通过核近似找到全局最小值

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Alessandro Rudi, Ulysse Marteau-Ferey, Francis Bach
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引用次数: 0

摘要

我们只考虑基于函数求值的平滑函数全局最小化问题。在给定精度水平下,实现最佳函数求值次数的算法通常依赖于显式构建函数近似值,然后用运行时间复杂度呈指数级的算法将其最小化。在本文中,我们考虑了一种方法,即联合建立函数近似模型并找到全局最小值。这种方法通过使用平方平滑函数的无限和来实现,并与多项式平方和层次结构有着密切联系。利用重现核希尔伯特空间的最新表示特性,可以通过子采样在函数求值次数为多项式的时间内求解无穷维优化问题,并从理论上保证求得最小值。给定 n 个样本,计算成本在时间上是\(O(n^{3.5})\),在空间上是\(O(n^2)\),我们达到全局最优的收敛速率是\(O(n^{-m/d + 1/2 + 3/d})\) 其中 m 是函数的可微分程度,d 是维数。在 Sobolev 函数的情况下,这个比率几乎是最优的,而且在更广泛的情况下,所提出的方法特别适用于具有许多导数的函数。事实上,当 m 在 d 的数量级时,向全局最优的收敛率不会受到维数诅咒的影响,维数诅咒只影响最坏情况下的常数(我们在论文中明确跟踪了这些常数)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Finding global minima via kernel approximations

Finding global minima via kernel approximations

We consider the global minimization of smooth functions based solely on function evaluations. Algorithms that achieve the optimal number of function evaluations for a given precision level typically rely on explicitly constructing an approximation of the function which is then minimized with algorithms that have exponential running-time complexity. In this paper, we consider an approach that jointly models the function to approximate and finds a global minimum. This is done by using infinite sums of square smooth functions and has strong links with polynomial sum-of-squares hierarchies. Leveraging recent representation properties of reproducing kernel Hilbert spaces, the infinite-dimensional optimization problem can be solved by subsampling in time polynomial in the number of function evaluations, and with theoretical guarantees on the obtained minimum. Given n samples, the computational cost is \(O(n^{3.5})\) in time, \(O(n^2)\) in space, and we achieve a convergence rate to the global optimum that is \(O(n^{-m/d + 1/2 + 3/d})\) where m is the degree of differentiability of the function and d the number of dimensions. The rate is nearly optimal in the case of Sobolev functions and more generally makes the proposed method particularly suitable for functions with many derivatives. Indeed, when m is in the order of d, the convergence rate to the global optimum does not suffer from the curse of dimensionality, which affects only the worst-case constants (that we track explicitly through the paper).

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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