Dispersion of Mass and the Complexity of Randomized Geometric Algorithms
Dispersion of Mass and the Complexity of Randomized Geometric Algorithms
How much can randomness help computation? Motivated by this general question and by volume computation, one of the few instances where randomness provably helps, we analyze a notion of dispersion and connect it to asymptotic convex geometry. We obtain a nearly quadratic lower bound on the complexity of randomized volume algorithms for convex bodies in R^n (the current best algorithm has complexity roughly n^4, conjectured to be n^3). Our main tools, dispersion of random determinants and dispersion of the length of a random point from a convex body, are of independent interest and applicable more generally; in particular, the latter is closely related to the variance hypothesis from convex geometry. This geometric dispersion also leads to lower bounds for matrix problems and property testing.
Full version of L. Rademacher, S. Vempala: Dispersion of Mass and the Complexity of Randomized Geometric Algorithms. Proc. 47th IEEE Annual Symp. on Found. of Comp. Sci. (2006). A version of it to appear in Advances in Mathematics
- Georgia Institute of Technology United States
- Massachusetts Institute of Technology United States
- GEORGIA TECH RESEARCH CORPORATION United States
- Yale University United States
Computational Geometry (cs.CG), FOS: Computer and information sciences, Mathematics(all), Analysis of algorithms and problem complexity, Computational Complexity (cs.CC), Determinant computation, lower bounds, Complexity and performance of numerical algorithms, variance hypothesis, dispersion of mass, Computer graphics; computational geometry (digital and algorithmic aspects), Computer Science - Data Structures and Algorithms, FOS: Mathematics, Volume computation, Data Structures and Algorithms (cs.DS), determinant computation, volume computation, randomized algorithms, Randomized algorithms, Variance hypothesis, Lower bounds, Functional Analysis (math.FA), Mathematics - Functional Analysis, Computer Science - Computational Complexity, Dispersion of mass, Computer Science - Computational Geometry
Computational Geometry (cs.CG), FOS: Computer and information sciences, Mathematics(all), Analysis of algorithms and problem complexity, Computational Complexity (cs.CC), Determinant computation, lower bounds, Complexity and performance of numerical algorithms, variance hypothesis, dispersion of mass, Computer graphics; computational geometry (digital and algorithmic aspects), Computer Science - Data Structures and Algorithms, FOS: Mathematics, Volume computation, Data Structures and Algorithms (cs.DS), determinant computation, volume computation, randomized algorithms, Randomized algorithms, Variance hypothesis, Lower bounds, Functional Analysis (math.FA), Mathematics - Functional Analysis, Computer Science - Computational Complexity, Dispersion of mass, Computer Science - Computational Geometry
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