Deterministic Approximation of Random Walks via Queries in Graphs of Unbounded Size

Proceedings of the SIAM Symposium on Simplicity in Algorithms (SOSA) Pub Date : 2021-11-03 DOI:10.1137/1.9781611977066.5

Edward Pyne, S. Vadhan

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引用次数: 6

Abstract

Consider the following computational problem: given a regular digraph G = (V,E), two vertices u, v ∈ V , and a walk length t ∈ N, estimate the probability that a random walk of length t from u ends at v to within ±ε. A randomized algorithm can solve this problem by carrying out O(1/ε) random walks of length t from u and outputting the fraction that end at v. In this paper, we study deterministic algorithms for this problem that are also restricted to carrying out walks of length t from u and seeing which ones end at v. Specifically, if G is d-regular, the algorithm is given oracle access to a function f : [d] → {0, 1} where f(x) is 1 if the walk from u specified by the edge labels in x ends at v. We assume that G is consistently labelled, meaning that the edges of label i for each i ∈ [d] form a permutation on V . We show that there exists a deterministic algorithm that makes poly(dt/ε) nonadaptive queries to f , regardless of the number of vertices in the graph G. Crucially, and in contrast to the randomized algorithm, our algorithm does not simply output the average value of its queries. Indeed, Hoza, Pyne, and Vadhan (ITCS 2021) showed that any deterministic algorithm of the latter form that works for graphs of unbounded size must have query complexity at least exp(Ω̃(log(t) log(1/ε))). In the language of pseudorandomness, our result is a separation between the query complexity of “deterministic samplers” and “deterministic averaging samplers” for the class of “permutation branching programs of unbounded width”. Our separation is stronger than the prior separation of Pyne and Vadhan (CCC 2021), and has a much simpler proof (not using spectral graph theory or the Impagliazzo–Nisan–Wigderson pseudorandom generator). On the other hand, the algorithm of Pyne and Vadhan is explicit and computable in small space, whereas ours is not explicit (unless we assume the existence of an optimal explicit pseudorandom generator for permutation branching programs of bounded width).

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无界图中随机游走查询的确定性逼近

考虑以下计算问题:给定一个正则有向图G = (V,E)，两个顶点u, V∈V，行走长度t∈N，估计从u到V到±ε范围内的随机行走长度t的概率。一种随机算法可以通过从u开始执行O(1/ε)个长度为t的随机漫步，并输出以v结束的分数来解决这个问题。本文研究了该问题的确定性算法，该算法也被限制为从u开始执行长度为t的漫步，并观察哪些漫步以v结束。[d]→{0,1}，其中f(x)为1，如果x中的边标号指定的从u开始的行走结束于V。我们假设G是一致标记的，这意味着对于每个i∈[d]，标号i的边在V上形成了一个排列。我们证明了存在一种确定性算法，无论图g中顶点的数量如何，都可以对f进行poly(dt/ε)非自适应查询。至关重要的是，与随机化算法相比，我们的算法并不简单地输出其查询的平均值。事实上，Hoza, Pyne和Vadhan (ITCS 2021)表明，对于无界大小的图，任何后一种形式的确定性算法都必须具有至少exp(Ω (log(t) log(1/ε)))的查询复杂度。在伪随机的语言中，我们的结果是一类“无界宽度的排列分支规划”的“确定性采样器”和“确定性平均采样器”的查询复杂度的分离。我们的分离比Pyne和Vadhan之前的分离(CCC 2021)更强，并且有一个更简单的证明(不使用谱图理论或Impagliazzo-Nisan-Wigderson伪随机生成器)。另一方面，Pyne和Vadhan的算法是显式的，在小空间中是可计算的，而我们的算法则不是显式的(除非我们假设存在一个最优的显式伪随机生成器，用于有界宽度的排列分支程序)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the SIAM Symposium on Simplicity in Algorithms (SOSA)

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