Distributed pheromone-based swarming control of unmanned air and ground vehicles for RSTA

John A. Sauter; Robert S. Mathews; Andrew Yinger; Joshua S. Robinson; John Moody; Stephanie Riddle

doi:10.1117/12.782271

16 April 2008 Distributed pheromone-based swarming control of unmanned air and ground vehicles for RSTA

John A. Sauter, Robert S. Mathews, Andrew Yinger, Joshua S. Robinson, John Moody, Stephanie Riddle

Proceedings Volume 6962, Unmanned Systems Technology X; 69620C (2008) https://doi.org/10.1117/12.782271
Event: SPIE Defense and Security Symposium, 2008, Orlando, Florida, United States

Abstract

The use of unmanned vehicles in Reconnaissance, Surveillance, and Target Acquisition (RSTA) applications has received considerable attention recently. Cooperating land and air vehicles can support multiple sensor modalities providing pervasive and ubiquitous broad area sensor coverage. However coordination of multiple air and land vehicles serving different mission objectives in a dynamic and complex environment is a challenging problem. Swarm intelligence algorithms, inspired by the mechanisms used in natural systems to coordinate the activities of many entities provide a promising alternative to traditional command and control approaches. This paper describes recent advances in a fully distributed digital pheromone algorithm that has demonstrated its effectiveness in managing the complexity of swarming unmanned systems. The results of a recent demonstration at NASA's Wallops Island of multiple Aerosonde Unmanned Air Vehicles (UAVs) and Pioneer Unmanned Ground Vehicles (UGVs) cooperating in a coordinated RSTA application are discussed. The vehicles were autonomously controlled by the onboard digital pheromone responding to the needs of the automatic target recognition algorithms. UAVs and UGVs controlled by the same pheromone algorithm self-organized to perform total area surveillance, automatic target detection, sensor cueing, and automatic target recognition with no central processing or control and minimal operator input. Complete autonomy adds several safety and fault tolerance requirements which were integrated into the basic pheromone framework. The adaptive algorithms demonstrated the ability to handle some unplanned hardware failures during the demonstration without any human intervention. The paper describes lessons learned and the next steps for this promising technology.

Citation Download Citation

John A. Sauter, Robert S. Mathews, Andrew Yinger, Joshua S. Robinson, John Moody, and Stephanie Riddle "Distributed pheromone-based swarming control of unmanned air and ground vehicles for RSTA", Proc. SPIE 6962, Unmanned Systems Technology X, 69620C (16 April 2008); https://doi.org/10.1117/12.782271

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