Optimizing Low Dimensional Functions over the Integers

Conference on Integer Programming and Combinatorial Optimization Pub Date : 2023-03-04 DOI:10.48550/arXiv.2303.02474

D. Dadush, A. L'eonard, Lars Rohwedder, José Verschae

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引用次数: 1

Abstract

We consider box-constrained integer programs with objective $g(Wx) + c^T x$, where $g$ is a"complicated"function with an $m$ dimensional domain. Here we assume we have $n \gg m$ variables and that $W \in \mathbb Z^{m \times n}$ is an integer matrix with coefficients of absolute value at most $\Delta$. We design an algorithm for this problem using only the mild assumption that the objective can be optimized efficiently when all but $m$ variables are fixed, yielding a running time of $n^m(m \Delta)^{O(m^2)}$. Moreover, we can avoid the term $n^m$ in several special cases, in particular when $c = 0$. Our approach can be applied in a variety of settings, generalizing several recent results. An important application are convex objectives of low domain dimension, where we imply a recent result by Hunkenschr\"oder et al. [SIOPT'22] for the 0-1-hypercube and sharp or separable convex $g$, assuming $W$ is given explicitly. By avoiding the direct use of proximity results, which only holds when $g$ is separable or sharp, we match their running time and generalize it for arbitrary convex functions. In the case where the objective is only accessible by an oracle and $W$ is unknown, we further show that their proximity framework can be implemented in $n (m \Delta)^{O(m^2)}$-time instead of $n (m \Delta)^{O(m^3)}$. Lastly, we extend the result by Eisenbrand and Weismantel [SODA'17, TALG'20] for integer programs with few constraints to a mixed-integer linear program setting where integer variables appear in only a small number of different constraints.

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整数上的低维函数优化

我们考虑目标为$g(Wx) + c^T x$的盒约束整数规划，其中$g$是一个具有$m$维域的“复杂”函数。这里我们假设我们有$n \gg \m $变量，并且$W \in \mathbb Z^{m \乘以n}$是一个整数矩阵，其系数的绝对值不超过$\Delta$。我们为这个问题设计了一个算法，只使用温和的假设，即当除了$m$变量之外的所有变量都是固定的时，目标可以有效地优化，从而产生$n^m(m \Delta)^{O(m^2)}$的运行时间。此外，在一些特殊情况下，特别是当c = 0时，我们可以避免使用n^m项。我们的方法可以应用于各种环境，概括了最近的几个结果。一个重要的应用是低域维数的凸目标，在这里我们引用了Hunkenschr\ ' oder等人[SIOPT'22]关于0-1超立方体和尖锐或可分离凸$g$的最新结果，假设$W$是明确给定的。通过避免直接使用邻近结果，只有当$g$是可分离的或尖锐的，我们匹配它们的运行时间，并将其推广到任意凸函数。在目标只能由oracle访问且$W$未知的情况下，我们进一步证明了它们的邻近框架可以在$n (m \Delta)^{O(m^2)}$时间内实现，而不是$n (m \Delta)^{O(m^3)}$时间内实现。最后，我们将Eisenbrand和Weismantel [SODA'17, TALG'20]对约束较少的整数规划的结果推广到一个混合整数线性规划设置，其中整数变量只出现在少数不同的约束中。

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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Conference on Integer Programming and Combinatorial Optimization

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