概率秩和矩阵刚性

Josh Alman, Richard Ryan Williams
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引用次数: 44

摘要

我们考虑了矩阵的概率秩和概率符号秩的概念,它们衡量了一个矩阵可以被低秩矩阵概率表示的程度。我们演示了几种与矩阵刚性、通信复杂性和电路下限有关的连接。最有趣的结果是:沃尔什-阿达玛变换不是很严格。我们给出了一类矩阵的刚性的惊人上界,这些矩阵的刚性已被广泛研究,并被推测为高刚性。对于2n X 2n的Walsh-Hadamard变换Hn(即Sylvester矩阵,即内积模2的通信矩阵),我们展示了如何在任何域上对所有小ε > 0的情况下,仅修改每一行中的2ε n项,使Hn的秩降至2n(1-Ω(ε2/log(1/ε)))以下。也就是说,不可能通过L. Valiant的矩阵刚性方法来证明Hadamard矩阵(如Hn)上的算术电路下界。我们还给出了目标秩较小的Hn的非平凡刚性上界。矩阵刚度和阈值电路下限。给出了关于布尔电路复杂度的刚性矩阵的新结果。首先,我们证明了显式n X n布尔矩阵在n2/2(logn)δ/2修改条目(在任何字段上,对于任何δ > 0)之后保持至少2(logn)1-δ的秩将产生一个显式函数,该显式函数不具有具有两层任意线性阈值门的次二次大小的AC0电路。其次,我们证明了显式的0/1矩阵,它比最著名的符号秩的刚性下界稍微更严格,对于在两层上具有任意权值的深度二线性阈值电路的臭名昭著的困难类,它意味着指数门下界。特别地,我们证明了由这些看似困难的电路类定义的矩阵实际上分别具有低概率秩和符号秩。通信、概率秩和刚性之间的等价。自Razborov[1989]以来,人们已经知道,明确的刚性下界将解决通信复杂性中长期存在的下界问题,但似乎有可能在矩阵刚性没有取得进展的情况下证明通信下界。我们证明了对于每一个以自然方式随机自约的函数f(内积模2就是一个例子),通过与概率秩的等价,限定f的通信复杂度(在精确的技术意义上)等于限定f的矩阵的刚性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Probabilistic rank and matrix rigidity
We consider a notion of probabilistic rank and probabilistic sign-rank of a matrix, which measure the extent to which a matrix can be probabilistically represented by low-rank matrices. We demonstrate several connections with matrix rigidity, communication complexity, and circuit lower bounds. The most interesting outcomes are: The Walsh-Hadamard Transform is Not Very Rigid. We give surprising upper bounds on the rigidity of a family of matrices whose rigidity has been extensively studied, and was conjectured to be highly rigid. For the 2n X 2n Walsh-Hadamard transform Hn (a.k.a. Sylvester matrices, a.k.a. the communication matrix of Inner Product modulo 2), we show how to modify only 2ε n entries in each row and make the rank of Hn drop below 2n(1-Ω(ε2/log(1/εε))), for all small ε > 0, over any field. That is, it is not possible to prove arithmetic circuit lower bounds on Hadamard matrices such as Hn, via L. Valiant's matrix rigidity approach. We also show non-trivial rigidity upper bounds for Hn with smaller target rank. Matrix Rigidity and Threshold Circuit Lower Bounds. We give new consequences of rigid matrices for Boolean circuit complexity. First, we show that explicit n X n Boolean matrices which maintain rank at least 2(logn)1-δ after n2/2(logn)δ/2 modified entries (over any field, for any δ > 0) would yield an explicit function that does not have sub-quadratic-size AC0 circuits with two layers of arbitrary linear threshold gates. Second, we prove that explicit 0/1 matrices over ℝ which are modestly more rigid than the best known rigidity lower bounds for sign-rank would imply exponential-gate lower bounds for the infamously difficult class of depth-two linear threshold circuits with arbitrary weights on both layers. In particular, we show that matrices defined by these seemingly-difficult circuit classes actually have low probabilistic rank and sign-rank, respectively. An Equivalence Between Communication, Probabilistic Rank, and Rigidity. It has been known since Razborov [1989] that explicit rigidity lower bounds would resolve longstanding lower-bound problems in communication complexity, but it seemed possible that communication lower bounds could be proved without making progress on matrix rigidity. We show that for every function f which is randomly self-reducible in a natural way (the inner product mod 2 is an example), bounding the communication complexity of f (in a precise technical sense) is equivalent to bounding the rigidity of the matrix of f, via an equivalence with probabilistic rank.
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