Predicting Goal-directed Attention Control Using Inverse-Reinforcement Learning.

Neurons, behavior, data analysis and theory Pub Date : 2021-01-01 Epub Date: 2021-04-20 DOI:10.51628/001c.22322
Gregory J Zelinsky, Yupei Chen, Seoyoung Ahn, Hossein Adeli, Zhibo Yang, Lihan Huang, Dimitrios Samaras, Minh Hoai
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Abstract

Understanding how goals control behavior is a question ripe for interrogation by new methods from machine learning. These methods require large and labeled datasets to train models. To annotate a large-scale image dataset with observed search fixations, we collected 16,184 fixations from people searching for either microwaves or clocks in a dataset of 4,366 images (MS-COCO). We then used this behaviorally-annotated dataset and the machine learning method of inverse-reinforcement learning (IRL) to learn target-specific reward functions and policies for these two target goals. Finally, we used these learned policies to predict the fixations of 60 new behavioral searchers (clock = 30, microwave = 30) in a disjoint test dataset of kitchen scenes depicting both a microwave and a clock (thus controlling for differences in low-level image contrast). We found that the IRL model predicted behavioral search efficiency and fixation-density maps using multiple metrics. Moreover, reward maps from the IRL model revealed target-specific patterns that suggest, not just attention guidance by target features, but also guidance by scene context (e.g., fixations along walls in the search of clocks). Using machine learning and the psychologically meaningful principle of reward, it is possible to learn the visual features used in goal-directed attention control.

利用反强化学习预测目标导向的注意力控制
了解目标是如何控制行为的,是机器学习新方法的一个成熟问题。这些方法需要大量的标注数据集来训练模型。为了用观察到的搜索定点来注释大规模图像数据集,我们在一个包含 4366 张图像的数据集(MS-COCO)中收集了 16184 次人们搜索微波炉或时钟的定点。然后,我们利用这个经过行为注释的数据集和反强化学习(IRL)的机器学习方法,为这两个目标学习特定目标的奖励函数和策略。最后,我们使用这些学习到的策略来预测 60 名新行为搜索者(时钟 = 30,微波炉 = 30)在微波炉和时钟的厨房场景(从而控制低级图像对比度的差异)中的固定行为。我们发现,IRL 模型通过多种指标预测了行为搜索效率和固定密度图。此外,IRL 模型的奖励图揭示了特定目标的模式,表明注意力不仅受目标特征的引导,还受场景背景的引导(例如,在搜索时钟时沿着墙壁的定点)。利用机器学习和心理学上有意义的奖励原则,可以学习目标引导的注意力控制中使用的视觉特征。
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