单调类学习的超多项式下界

Electron. Colloquium Comput. Complex. Pub Date : 2023-01-20 DOI:10.48550/arXiv.2301.08486

N. Bshouty

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引用次数: 2

摘要

Koch, Strassle和Tan [SODA 2023]表明，在随机指数时间假设下，对于$n$ -可变大小- $s$ DNF，大小- $s$决策树和$\log s$ - junta的DNF类(返回DNF假设)，没有无分布的pac学习算法可以在时间$n^{\tilde O(\log\log s)}$上运行。假设对集盖的硬度有一个自然的猜想，他们给出了下界$n^{\Omega(\log s)}$。这与最著名的$n$ -可变大小- $s$决策树和$\log s$ -军政府的上界相匹配。在本文中，我们给出了$n$ -可变大小- $s$单调DNF、大小- $s$单调决策树和单调$\log s$ - junta的相同下界。这解决了Koch, Strassle和Tan提出的开放性问题，并将上述结果纳入其中。下界成立，即使学习者知道分布，也可以在多项式时间内根据分布绘制样本，并在多项式时间内计算出支持分布的所有点上的目标函数。

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Superpolynomial Lower Bounds for Learning Monotone Classes

Koch, Strassle, and Tan [SODA 2023], show that, under the randomized exponential time hypothesis, there is no distribution-free PAC-learning algorithm that runs in time $n^{\tilde O(\log\log s)}$ for the classes of $n$-variable size-$s$ DNF, size-$s$ Decision Tree, and $\log s$-Junta by DNF (that returns a DNF hypothesis). Assuming a natural conjecture on the hardness of set cover, they give the lower bound $n^{\Omega(\log s)}$. This matches the best known upper bound for $n$-variable size-$s$ Decision Tree, and $\log s$-Junta. In this paper, we give the same lower bounds for PAC-learning of $n$-variable size-$s$ Monotone DNF, size-$s$ Monotone Decision Tree, and Monotone $\log s$-Junta by~DNF. This solves the open problem proposed by Koch, Strassle, and Tan and subsumes the above results. The lower bound holds, even if the learner knows the distribution, can draw a sample according to the distribution in polynomial time, and can compute the target function on all the points of the support of the distribution in polynomial time.

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Electron. Colloquium Comput. Complex.

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