Polynomial-time computing over quadratic maps I: sampling in real algebraic sets

Abstract

Given a quadratic map Q : Kn -> Kk defined over a computable subring D of a real closed field K, and a polynomial p(Y1,...,Yk) of degree d, we consider the zero set Z=Z(p(Q(X)),Kn) of the polynomial p(Q(X1,...,Xn)). We present a procedure that computes, in (dn)O(k) arithmetic operations in D, a set S of (real univariate representations of) sampling points in Kn that intersects nontrivially each connected component of Z. As soon as k=o(n), this is faster than the standard methods that all have exponential dependence on n in the complexity. In particular, our procedure is polynomial-time for constant k. In contrast, the best previously known procedure (due to A.Barvinok) is only capable of deciding in nO(k2) operations the nonemptiness (rather than constructing sampling points) of the set Z in the case of p(Y)=sumi Yi2 and homogeneous Q. A by-product of our procedure is a bound (dn)O(k) on the number of connected components of Z. The procedure consists of exact symbolic computations in D and outputs vectors of algebraic numbers. It involves extending K by infinitesimals and subsequent limit computation by a novel procedure that utilizes knowledge of an explicit isomorphism between real algebraic sets.

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