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A constraint-based approach for planning unmanned aerial vehicle activities

Published online by Cambridge University Press:  22 February 2017

Christophe Guettier  and
François Lucas
Christophe Guettier
Affiliation:
SAFRAN Electronics and Defense, 100 Avenue de Paris, 91344 Massy, France e-mail: christophe.guettier@safrangroup.com
François Lucas
Affiliation:
EPEX SPOT, 5 Boulevard Montmartre, 75002 Paris, France e-mail: f.lucas@epexspot.com
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Abstract

Unmanned Aerial Vehicles (UAV) represent a major advantage in defense, disaster relief and first responder applications. UAV may provide valuable information on the environment if their Command and Control (C2) is shared by different operators. In a C2 networking system, any operator may request and use the UAV to perform a remote sensing operation. These requests have to be scheduled in time and a consistent navigation plan must be defined for the UAV. Moreover, maximizing UAV utilization is a key challenge for user acceptance and operational efficiency. The global planning problem is constrained by the environment, targets to observe, user availability, mission duration and on-board resources. This problem follows previous research works on automatic mission Planning & Scheduling for defense applications. The paper presents a full constraint-based approach to simultaneously satisfy observation requests, and resolve navigation plans.

Type
Articles
Information
The Knowledge Engineering Review , Volume 31 , Special Issue 5: Constraint Satisfaction for Planning and Scheduling , November 2016 , pp. 486 - 497
Copyright
© Cambridge University Press, 2017 

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