Title :
Approximating the volume of definable sets
Author_Institution :
LIP, CNRS, Lyon, France
Abstract :
The first part of this paper deals with finite-precision arithmetic. We give an upper bound on the precision that should be used in a Monte-Carlo integration method. Such bounds have been known only for convex sets; our bound applies to almost any “reasonable” set. In the second part of the paper, we show how to construct in polynomial time first-order formulas that approximately define the volume of definable sets. This result is based on a VC dimension hypothesis, and is inspired from the well-known complexity-theoretic result “BPP⊆2”. Finally, we show how these results can be applied to sets defined by systems of inequalities involving polynomial or exponential functions. In particular, we describe an application to a problem of structural complexity in the Blum-Shub-Smale model of computation over the reals
Keywords :
Monte Carlo methods; computational complexity; Blum-Shub-Smale model; Monte-Carlo integration method; VC dimension hypothesis; complexity-theoretic result; convex sets; definable sets; finite-precision arithmetic; polynomial time first-order formulas; structural complexity; upper bound; Arithmetic; Computational modeling; Equations; Grid computing; Polynomials; Random number generation; Upper bound; Virtual colonoscopy;
Conference_Titel :
Foundations of Computer Science, 1995. Proceedings., 36th Annual Symposium on
Conference_Location :
Milwaukee, WI
Print_ISBN :
0-8186-7183-1
DOI :
10.1109/SFCS.1995.492470
