Human autonomy teaming-based safety-aware navigation through bio-inspired and graph-based algorithms

Human autonomy teaming-based safety-aware navigation through bio-inspired and graph-based algorithms

In the field of autonomous robots, achieving complete precision is challenging, underscoring the need for human intervention, particularly in ensuring safety. Human Autonomy Teaming (HAT) is crucial for promoting safe and efficient human–robot collaboration in dynamic indoor environments. This paper...

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Bibliographic Details
Main Authors: Timothy Sellers, Tingjun Lei, Chaomin Luo, Zhuming Bi, Gene Eu Jan
Format: Article
Language:English
Published: Elsevier 2024-12-01
Series:Biomimetic Intelligence and Robotics
Subjects:
Human autonomy teaming (HAT)
Robot path planning
Generalized Voronoi diagram (GVD)
Spatio-temporal graphs
Bio-inspired algorithms
Online Access:http://www.sciencedirect.com/science/article/pii/S2667379724000470
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Summary:In the field of autonomous robots, achieving complete precision is challenging, underscoring the need for human intervention, particularly in ensuring safety. Human Autonomy Teaming (HAT) is crucial for promoting safe and efficient human–robot collaboration in dynamic indoor environments. This paper introduces a framework designed to address these precision gaps, enhancing safety and robotic interactions within such settings. Central to our approach is a hybrid graph system that integrates the Generalized Voronoi Diagram (GVD) with spatio-temporal graphs, effectively combining human feedback, environmental factors, and key waypoints. An integral component of this system is the improved Node Selection Algorithm (iNSA), which utilizes the revised Grey Wolf Optimization (rGWO) for better adaptability and performance. Furthermore, an obstacle tracking model is employed to provide predictive data, enhancing the efficiency of the system. Human insights play a critical role, from supplying initial environmental data and determining key waypoints to intervening during unexpected challenges or dynamic environmental changes. Extensive simulation and comparison tests confirm the reliability and effectiveness of our proposed model, highlighting its unique advantages in the domain of HAT. This comprehensive approach ensures that the system remains robust and responsive to the complexities of real-world applications.
ISSN:2667-3797

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