弱困难问题

Proceedings of IEEE 9th Annual Conference on Structure in Complexity Theory Pub Date : 1994-06-28 DOI:10.1109/SCT.1994.315808

J. H. Lutz

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引用次数: 45

摘要

研究了复杂度类E=DTIME(2/sup线性/)中的弱完备性现象。根据标准术语，语言H对于E来说是/spl lessub msup P/-难的，如果集合P/sub m/(H)，由所有语言a /spl lessub msup P/H组成，包含整个E类。语言C对于E来说是/spl lessub msup P/-难的，如果它对于E来说是/spl lessub msup P/-难的，并且也是E的一个元素。如果集合P/sub m/(H)在E中没有测度0，那么语言H对于E来说是弱/spl lesssub msup P/-难的;如果语言C对于E来说是弱/spl lesssub msup P/-难的，那么语言C对于E来说是弱/spl lesssub msup P/-完备的，并且也是E的一个元素。本文的主要结果是构造了一个弱/spl lesssub msup P/-完备的语言，而不是/spl lesssub msup P/-完备的语言。这类语言的存在意味着已知的E的弱/spl lesssub msup P/-困难问题的复杂度强下界确实比E的/spl lesssub msup P/-困难问题的复杂度强下界更一般。这一结果的证明引入了一种新的对角化方法——鞅对角化。使用这种方法，一个人同时开发了无限的多项式时间可计算鞅(投注策略)和相应的语言家族，以击败这些鞅(即防止他们赢得太多的钱)，同时也追求另一个议程。鞅对角化可能对各种应用都很有用。

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Weakly hard problems

A weak completeness phenomenon is investigated in the complexity class E=DTIME(2/sup linear/). According to standard terminology, a language H is /spl lessub msup P/-hard for E if the set P/sub m/(H), consisting of all languages A/spl lessub msup P/H, contains the entire class E. A language C is /spl lessub msup P/-complete for E if it is /spl lessub msup P/-hard for E and is also an element of E. Generalizing this, a language H is weakly /spl lessub msup P/-hard for E if the set P/sub m/(H) does not have measure 0 in E. A language C is weakly /spl lessub msup P/-complete for E if it is weakly /spl lessub msup P/-hard for E and is also an element of E. The main result of this paper is the construction of a language that is weakly /spl lessub msup P/-complete, but not /spl lessub msup P/-complete, for E. The existence of such languages implies that previously known strong lower bounds on the complexity of weakly /spl lessub msup P/-hard problems for E are indeed more general than the corresponding bounds for /spl lessub msup P/-hard problems for E. The proof of this result introduces a new diagonalization method, called martingale diagonalization. Using this method, one simultaneously develops an infinite family of polynomial time computable martingales (betting strategies) and a corresponding family of languages that defeat these martingales (i.e. prevent them from winning too much money), while also pursuing another agenda. Martingale diagonalization may be useful for a variety of applications.<>

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Proceedings of IEEE 9th Annual Conference on Structure in Complexity Theory

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