Modularity Theorem Article Index for
Modularity 		Website Links For
Theorem 		 

Information About

Modularity Theorem
  CATEGORIES ABOUT MODULARITY THEOREM
   
algebraic curves
   
riemann surfaces
   
modular forms
   
mathematical theorems
   
APPAREL
BABY
BEAUTY
BOOKS
CAR TOYS
CELL PHONES
DVD'S
ELECTRONICS
GOURMET FOOD
GROCERIES
HEALTH & PERSONAL
HOME & GARDEN
JEWELRY
MUSIC
MUSIC INSTRUMENTS
OFFICE PRODUCTS
SOFTWARE
SPORTING GOODS
TOOLS & HARDWARE
TOYS
VIDEO GAMES
SHOPPING HOME
MORE SHOPPING...



The modularity theorem is a special case of more general conjectures due to Robert Langlands . In the Langlands Programme , to every elliptic curve over a Number Field one can associate an Automorphic Form or Automorphic Representation , a suitable generalization of a modular form. Most cases of these extended conjectures have not yet been proved.


STATEMENT


The theorem states that any Elliptic Curve over Q can be obtained via a Rational Map with Integer Coefficient s from the Classical Modular Curve

X


for some integer ''N''; this is a curve with integer coefficients with an explicit definition. This mapping is called a modular parametrization of level N. If N is the smallest integer for which such a parametrization can be found (which by the modularity theorem itself is now known to be a number called the ''conductor''), then the parametrization may be defined in terms of
a mapping generated by a particular kind of modular form of weight two and level N, a normalized Newform with integer q-expansion, followed if need be by an Isogeny .

From another point of view, given an elliptic curve E over Q we may define a corresponding L-series . The L-series is a Dirichlet Series which we may write

:L(s, E) = \sum_{n=1}^\infty rac{c_n}{n^s}.

We can take the same coefficients, and use them to define a function in powers of q

:f(q, E) = \sum_{n=1}^\infty c_n q^n.

If we make the substitution q = exp(2πiτ), then the series becomes a Fourier Series , and so the coefficients are sometimes called "q-series coefficients", but other times "Fourier coefficients". The function obtained in this way, remarkably, is a Cusp Form of weight two and level N and is also an eigenform (an eigenvector of all Hecke Operator s); this is the Hasse–Weil conjecture, which follows from the modularity theorem.

Some modular forms of level two, in turn, correspond to Holomorphic Differential s for an elliptic curve. The Jacobian of the modular curve can (up to isogeny) be written as a product of irreducible abelian varieties, corresponding to Hecke eigenforms of weight 2. The 1-dimensional factors are elliptic curves (there can also be higher dimensional factors, so not all Hecke eigenforms correspond to rational elliptic curves). The curve we obtain by finding the corresponding cusp form, and then constructing a curve from it, is Isogenous to the original curve (but not in general isomorphic to it).


HISTORY

An incorrect version of this Theorem was first Conjecture d by Yutaka Taniyama in September 1955 . With Goro Shimura he improved its rigor until 1957 . Taniyama died in 1958 . The conjecture was rediscovered by André Weil in 1967, who showed that it would follow from the (conjectured) functional equations for some twisted L-series of the elliptic curve; this was the first serious evidence that the conjecture might be true.
In the 1970s it became associated with the Langlands Program of unifying conjectures in mathematics.

It attracted considerable interest in the 1980s when Gerhard Frey suggested that the Taniyama–Shimura–Weil conjecture implies Fermat's Last Theorem . He did this by attempting to show that any counterexample to Fermat's last theorem would give rise to a non-modular elliptic curve. Ken Ribet later proved this result. In 1995 , Andrew Wiles , with the partial help of Richard Taylor , proved the modularity theorem for Semistable Elliptic Curve s, which was strong enough to yield a proof of Fermat's Last Theorem .

The full modularity theorem was finally proved in 1999 by Breuil, Conrad, Diamond, and Taylor who, building on Wiles' work, incrementally chipped away at the remaining cases until the full result was proved.

Several theorems in number theory similar to Fermat's last theorem follow from the modularity theorem. For example: no cube can be written as a sum of two Coprime ''n''-th powers, ''n'' ≥ 3. (The case ''n'' = 3 was already known by Euler .)

In March 1996 Wiles shared the Wolf Prize with Robert Langlands .


REFERENCES

  • Henri Darmon: '' A Proof of the Full Shimura-Taniyama-Weil Conjecture Is Announced '', Notices of the American Mathematical Society, Vol. 46 (1999), No. 11. Contains a gentle introduction to the theorem and an outline of the proof.

  • Christophe Breuil, Brian Conrad, Fred Diamond, Richard Taylor: '' On the modularity of elliptic curves over Q: Wild 3-adic exercises '', Journal of the American Mathematical Society 14 (2001), pp. 843–939. Contains the proof of the modularity theorem.

  • Barry Mazur , Number theory as gadfly - American Mathematical Monthly, 98 (7), August-September 1991, pp. 593–610, Discusses the Taniyama-Shimura conjecture 3 years before it was proven for infinitely many cases.

  • Weil, André ''Über die Bestimmung Dirichletscher Reihen durch Funktionalgleichungen.'' Math. Ann. 168 1967 149-156.

  • Wiles, Andrew [http://links.jstor.org/sici?sici=0003-486X%28199505%292%3A141%3A3%3C443%3AMECAFL%3E2.0.CO%3B2-Y ''Modular elliptic curves and Fermat's last theorem.''] Ann. of Math. (2) 141 (1995), no. 3, 443--551.

  • Taylor, Richard; Wiles, Andrew ''Ring-theoretic properties of certain Hecke algebras.'' Ann. of Math. (2) 141 (1995), no. 3, 553--572

  • Wiles, Andrew ''Modular forms, elliptic curves, and Fermat's last theorem.'' Proceedings of the International Congress of Mathematicians, Vol. 1, 2 (Zürich, 1994), 243--245, Birkhäuser, Basel, 1995.