of the most profound subjects in present-day mathematics.[14]
  39. Elliptic curves over the complex numbers are also interpreted as those worldsheets in string theory whose correlators are the superstring‘s partition function, which is the Witten genus.[14]
  40. Via the string orientation of tmf this connects to to the role of elliptic curves in elliptic cohomology theory.[14]
  41. Otherwise the height equals 1 and the elliptic curve is called ordinary.[14]
  42. A goal of the theory of elliptic curves is to nd all the -rational points on curves of genus one.[15]
  43. The study of elliptic curves grew in the 1980s.[15]
  44. An elliptic curve is a smooth projective2 curve of genus 1 dened over a eld , with at least one - rational point (i.e., there is at least one point on with coordinates in ).[15]
  45. We then call = / the rank of the elliptic curve /.[15]
  46. What is elliptic curve cryptography, and how does it work?[16]
  47. You might be curious about what happens at the edge cases of the group law on elliptic curves.[16]
  48. Readers are reminded that elliptic curve cryptography is a set of algorithms for encrypting and decrypting data and exchanging cryptographic keys.[17]
  49. The purpose of this article will be to go into elliptic curve pairings in detail, and explain a general outline of how they work.[18]
  50. p * G = P), then whereas traditional elliptic curve math lets you check linear constraints on the numbers (eg.[18]
  51. This is where elliptic curves and elliptic curve pairings come in.[18]
  52. And it is these kinds of supercharged modular complex numbers that elliptic curve pairings are built on.[18]
  53. But historically the theory of elliptic curves arose as a part of analysis, as the theory of elliptic integrals and elliptic functions (cf.[19]
  54. Rather than relying on large numbers alone, elliptic curves obtain their security by combining points on mathematical curves.[20]
  55. Real-world elliptic curves aren’t too different from this, although this is just used as an example.[20]
  56. Our goal was to introduce you to the basics of elliptic curves, how they’re formed and the types of operations we can do on them.[20]
  57. Upcoming parts will talk about how we utilize the properties of elliptic curves for the public key and private key cryptography in today’s world.[20]
  58. What do elliptic curves look like?[21]
  59. In 1994, Wiles and Taylor-Wiles proved this result for semistable elliptic curves over the rationals and, in so doing, proved Fermat's Last Theorem.[21]
  60. This correspondence between elliptic curves and cusp forms - through the theory of Galois representations - now motivates an exciting area of research known as the Langlands problem.[21]
  61. Abelian Varieties can be viewed as generalizations of elliptic curves.[22]
  62. General purpose Elliptic Curve Cryptography (ECC) support, including types and traits for representing various elliptic curve forms, scalars, points, and public/secret keys composed thereof.[23]
  63. This crate provides traits for describing elliptic curves, along with types which are generic over elliptic curves which can be used as the basis of curve-agnostic code.[23]
  64. Elliptic curves are a very important new area of mathematics which has been greatly explored over the past few decades.[24]
  65. In 1994 Andrew Wiles, together with his former student Richard Taylor, solved one of the most famous maths problems of the last 400 years, Fermat's Last Theorem, using elliptic curves.[24]
  66. In the last few decades there has also been a lot of research into using elliptic curves instead of what is called RSA encryption to keep data transfer safe online.[24]
  67. The elliptic curves corresponding to whole number values of a between -2 and 1 and whole number values of values of b between -1 and 2.[24]
  68. This book is an introduction to the theory of elliptic curves, ranging from elementary topics to current research.[25]
  69. The two additional chapters concern higher-dimensional analogues of elliptic curves, including K3 surfaces and Calabi-Yau manifolds.[25]
  70. Two new appendices explore recent applications of elliptic curves and their generalizations.[25]
  71. Please see our tracking issue for additional elliptic curves if you are interested in curves beyond the ones listed here.[26]
  72. Each elliptic curve point is associated with a particular parameter set.[27]
  73. We use elliptic curves because they provide a cryptographic group, i.e. a group in which the discrete logarithm problem (discussed below) is hard.[28]
  74. By convention, elliptic curve groups are written additively.[28]
  75. This is called the elliptic curve discrete log assumption.[28]
  76. In the case of a cryptographically secure elliptic curve, the isomorphism is hard to compute in the G→Fq​ direction because the elliptic curve discrete log problem is hard.[28]
  77. Elliptic Curves Elliptic curves are groups created by de(cid:12)ning a binary operation (addition) on the points of the graph of certain polynomial equations in two variables.[29]
  78. Choosing random coe(cid:14)cients results in groups with random orders near p. 1 One can use elliptic curves to factor integers, although probably not RSA moduli.[29]
  79. There is a probabilistic algorithm for proving primality that uses elliptic curves.[29]
  80. discrete logarithm problem is harder for elliptic curve groups than for the integers modulo p, permitting smaller parameters and faster algo- rithms.[29]
  81. The use of elliptic curves in cryptography was independently suggested by Neal Koblitz and Victor Miller in 1985.[30]
  82. From a high level, Crypto++ offers a numbers of schemes and alogrithms which operate over elliptic curves.[30]
  83. For cryptographic computational purposes, elliptic curves are represented in several different forms.[31]
  84. You don't need to know much algebra to understand how elliptic curve cryptography works.[32]
  85. This method can give all such functions and only them; it's not hard to see that only meromorphic functions with this property are allowed on elliptic curve.[33]
  86. In particular, elliptic curves coincide with their Jacobian and that's another explanation for the additive law.[33]
  87. Indeed elliptic curves are dominating the cryptography landscape but for people other than Mathematicians the logic behind this may not be so obvious.[34]
  88. I am therefore writing this post to give a gentle introduction in elliptic curves for people with basic mathematical background and explain why they are so popular amongst cryptographers.[34]
  89. This is exactly where elliptic curves become relevant in cryptography.[34]
  90. These groups formed by elliptic curves are the groups used for building elliptic curve cryptosystems.[34]
  91. Elliptic curve cryptography (ECC) uses the mathematical properties of elliptic curves to produce public key cryptographic systems.[35]

