English

Neural Encoding and Decoding with Deep Learning for Dynamic Natural Vision

Neurons and Cognition 2017-11-15 v2 Quantitative Methods

Abstract

Convolutional neural network (CNN) driven by image recognition has been shown to be able to explain cortical responses to static pictures at ventral-stream areas. Here, we further showed that such CNN could reliably predict and decode functional magnetic resonance imaging data from humans watching natural movies, despite its lack of any mechanism to account for temporal dynamics or feedback processing. Using separate data, encoding and decoding models were developed and evaluated for describing the bi-directional relationships be-tween the CNN and the brain. Through the encoding models, the CNN-predicted areas covered not only the ventral stream, but also the dorsal stream, albe-it to a lesser degree; single-voxel response was visualized as the specific pixel pattern that drove the response, revealing the distinct representation of individual cortical location; cortical activation was synthesized from natural images with high-throughput to map category representation, con-trast, and selectivity. Through the decoding models, fMRI signals were directly decoded to estimate the feature representations in both visual and semantic spaces, for direct visual reconstruction and seman-tic categorization, respectively. These results cor-roborate, generalize, and extend previous findings, and highlight the value of using deep learning, as an all-in-one model of the visual cortex, to understand and decode natural vision.

Keywords

Cite

@article{arxiv.1608.03425,
  title  = {Neural Encoding and Decoding with Deep Learning for Dynamic Natural Vision},
  author = {Haiguang Wen and Junxing Shi and Yizhen Zhang and Kun-Han Lu and Jiayue Cao and Zhongming Liu},
  journal= {arXiv preprint arXiv:1608.03425},
  year   = {2017}
}

Comments

27 pages, 10 figures, 1 table

R2 v1 2026-06-22T15:17:32.035Z