A brain-inspired framework integrating Entorhinal-Hippocampal-Prefrontal circuits for adaptive navigation in mobile robots

Yishen Liao; Chenghua Wang; Naigong Yu; Hejie Yu; Kun Xiao; Yishen Liao; Chenghua Wang; Naigong Yu; Hejie Yu; Kun Xiao

doi:10.3934/era.2026071

Electronic Research Archive

2026, Volume 34, Issue 3: 1559-1584. doi: 10.3934/era.2026071

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A brain-inspired framework integrating Entorhinal-Hippocampal-Prefrontal circuits for adaptive navigation in mobile robots

1.
Modern Industry School of Virtual Reality, Jiangxi University of Finance and Economics, Nanchang 330013, China
2.
School of Information Science and Technology, Beijing University of Technology, Beijing 100124, China
3.
Department of Precision Instrument, Tsinghua University, Beijing 100084, China

Received: 05 January 2026 Revised: 04 February 2026 Accepted: 12 February 2026 Published: 13 February 2026

Autonomous navigation in complex, dynamic, and unstructured environments poses a major challenge for mobile robots due to limitations in traditional methods. Inspired by rodent entorhinal-hippocampal-prefrontal circuits, we proposed a brain-inspired navigation framework that leverages specialized spatial cells. The framework integrates entorhinal-hippocampal path integration from self-motion cues with prefrontal action selection via Sn-Plast modulated spiking neural networks (SNNs) to form initial goal-directed habits. Upon reaching the goal, CA1 place cells self-organize to optimize navigation routes, generating supervisory firing rate sequences that consolidate refined routes in the SNNs via feedback, enabling stable habits and rapid reshaping under task changes. Additionally, a chaining strategy decomposes complex long-distance tasks into sequential subtasks, enabling independent local habit formation and seamless integration into globally efficient routes. 3D robot simulation experiments showed superior performance over baseline algorithms in convergence speed and route efficiency. Moreover, the method exhibits rapid habit reshaping under dynamic task changes, reducing exploration episodes by 52.3%–62.2% and shortening route length by 5.6%–7.7% in multi-compartment environments via a hierarchical chaining strategy. Moreover, the framework can operate in real time at approximately 12 Hz, demonstrating its feasibility for robotic applications.
- brain-inspired navigation,
- spiking neural networks,
- Entorhinal-Hippocampal-Prefrontal,
- mobile robots,
- spatial cells
Citation: Yishen Liao, Chenghua Wang, Naigong Yu, Hejie Yu, Kun Xiao. A brain-inspired framework integrating Entorhinal-Hippocampal-Prefrontal circuits for adaptive navigation in mobile robots[J]. Electronic Research Archive, 2026, 34(3): 1559-1584. doi: 10.3934/era.2026071

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Abstract

Autonomous navigation in complex, dynamic, and unstructured environments poses a major challenge for mobile robots due to limitations in traditional methods. Inspired by rodent entorhinal-hippocampal-prefrontal circuits, we proposed a brain-inspired navigation framework that leverages specialized spatial cells. The framework integrates entorhinal-hippocampal path integration from self-motion cues with prefrontal action selection via Sn-Plast modulated spiking neural networks (SNNs) to form initial goal-directed habits. Upon reaching the goal, CA1 place cells self-organize to optimize navigation routes, generating supervisory firing rate sequences that consolidate refined routes in the SNNs via feedback, enabling stable habits and rapid reshaping under task changes. Additionally, a chaining strategy decomposes complex long-distance tasks into sequential subtasks, enabling independent local habit formation and seamless integration into globally efficient routes. 3D robot simulation experiments showed superior performance over baseline algorithms in convergence speed and route efficiency. Moreover, the method exhibits rapid habit reshaping under dynamic task changes, reducing exploration episodes by 52.3%–62.2% and shortening route length by 5.6%–7.7% in multi-compartment environments via a hierarchical chaining strategy. Moreover, the framework can operate in real time at approximately 12 Hz, demonstrating its feasibility for robotic applications.

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