소스

  1. Benefits of Elliptic Curve Cryptography
  2. 2.0 2.1 2.2 2.3 Why Are They Called “Elliptic” Curves?
  3. 3.0 3.1 3.2 3.3 Elliptic Curve -- from Wolfram MathWorld
  4. 4.0 4.1 4.2 4.3 What is an elliptic curve? Informal and formal definition
  5. 5.0 5.1 5.2 Elliptic-curve cryptography
  6. 6.0 6.1 6.2 Elliptic curve
  7. Brilliant Math & Science Wiki
  8. 8.0 8.1 8.2 8.3 Elliptic curve cryptography methods
  9. 9.0 9.1 9.2 9.3 18.783 elliptic curves
  10. 10.0 10.1 10.2 Elliptic Curve Cryptography: a gentle introduction
  11. 11.0 11.1 11.2 11.3 What is Elliptic Curve Cryptography? Definition & FAQs
  12. 2.0 Elliptic Curve Groups over Real Numbers
  13. Elliptic Curve - an overview
  14. 14.0 14.1 14.2 14.3 elliptic curve in nLab
  15. 15.0 15.1 15.2 15.3 The gra d uate stude nt secti on
  16. 16.0 16.1 Elliptic Curve Cryptography for Beginners
  17. A (relatively easy to understand) primer on elliptic curve cryptography
  18. 18.0 18.1 18.2 18.3 Exploring Elliptic Curve Pairings
  19. Encyclopedia of Mathematics
  20. 20.0 20.1 20.2 20.3 Learning Cryptography, Part 3: Elliptic Curves
  21. 21.0 21.1 21.2 E is for Elliptic Curves
  22. Elliptic Curve
  23. 23.0 23.1 elliptic_curve
  24. 24.0 24.1 24.2 24.3 Elliptic cryptography
  25. 25.0 25.1 25.2 Elliptic Curves
  26. RustCrypto/elliptic-curves: Collection of pure Rust elliptic curve implementations: NIST P-256, P-384, secp256k1
  27. Fundamental Elliptic Curve Cryptography Algorithms
  28. 28.0 28.1 28.2 28.3 Elliptic curves
  29. 29.0 29.1 29.2 29.3 Elliptic curves
  30. 30.0 30.1 Elliptic Curve Cryptography
  31. elliptic-curve
  32. How are points on an elliptic curve discretized?
  33. 33.0 33.1 Why is an elliptic curve a group?
  34. 34.0 34.1 34.2 34.3 Demystifying Elliptic Curve Cryptography
  35. What is Elliptic curve cryptography (ECC)?

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Spacy 패턴 목록

  • [{'LOWER': 'elliptic'}, {'LEMMA': 'curve'}]