Qiqi Duan , Chang Shao , Guochen Zhou , Haobin Yang , Qi Zhao , Yuhui Shi
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引用次数: 0
Abstract
Given the ubiquity of non-separable optimization problems in real worlds, in this paper we analyze and extend the large-scale version of the well-known cooperative coevolution (CC), a divide-and-conquer black-box optimization framework, on non-separable functions. First, we reveal empirical reasons of when decomposition-based methods are preferred or not in practice on some non-separable large-scale problems, which have not been clearly pointed out in many previous CC papers. Then, we formalize CC to a continuous-game model via simplification, but without losing its essential property. Different from previous evolutionary game theory for CC, our new model provides a much simpler but useful viewpoint to analyze its convergence, since only the pure Nash equilibrium concept is needed and more general fitness landscapes can be explicitly considered. Based on convergence analyses, we propose a hierarchical decomposition strategy for better generalization, as for any decomposition, there is a risk of getting trapped into a suboptimal Nash equilibrium. Finally, we use powerful distributed computing to accelerate it under the recent multi-level learning framework, which combines the fine-tuning ability from decomposition with the invariance property of CMA-ES. Experiments on a set of high-dimensional test functions validate both its search performance and scalability (w.r.t. CPU cores) on a clustering computing platform with 400 CPU cores.
鉴于不可分割的优化问题在现实世界中无处不在,我们在本文中分析并扩展了著名的合作协同进化(CC)--一种分而治之的黑箱优化框架--在不可分割函数上的大规模版本。首先,我们揭示了在某些不可分割的大规模问题上,基于分解的方法在实践中是否更受青睐的经验原因,这在之前的许多 CC 论文中都没有明确指出。然后,我们通过简化将 CC 形式化为连续博弈模型,但并没有失去其基本特性。与以往的 CC 演化博弈论不同,我们的新模型只需要纯粹的纳什均衡概念,而且可以明确地考虑更一般的适合度景观,因此为分析其收敛性提供了一个更简单但有用的视角。基于收敛性分析,我们提出了一种分层分解策略,以实现更好的泛化,因为对于任何分解,都存在陷入次优纳什均衡的风险。最后,我们利用强大的分布式计算,在最新的多层次学习框架下对其进行加速,从而将分解带来的微调能力与 CMA-ES 的不变性相结合。在一个拥有 400 个 CPU 内核的集群计算平台上,一组高维测试函数的实验验证了它的搜索性能和可扩展性(相对于 CPU 内核)。
期刊介绍:
Applied Soft Computing is an international journal promoting an integrated view of soft computing to solve real life problems.The focus is to publish the highest quality research in application and convergence of the areas of Fuzzy Logic, Neural Networks, Evolutionary Computing, Rough Sets and other similar techniques to address real world complexities.
Applied Soft Computing is a rolling publication: articles are published as soon as the editor-in-chief has accepted them. Therefore, the web site will continuously be updated with new articles and the publication time will be short.