Instance-optimal geometric algorithms
Keywords: algorithm, fiber, structures, geometry, optimization, sensors, trees, location, entropy, algorithms, bounds, computation, data, convex, theory, hull, segments, optimality, point, segment, decision, intersection, adaptive, chemical, sensitive, Computational, lower, optic, Orthogonal, datas, Output-sensitive
Abstract
We prove the existence of an algorithm A for computing 2-d or 3-d convex hulls that is optimal for every point set in the following sense: for every set S of n points and for every algorithm A? in a certain class A, the running time of A on the worst permutation of S for A is at most a constant factor times the running time of A? on the worst permutation of S for A?. In fact, we can establish a stronger property: for every S and A?, the running time of A on S is at most a constant factor times the average running time of A? over all permutations of S. We call algorithms satisfying these properties instance-optimal in the order-oblivious and random-order setting. Such instance-optimal algorithms simultaneously subsume output-sensitive algorithms and distribution-dependent average-case algorithms, and all algorithms that do not take advantage of the order of the input or that assume the input is given in a random order. The class A under consideration consists of all algorithms in a decision tree model where the tests involve only multilinear functions with a constant number of arguments. To establish an instance-specific lower bound, we deviate from traditional Ben-Or-style proofs and adopt an interesting adversary argument. For 2-d convex hulls, we prove that a version of the well known algorithm by Kirkpatrick and Seidel (1986) or Chan, Snoeyink, and Yap (1995) already attains this lower bound. For 3-d convex hulls, we propose a new algorithm. We further obtain instance-optimal results for a few other standard problems in computational geometry, such as maxima in 2-d and 3-d, orthogonal line segment intersection in 2-d, offline orthogonal range searching in 2-d, off-line halfspace range reporting in 2-d and 3-d, and off-line point location in 2-d. The theory we develop also neatly reveals connections to entropy-dependent data structures, and yields as a byproduct new expected-case results, e.g., for on-line orthogonal range counting in 2-d. © 2009 IEEE.
Más información
Título de la Revista: | Proceedings - Annual IEEE Symposium on Foundations of Computer Science, FOCS |
Editorial: | Society of Laparoendoscopic Surgeons |
Fecha de publicación: | 2009 |
Página de inicio: | 129 |
Página final: | 138 |
URL: | http://www.scopus.com/inward/record.url?eid=2-s2.0-77952344373&partnerID=q2rCbXpz |