Planificación de trayectoria determinista basado en recompensas para entornos discretos 3D

Gloria Isabel Vanegas Zabala; Andrea Liger Yépez

doi:10.37135/ns.01.12.10

Autores/as

Gloria Isabel Vanegas Zabala Instituto Superior Tecnológico Bolivar https://orcid.org/0000-0003-0490-996X
Andrea Liger Yépez Instituto Superior Tecnológico Bolívar https://orcid.org/0009-0008-9714-1315

DOI:

https://doi.org/10.37135/ns.01.12.10

Palabras clave:

Planificación de trayectoria 3D, trayectoria óptima, UAV

Resumen

Diversas ramas de estudio e investigación surgen de la tecnología de los vehículos aéreos no tripulados (UAV). Una tarea relevante en vuelo UAV se centra en la planificación de trayectorias tri-dimensional (3D), tarea que implica un alto costo computacional, en consecuencia, debe ser resuelta mejorando el tiempo de respuesta. El objetivo de este trabajo es optimizar el tiempo de cálculo y determinar una trayectoria completa de vuelo 3D. En este sentido, se considera un entorno de vuelo 3D como una malla discreta adaptativa 3D, la cual se somete a un refinamiento mínimo en busca de espacios libres de colisiones. Con la construcción de la malla discreta 3D, se aplica una metodología de coste-respuesta a modo de un Autómata Finito Determinista Discreto (DDFA), metodología que da como resultado un conjunto de respuestas óptimas parciales (calculadas recursivamente) que indican los espacios libres de colisión en la trayectoria 3D final para el vuelo del UAV. Como resultado, el algoritmo de planificación de trayectorias 3D ha mostrado un ahorro en tiempo computacional y recursos de memoria en comparación con las técnicas clásicas.

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Planificación de trayectoria determinista basado en recompensas para entornos discretos 3D

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