| Birch And Swinnerton-dyer Conjecture |
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| CATEGORIES ABOUT BIRCH AND SWINNERTON-DYER CONJECTURE | |
| number theory | |
| zeta and l-functions | |
| diophantine geometry | |
| conjectures | |
| unsolved problems in mathematics | |
| millennium prize problems | |
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In Mathematics , the Birch and Swinnerton-Dyer conjecture relates the rank of the Abelian Group of points over a Number Field of an Elliptic Curve ''E'' to the order of zero of the associated L-function ''L''(''E'', ''s'') at ''s'' = 1. As of 2007, it has been proved only in special cases, all of rank less than or equal to 1. It has been an open problem for around 40 years, and has stimulated much research; its status as one of the most challenging mathematical questions has become widely recognized. It is one of the Millennium Prize Problems listed by the Clay Mathematics Institute , which has offered a USD 1,000,000 prize for the first correct proof. BACKGROUND In 1922 Louis Mordell proved Mordell's Theorem : the group of rational points on an elliptic curve has a finite basis. This means that for any elliptic curve there is a finite sub-set of the rational points on the curve, from which all further rational points may be generated. If the number of rational points on a curve is Infinite then some point in a finite basis must have infinite order. The number of ''independent'' basis points with infinite order is called the Rank of the curve, and is an important Invariant property of an elliptic curve. If the rank of an elliptic curve is 0 then the curve has only a finite number of rational points. On the other hand, if the rank of the curve is greater than 0, then the curve has an infinite number of rational points. Although Mordell's theorem shows that the rank of an elliptic curve is always finite, it does not give an effective method for calculating the rank of every curve. The rank of certain elliptic curves can be calculated using numerical methods but (in the current state of knowledge) these cannot be generalised to handle all curves. An ''L''-function ''L''(''E'', ''s'') can be defined for an elliptic curve ''E'' by constructing an Euler Product from the number of points on the curve modulo each Prime ''p''. This ''L''-function is analogous to the Riemann Zeta Function and the Dirichlet L-series that is defined for a binary Quadratic Form . It is a special case of a Hasse-Weil L-function . The natural definition of ''L''(''E'', ''s'') only converges for values of ''s'' in the complex plane with Re(''s'') > 3/2. Helmut Hasse conjectured that ''L''(''E'', ''s'') could be extended by Analytic Continuation to the whole complex plane. This conjecture was first proved by Max Deuring for elliptic curves with Complex Multiplication . It was subsequently shown to be true for all elliptic curves, as a consequence of the Modularity Theorem . Finding rational points on a general elliptic curve is a difficult problem. Finding the points on an elliptic curve modulo a given prime ''p'' is conceptually straightforward, as there are only a finite number of possibilities to check. However, for large primes it is computationally intensive. HISTORY In the early 1960s Peter Swinnerton-Dyer used the EDSAC computer at the University Of Cambridge Computer Laboratory to calculate the number of points modulo ''p'' (denoted by ''Np'') for a large number of primes ''p'' on elliptic curves whose rank was known. From these numerical results Bryan Birch and Swinnerton-Dyer conjectured that ''Np'' for a curve ''E'' with rank ''r'' obeys an asymptotic law : |
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