Significance[edit]

Height functions allow mathematicians to count objects, such as rational points, that are otherwise infinite in quantity. For instance, the set of rational numbers of naive height (the maximum of the numerator and denominator when expressed in lowest terms) below any given constant is finite despite the set of rational numbers being infinite.[2] In this sense, height functions can be used to prove asymptotic results such as Baker's theorem in transcendental number theory which was proved by Alan Baker (1966, 1967a, 1967b).


In other cases, height functions can distinguish some objects based on their complexity. For instance, the subspace theorem proved by Wolfgang M. Schmidt (1972) demonstrates that points of small height (i.e. small complexity) in projective space lie in a finite number of hyperplanes and generalizes Siegel's theorem on integral points and solution of the S-unit equation.[3]


Height functions were crucial to the proofs of the Mordell–Weil theorem and Faltings's theorem by Weil (1929) and Faltings (1983) respectively. Several outstanding unsolved problems about the heights of rational points on algebraic varieties, such as the Manin conjecture and Vojta's conjecture, have far-reaching implications for problems in Diophantine approximation, Diophantine equations, arithmetic geometry, and mathematical logic.[4][5]

History[edit]

An early form of height function was proposed by Giambattista Benedetti (c. 1563), who argued that the consonance of a musical interval could be measured by the product of its numerator and denominator (in reduced form); see Giambattista Benedetti § Music.


Heights in Diophantine geometry were initially developed by André Weil and Douglas Northcott beginning in the 1920s.[6] Innovations in 1960s were the Néron–Tate height and the realization that heights were linked to projective representations in much the same way that ample line bundles are in other parts of algebraic geometry. In the 1970s, Suren Arakelov developed Arakelov heights in Arakelov theory.[7] In 1983, Faltings developed his theory of Faltings heights in his proof of Faltings's theorem.[8]

Height functions in Diophantine geometry[edit]

Naive height[edit]

Classical or naive height is defined in terms of ordinary absolute value on homogeneous coordinates. It is typically a logarithmic scale and therefore can be viewed as being proportional to the "algebraic complexity" or number of bits needed to store a point.[2] It is typically defined to be the logarithm of the maximum absolute value of the vector of coprime integers obtained by multiplying through by a lowest common denominator. This may be used to define height on a point in projective space over Q, or of a polynomial, regarded as a vector of coefficients, or of an algebraic number, from the height of its minimal polynomial.[9]


The naive height of a rational number x = p/q (in lowest terms) is

Height functions in automorphic forms[edit]

One of the conditions in the definition of an automorphic form on the general linear group of an adelic algebraic group is moderate growth, which is an asymptotic condition on the growth of a height function on the general linear group viewed as an affine variety.[20]

Other height functions[edit]

The height of an irreducible rational number x = p/q, q > 0 is (this function is used for constructing a bijection between and ).[21]

abc conjecture

Birch and Swinnerton-Dyer conjecture

Elliptic Lehmer conjecture

Heath-Brown–Moroz constant

Height of a formal group law

Height zeta function

Raynaud's isogeny theorem

(1966). "Linear forms in the logarithms of algebraic numbers. I". Mathematika. 13 (2): 204–216. doi:10.1112/S0025579300003971. ISSN 0025-5793. MR 0220680.

Baker, Alan

Baker, Alan (1967a). "Linear forms in the logarithms of algebraic numbers. II". . 14: 102–107. doi:10.1112/S0025579300008068. ISSN 0025-5793. MR 0220680.

Mathematika

Baker, Alan (1967b). "Linear forms in the logarithms of algebraic numbers. III". . 14 (2): 220–228. doi:10.1112/S0025579300003843. ISSN 0025-5793. MR 0220680.

Mathematika

Baker, Alan; (2007). Logarithmic Forms and Diophantine Geometry. New Mathematical Monographs. Vol. 9. Cambridge University Press. p. 3. ISBN 978-0-521-88268-2. Zbl 1145.11004.

Wüstholz, Gisbert

; Gubler, Walter (2006). Heights in Diophantine Geometry. New Mathematical Monographs. Vol. 4. Cambridge University Press. ISBN 978-0-521-71229-3. Zbl 1130.11034.

Bombieri, Enrico

(2002). Computational Excursions in Analysis and Number Theory. CMS Books in Mathematics. Springer-Verlag. pp. 2, 3, 14148. ISBN 0-387-95444-9. Zbl 1020.12001.

Borwein, Peter

(1998). Automorphic Forms and Representations. Cambridge Studies in Advanced Mathematics. Vol. 55. Cambridge University Press. p. 300. ISBN 9780521658188.

Bump, Daniel

Cornell, Gary; (1986). Arithmetic geometry. New York: Springer. ISBN 0387963111. → Contains an English translation of Faltings (1983)

Silverman, Joseph H.

Faltings, Gerd (1983). "Endlichkeitssätze für abelsche Varietäten über Zahlkörpern" [Finiteness theorems for abelian varieties over number fields]. Inventiones Mathematicae (in German). 73 (3): 349–366. :1983InMat..73..349F. doi:10.1007/BF01388432. MR 0718935. S2CID 121049418.

Bibcode

(1991). "Diophantine approximation on abelian varieties". Annals of Mathematics. 123 (3): 549–576. doi:10.2307/2944319. JSTOR 2944319. MR 1109353.

Faltings, Gerd

Fili, Paul; Petsche, Clayton; Pritsker, Igor (2017). "Energy integrals and small points for the Arakelov height". Archiv der Mathematik. 109 (5): 441–454. :1507.01900. doi:10.1007/s00013-017-1080-x. S2CID 119161942.

arXiv

(1965). "Quasi-fonctions et hauteurs sur les variétés abéliennes". Annals of Mathematics (in French). 82 (2): 249–331. doi:10.2307/1970644. JSTOR 1970644. MR 0179173.

Néron, André

(2000). Polynomials with special regard to reducibility. Encyclopedia of Mathematics and Its Applications. Vol. 77. Cambridge: Cambridge University Press. p. 212. ISBN 0-521-66225-7. Zbl 0956.12001.

Schinzel, Andrzej

(1972). "Norm form equations". Annals of Mathematics. Second Series. 96 (3): 526–551. doi:10.2307/1970824. JSTOR 1970824. MR 0314761.

Schmidt, Wolfgang M.

(1988). Introduction to Arakelov theory. New York: Springer-Verlag. ISBN 0-387-96793-1. MR 0969124. Zbl 0667.14001.

Lang, Serge

Lang, Serge (1997). Survey of Diophantine Geometry. . ISBN 3-540-61223-8. Zbl 0869.11051.

Springer-Verlag

(1994). Advanced Topics in the Arithmetic of Elliptic Curves. New York: Springer. ISBN 978-1-4612-0851-8.

Silverman, Joseph H.

(1987). Diophantine approximations and value distribution theory. Lecture Notes in Mathematics. Vol. 1239. Berlin, New York: Springer-Verlag. doi:10.1007/BFb0072989. ISBN 978-3-540-17551-3. MR 0883451. Zbl 0609.14011.

Vojta, Paul

; Fomin, Sergei (1957). Elements of the Theory of Functions and Functional Analysis. New York: Graylock Press.

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Polynomial height at Mathworld