Title :
A fuzzy logic solution for navigation of an autonomous subsurface planetary exploration robot
Author :
Gauss, V.A. ; Bay, J.S.
Author_Institution :
Comput. Motion Inc., Goleta, CA, USA
Abstract :
An unsupervised fuzzy logic navigation algorithm is designed and simulated for a subsurface planetary exploration robot. The robot is intended for the subsurface exploration of Mars, and will be equipped with acoustic sensing for detecting obstacles. Measurements of obstacle distance and direction are anticipated to be imprecise however, because the performance of acoustic sensors is degraded in underground environments. We present an unsupervised fuzzy logic algorithm that can determine a trajectory for a subsurface planetary exploration robot through unknown environments, even in the presence of imprecise sensor data. This algorithm uses a combination of simple fusion of robot behaviors and self-tuning membership functions to determine robot navigation without resorting to the degree of complexity of previous fuzzy logic algorithms
Keywords :
fuzzy control; fuzzy logic; fuzzy set theory; intelligent control; mobile robots; path planning; planetary rovers; unsupervised learning; acoustic sensors; autonomous subsurface planetary exploration robot; direction measurement; fuzzy logic solution; navigation; obstacle distance measurement; self-tuning membership functions; underground environments; unsupervised fuzzy logic navigation algorithm; Acoustic measurements; Acoustic sensors; Acoustic signal detection; Algorithm design and analysis; Degradation; Extraterrestrial measurements; Fuzzy logic; Mars; Navigation; Robot sensing systems;
Conference_Titel :
Intelligent Control (ISIC), 1998. Held jointly with IEEE International Symposium on Computational Intelligence in Robotics and Automation (CIRA), Intelligent Systems and Semiotics (ISAS), Proceedings
Conference_Location :
Gaithersburg, MD
Print_ISBN :
0-7803-4423-5
DOI :
10.1109/ISIC.1998.713724
