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Apr 27, 2024;24 (9):

Cognitive Control Architecture for the Practical Realization of UAV Collision Avoidance.

Qirui Zhang, Ruixuan Wei, Songlin Huang
Author Information
  1. Qirui Zhang: Aviation Engineering School, Air Force Engineering University, Xi'an 710038, China. ORCID
  2. Ruixuan Wei: Aviation Engineering School, Air Force Engineering University, Xi'an 710038, China.
  3. Songlin Huang: Unit 93535 of PLA, Rikaze 857060, China.
PMID: 38732897 DOI: 10.3390/s24092790

Abstract

A highly intelligent system often draws lessons from the unique abilities of humans. Current humanlike models, however, mainly focus on biological behavior, and the brain functions of humans are often overlooked. By drawing inspiration from brain science, this article shows how aspects of brain processing such as sensing, preprocessing, cognition, obstacle learning, behavior, strategy learning, pre-action, and action can be melded together in a coherent manner with cognitive control architecture. This work is based on the notion that the anti-collision response is activated in sequence, which starts from obstacle sensing to action. In the process of collision avoidance, cognition and learning modules continuously control the UAV's repertoire. Furthermore, simulated and experimental results show that the proposed architecture is effective and feasible.

Keywords

anti-collision cognitive control architecture conditioned reflex unmanned aerial vehicles

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Grants

  1. 2018AAA0102400/The New Generation Artificial Intelligence Project of The Ministry of Science and Technology of China
Journal Article

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