Bayesian Integration of Multi-resolutional Grid Codes for Spatial Cognition

TL;DR

This paper presents a Bayesian model integrating multi-resolution grid codes to explain spatial cognition, providing theoretical insights and practical validation for neural and robotic spatial mapping.

Contribution

It introduces a Bayesian framework for grid cell integration, explaining experimental observations and demonstrating robust SLAM capabilities in large environments.

Findings

Model explains expansion of place fields due to MEC inactivation

Validates Fourier hypothesis through robotic experiments

Achieves robust large-scale SLAM performance

Abstract

Fourier-like summation of several grid cell modules with different spatial frequencies in the medial entorhinal cortex (MEC) has long been proposed to form the contours of place firing fields. Recent experiments largely, but not completely, support this theory. Place fields are obviously expanded by inactivation of dorsal MEC, which fits the hypothesis. However, contrary to the prediction, inactivation of ventral MEC is also weakly broaden the spatial place firing patterns. In this study, we derive the model from grid spatial frequencies represented by Gaussian profiles to a 1D place field by Bayesian inference, and further provide completely theoretical explanations for expansion of place fields and predictions for alignments of grid components. To understand the information transform across between neocortex, entorhinal cortex, and hippocampus, we propose spatial memory indexing theory from hippocampal indexing theory to investigate how neural dynamics work in the entorhinal-hippocampal circuit. The inputs of place cells in CA3 are converged from three grid modules with different grid spacings layer II of MEC by Bayesian mechanism. We resort to the robot system to test Fourier hypothesis and spatial memory indexing theory, and validate our proposed entorhinal-hippocampal model. And then we demonstrate its cognitive mapping capability on the KITTI odometry benchmark dataset. Results suggest that our model provides a rational theoretical explanation for the biological experimental results. Results also show that the proposed model is robust for simultaneous localization and mapping (SLAM) in the large-scale environment. Our proposed model theoretically supports for Fourier hypothesis in a general Bayesian mechanism, which may pertain to other neural systems in addition to spatial cognition.