Randomness conductors and constant-degree lossless expanders

Proceedings 17th IEEE Annual Conference on Computational Complexity Pub Date : 2002-05-19 DOI:10.1145/509907.510003

Michael R. Capalbo, Omer Reingold, S. Vadhan, A. Wigderson

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引用次数: 249

Abstract

The main concrete result of this paper is the first explicit construction of constant degree lossless expanders. In these graphs, the expansion factor is almost as large as possible: (1—ε)D, where D is the degree and ε is an arbitrarily small constant. The best previous explicit constructions gave expansion factor D/2, which is too weak for many applications. The D/2 bound was obtained via the eigenvalue method, and is known that that method cannot give better bounds.The main abstract contribution of this paper is the introduction and initial study of randomness conductors, a notion which generalizes extractors, expanders, condensers and other similar objects. In all these functions, certain guarantee on the input "entropy" is converted to a guarantee on the output "entropy". For historical reasons, specific objects used specific guarantees of different flavors. We show that the flexibility afforded by the conductor definition leads to interesting combinations of these objects, and to better constructions such as those above.The main technical tool in these constructions is a natural generalization to conductors of the zig-zag graph product, previously defined for expanders and extractors.

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随机导体和恒定度无损扩展器

本文的主要具体成果是首次明确构造了常度无损展开器。在这些图中，膨胀因子几乎是尽可能大的:(1 -ε)D，其中D是度，ε是一个任意小的常数。以前最好的显式结构给出了扩展因子D/2，这对于许多应用来说太弱了。D/2边界是通过特征值法得到的，已知该方法不能给出更好的边界。本文的主要抽象贡献是引入并初步研究了随机导体，这是一个泛化抽取器、膨胀器、冷凝器和其他类似物体的概念。在所有这些函数中，对输入“熵”的一定保证转化为对输出“熵”的保证。由于历史原因，特定的对象使用不同口味的特定保证。我们展示了导体定义所提供的灵活性导致了这些对象的有趣组合，以及诸如上述的更好的结构。这些结构中的主要技术工具是对锯齿形图积导体的自然推广，之前为膨胀器和提取器定义。

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 17th IEEE Annual Conference on Computational Complexity

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