In number theory, the Néron–Tate height (or canonical height) is a quadratic form on the Mordell-Weil group of rational points of an abelian variety defined over a global field. It is named after André Néron and John Tate.
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Néron defined the Néron–Tate height as a sum of local heights.[1] Tate (unpublished) defined it globally by observing that the logarithmic height hL associated to an invertible sheaf L on an abelian variety A is “almost quadratic,” and used this to show that the limit
exists and defines a quadratic form on the Mordell-Weil group of rational points.
The Néron–Tate height depends on the choice of an invertible sheaf (or an element of the Néron-Severi group) on the abelian variety. If the abelian variety A is defined over a number field K and the invertible sheaf is ample, then the Néron–Tate height is positive definite in the sense that it vanishes only on torsion elements of the Mordell-Weil group A(K). More generally, induces a positive definite quadratic form on the real vector space .
On an elliptic curve, the Néron-Severi group is of rank one and has a unique ample generator, so this generator is often used to define the Néron–Tate height, which is denoted without reference to a particular line bundle. (However, the height that naturally appears in the statement of the Birch–Swinnerton-Dyer conjecture is twice this height.) On abelian varieties of higher dimension, there need not be a particular choice of smallest ample line bundle to be used in defining the Néron–Tate height.
The bilinear form associated to the canonical height on an elliptic curve E is
The elliptic regulator of E/K is
where P1,…,Pr is a basis for the Mordell-Weil group E(K) modulo torsion (cf. Gram determinant). The elliptic regulator does not depend on the choice of basis.
More generally, let A/K be an abelian variety, let B ≅ Pic0(A) be the dual abelian variety to A, and let P be the Poincaré line bundle on A × B. Then the abelian regulator of A/K is defined by choosing a basis Q1,…,Qr for the Mordell-Weil group A(K) modulo torsion and a basis η1,…,ηr for the Mordell-Weil group B(K) modulo torsion and setting
(The definitions of elliptic and abelian regulator are not entirely consistent, since if A is an elliptic curve, then the latter is 2r times the former.)
The elliptic and abelian regulators appear in the Birch–Swinnerton-Dyer conjecture.
There are two fundamental conjectures that give lower bounds for the Néron–Tate height. In the first, the field K is fixed and the elliptic curve E/K and point P ∈ E(K) vary, while in the second, the curve E/K is fixed while the field of definition of the point P varies.
In both conjectures, the constants are positive and depend only on the indicated quantities. It is known that the abc conjecture implies Lang's conjecture.[2] The best general result on Lehmer's conjecture is the weaker estimate due to Masser.[3] When the elliptic curve has complex multiplication, this has been improved to by Laurent.[4]
A polarized algebraic dynamical system is a triple (V,φ,L) consisting of a (smooth projective) algebraic variety V, a self-morphism φ : V → V, and a line bundle L on V with the property that for some integer d > 1. The associated canonical height is given by the Tate limit[5]
where φ(n) = φ o φ o … o φ is the n-fold iteration of φ. For example, any morphism φ : PN → PN of degree d > 1 yields a canonical height associated to the line bundle relation φ*O(1) = O(d). If V is defined over a number field and L is ample, then the canonical height is non-negative, and
(P is preperiodic if its forward orbit P, φ(P), φ2(P), φ3(P),… contains only finitely many distinct points.)
General references for the theory of canonical heights