Solving the moving obstacle path planning problem using embedded variational methods

An analytically derived algorithm to solve a simple two-dimensional robot planning problem subject to moving obstacle constraints is presented. Normally a variational formulation is intractable since an obstacle-cluttered environment will present multiple trajectories that are locally optimal soluti...

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Bibliographic Details
Published inRobotics and Automation, '91 International Conference On pp. 450 - 455 vol.1
Main Authors Tominaga, H., Bavarian, B.
Format Conference Proceeding
LanguageEnglish
Published IEEE Comput. Soc. Press 1991
Subjects
Algorithm design and analysis
Calculus
Cost function
History
Iterative algorithms
Manipulator dynamics
Optimal control
Optimization methods
Path planning
Robots
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ISBN081862163X
9780818621635
DOI10.1109/ROBOT.1991.131619

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Summary:An analytically derived algorithm to solve a simple two-dimensional robot planning problem subject to moving obstacle constraints is presented. Normally a variational formulation is intractable since an obstacle-cluttered environment will present multiple trajectories that are locally optimal solutions. To derive an algorithm which produces a unique solution, an embedding method commonly found in homotopic methods is used. A fictitious third dimension is added to the two-dimensional formulation; local (but nonglobal solutions) in the original problem become saddle-point trajectories in the embedded formulation, allowing for convergence of a numerical algorithm to continue along a descent direction. The computational algorithm becomes globally convergent, i.e., convergence to the global solution is achieved regardless of the choice of initial trajectory used to start the algorithm. Simulation results demonstrate the effectiveness of the algorithm.< >
ISBN:081862163X
9780818621635
DOI:10.1109/ROBOT.1991.131619