From an engineering perspective, a design should not only perform well in an ideal condition, but should also resist noises. Such a design methodology, namely robust design, has been widely implemented in the industry for product quality control. However, classic robust design requires a lot of evaluations for a single design target, while the results of these evaluations could not be reused for a new target. To achieve a data-efficient robust design, we propose Robust Inverse Design under Noise (RID-Noise), which can utilize existing noisy data to train a conditional invertible neural network (cINN). Specifically, we estimate the robustness of a design parameter by its predictability, measured by the prediction error of a forward neural network. We also define a sample-wise weight, which can be used in the maximum weighted likelihood estimation of an inverse model based on a cINN. With the visual results from experiments, we clearly justify how RID-Noise works by learning the distribution and robustness from data. Further experiments on several real-world benchmark tasks with noises confirm that our method is more effective than other state-of-the-art inverse design methods. Code and supplementary is publicly available at https://github.com/ThyrixYang/rid-noise-aaai22
翻译:从工程角度看,设计不仅应在理想条件下良好,而且应当抵制噪音。这种设计方法,即稳健的设计,已经在产品质量控制行业中广泛采用。然而,典型的稳健设计要求对单一设计目标进行大量评价,而这些评价的结果不能再用于新的目标。为了实现数据效率强的稳健设计,我们提议在噪音(RID-Noise)下进行机械化的反向设计,它可以利用现有的噪音数据来训练一个有条件的不可逆神经网络(cINN)。具体地说,我们根据其可预测性来估计设计参数的稳健性,用远方神经网络的预测误差来衡量。我们还界定了一种抽样加权的权重,可用于对基于 cINN 的反型模型的最大加权概率估计。根据实验的视觉结果,我们明确证明RID-Noise是如何通过从数据中学习分布和稳健健的。对若干真实世界的噪音基准任务进行进一步试验,证实我们的方法比其他状态的艺术反向设计方法更有效。 httpscodeal andsubly a at at at httpstrob-comriqueriquestria.