Abstract
In 1970 a negative solution to the tenth Hilbert problem, concerning the determination of integral solutions of diophantine equations, was published by Y. W. Matiyasevich. Despite this result, we can present algorithms to compute integral solutions (roots) to a wide class of quadratic diophantine equations of the form q(x) = d, where q : Z is a homogeneous quadratic form. We will focus on the roots of one (i.e., d = 1) of quadratic unit forms (q11 = ' = qnn = 1). In particular, we will describe the set of roots Rq of positive definite quadratic forms and the set of roots of quadratic forms that are principal. The algorithms and results presented here are successfully used in the representation theory of finite groups and algebras. If q is principal (q is positive semi-definite and Ker q={v i¾? Zn; q(v) = 0}=Z i¾? h) then |Rq| = ∞. For a given unit quadratic form q (or its bigraph), which is positive semi-definite or is principal, we present an algorithm which aligns roots Rq in a i¾?-mesh. If q is principal (|Rq| < ∞), then our algorithm produces consecutive roots in Rq from finite subset of Rq, determined in an initial step of the algorithm.
Highlights
In 1900 during the International Congress of Mathematicians in Paris David Hilbert presented 23 problems, known today as Hilbert problems. One of those problems was The Tenth Hilbert Problem, which consists in finding a general procedure for solving any diophantine equation, i.e., a polynomial with the integral coefficients in which only integral variables are allowed
Given a finite poset I we study an integral quadratic form of I defined by the incidence matrix CI ∈ Mn(Z)
The aim of this paper is to present a Φ-mesh algorithm which, for a given principal quadratic form, returns a part of the Φ-mesh graph
Summary
In 1900 during the International Congress of Mathematicians in Paris David Hilbert presented 23 problems, known today as Hilbert problems. U For a given unit quadratic form q (or its bigraph), which is positive semi-definite or is principal, we present an algorithm which aligns roots Rq in a Φ-mesh. Given a finite poset I we study an integral quadratic form of I defined by the incidence matrix CI ∈ Mn(Z).
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