Related papers: Deep Reinforcement Learning Models Predict Visual Responses in the Brain: A Preliminary Result

Deep Reinforcement Learning Models Predict Visual Responses in the Brain: A Preliminary Result

URL: http://arxiv.org/abs/2106.10112v1
Date: Fri, 18 Jun 2021 13:10:06 GMT
Title: Deep Reinforcement Learning Models Predict Visual Responses in the Brain: A Preliminary Result
Authors: Maytus Piriyajitakonkij, Sirawaj Itthipuripat, Theerawit Wilaiprasitporn, Nat Dilokthanakul
Abstract summary: We use reinforcement learning to train neural network models to play a 3D computer game. We find that these reinforcement learning models achieve neural response prediction accuracy scores in the early visual areas. In contrast, the supervised neural network models yield better neural response predictions in the higher visual areas.
Score: 1.0323063834827415
License: http://creativecommons.org/publicdomain/zero/1.0/
Abstract: Supervised deep convolutional neural networks (DCNNs) are currently one of the best computational models that can explain how the primate ventral visual stream solves object recognition. However, embodied cognition has not been considered in the existing visual processing models. From the ecological standpoint, humans learn to recognize objects by interacting with them, allowing better classification, specialization, and generalization. Here, we ask if computational models under the embodied learning framework can explain mechanisms underlying object recognition in the primate visual system better than the existing supervised models? To address this question, we use reinforcement learning to train neural network models to play a 3D computer game and we find that these reinforcement learning models achieve neural response prediction accuracy scores in the early visual areas (e.g., V1 and V2) in the levels that are comparable to those accomplished by the supervised neural network model. In contrast, the supervised neural network models yield better neural response predictions in the higher visual areas, compared to the reinforcement learning models. Our preliminary results suggest the future direction of visual neuroscience in which deep reinforcement learning should be included to fill the missing embodiment concept.

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