Abstract :
We give a polynomial time approximation scheme (PTAS) for computing the supremum of a Gaussian process. That is, given a finite set of vectors V ⊆ Rd, we compute a (1+ε)-factor approximation to EX←Nd[supv∈V |〈v, X〉|] deterministically in time poly(d) · |V|(Oε)(1). Previously, only a constant factor deterministic polynomial time approximation algorithm was known due to the work of Ding, Lee and Peres [1]. This answers an open question of Lee [2] and Ding [3]. The study of supremum of Gaussian processes is of considerable importance in probability with applications in functional analysis, convex geometry, and in light of the recent breakthrough work of Ding, Lee and Peres [1], to random walks on finite graphs. As such our result could be of use elsewhere. In particular, combining with the recent work of Ding [3], our result yields a PTAS for computing the cover time of bounded degree graphs. Previously, such algorithms were known only for trees. Along the way, we also give an explicit oblivious estimator for semi-norms in Gaussian space with optimal query complexity. Our algorithm and its analysis are elementary in nature using two classical comparison inequalities in convex geometry- Slepian´s lemma and Kanter´s lemma.
Keywords :
Gaussian processes; approximation theory; computational complexity; geometry; probability; trees (mathematics); vectors; Gaussian process supremum computation; Kanter lemma; PTAS; Slepian lemma; bounded degree graphs; classical comparison inequalities; constant factor deterministic polynomial time approximation algorithm; convex geometry; factor approximation; finite graphs; functional analysis; optimal query complexity; probability; random walks; seminorm explicit oblivious estimator; trees; vectors; Algorithm design and analysis; Approximation algorithms; Approximation methods; Gaussian distribution; Gaussian processes; Polynomials; Vectors; cover time; epsilon-nets; gaussian processes; majorizing measures;
