Saved in:
Bibliographic Details
Main Authors: Gao, Xiaohui, Cheng, Yue, Li, Peiyang, Niu, Yijie, Ren, Yifan, Liu, Yiheng, Sun, Haiyang, Li, Zhuoyi, Xing, Weiwei, Hu, Xintao
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.20053
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866913564771483648
author Gao, Xiaohui
Cheng, Yue
Li, Peiyang
Niu, Yijie
Ren, Yifan
Liu, Yiheng
Sun, Haiyang
Li, Zhuoyi
Xing, Weiwei
Hu, Xintao
author_facet Gao, Xiaohui
Cheng, Yue
Li, Peiyang
Niu, Yijie
Ren, Yifan
Liu, Yiheng
Sun, Haiyang
Li, Zhuoyi
Xing, Weiwei
Hu, Xintao
contents Neural encoding of artificial neural networks (ANNs) links their computational representations to brain responses, offering insights into how the brain processes information. Current studies mostly use linear encoding models for clarity, even though brain responses are often nonlinear. This has sparked interest in developing nonlinear encoding models that are still interpretable. To address this problem, we propose LinBridge, a learnable and flexible framework based on Jacobian analysis for interpreting nonlinear encoding models. LinBridge posits that the nonlinear mapping between ANN representations and neural responses can be factorized into a linear inherent component that approximates the complex nonlinear relationship, and a mapping bias that captures sample-selective nonlinearity. The Jacobian matrix, which reflects output change rates relative to input, enables the analysis of sample-selective mapping in nonlinear models. LinBridge employs a self-supervised learning strategy to extract both the linear inherent component and nonlinear mapping biases from the Jacobian matrices of the test set, allowing it to adapt effectively to various nonlinear encoding models. We validate the LinBridge framework in the scenario of neural visual encoding, using computational visual representations from CLIP-ViT to predict brain activity recorded via functional magnetic resonance imaging (fMRI). Our experimental results demonstrate that: 1) the linear inherent component extracted by LinBridge accurately reflects the complex mappings of nonlinear neural encoding models; 2) the sample-selective mapping bias elucidates the variability of nonlinearity across different levels of the visual processing hierarchy. This study presents a novel tool for interpreting nonlinear neural encoding models and offers fresh evidence about hierarchical nonlinearity distribution in the visual cortex.
format Preprint
id arxiv_https___arxiv_org_abs_2410_20053
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle LinBridge: A Learnable Framework for Interpreting Nonlinear Neural Encoding Models
Gao, Xiaohui
Cheng, Yue
Li, Peiyang
Niu, Yijie
Ren, Yifan
Liu, Yiheng
Sun, Haiyang
Li, Zhuoyi
Xing, Weiwei
Hu, Xintao
Neurons and Cognition
Computation and Language
Neural encoding of artificial neural networks (ANNs) links their computational representations to brain responses, offering insights into how the brain processes information. Current studies mostly use linear encoding models for clarity, even though brain responses are often nonlinear. This has sparked interest in developing nonlinear encoding models that are still interpretable. To address this problem, we propose LinBridge, a learnable and flexible framework based on Jacobian analysis for interpreting nonlinear encoding models. LinBridge posits that the nonlinear mapping between ANN representations and neural responses can be factorized into a linear inherent component that approximates the complex nonlinear relationship, and a mapping bias that captures sample-selective nonlinearity. The Jacobian matrix, which reflects output change rates relative to input, enables the analysis of sample-selective mapping in nonlinear models. LinBridge employs a self-supervised learning strategy to extract both the linear inherent component and nonlinear mapping biases from the Jacobian matrices of the test set, allowing it to adapt effectively to various nonlinear encoding models. We validate the LinBridge framework in the scenario of neural visual encoding, using computational visual representations from CLIP-ViT to predict brain activity recorded via functional magnetic resonance imaging (fMRI). Our experimental results demonstrate that: 1) the linear inherent component extracted by LinBridge accurately reflects the complex mappings of nonlinear neural encoding models; 2) the sample-selective mapping bias elucidates the variability of nonlinearity across different levels of the visual processing hierarchy. This study presents a novel tool for interpreting nonlinear neural encoding models and offers fresh evidence about hierarchical nonlinearity distribution in the visual cortex.
title LinBridge: A Learnable Framework for Interpreting Nonlinear Neural Encoding Models
topic Neurons and Cognition
Computation and Language
url https://arxiv.org/abs/2410.20053