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Air Vehicle Optimal Trajectories for Minimization of Radar Exposure
Contributor(s): Penny Hill Press (Editor), Air Force Institute of Technology (Author)
ISBN: 1530738938     ISBN-13: 9781530738939
Publisher: Createspace Independent Publishing Platform
OUR PRICE:   $12.30  
Product Type: Paperback - Other Formats
Published: March 2016
Qty:
Additional Information
BISAC Categories:
- Technology & Engineering | Military Science
Physical Information: 0.22" H x 8.5" W x 11.02" (0.58 lbs) 106 pages
 
Descriptions, Reviews, Etc.
Publisher Description:
This book addresses the problem of formulating and analyzing the single vehicle path planning problem for radar exposure minimization. A single vehicle with given initial and final positions is exposed to a threat radar and optimal paths are sought. The calculus of variations and optimal control are applied to formulate optimal trajectories and numerical optimization algorithms are utilized to solve for the optimal paths. A sensitivity study of the objective cost is performed for flight against one radar utilizing two different geometries and several numerical approaches. A second threat radar is then included in the formulation and the optimal trajectory for flight between the radars is found for several symmetric threat radar geometries. The objective cost of the optimal paths are compared with the direct path (a straight line) as well as trajectories generated using the graphical Voronoi path planning approach. Finally, each radar is given a different weight, simulating differing transmission powers, and optimal paths are sought for the same radar configurations. The objective costs of these trajectories are again compared to the direct path and the weighted Voronoi path.Results indicate low sensitivity of the objective cost to suboptimal paths for flight against one threat radar; however, the numerical method applied to find the solution results in widely varying optimal trajectories. The nonlinear differential equations governing the optimal trajectory against multiple radars constitute a difficult, numerically sensitive two point boundary value problem. Results indicate that approaching the Voronoi-generated curves in an optimal way from the endpoints may provide for feasible on-line and real-time utilization.