Abstract
This paper provides algorithms to fuse relative and absolute microelectromechanical systems (MEMS) navigation sensors, suitable for micro planetary rovers, to provide a more accurate estimation of navigation information, specifically, attitude and position. Planetary rovers have extremely slow speed (~1 cm/s) and lack conventional navigation sensors/systems, hence the general methods of terrestrial navigation may not be applicable to these applications. While relative attitude and position can be tracked in a way similar to those for ground robots, absolute navigation information is hard to achieve on a remote celestial body, like Moon or Mars, in contrast to terrestrial applications. In this study, two absolute attitude estimation algorithms were developed and compared for accuracy and robustness. The estimated absolute attitude was fused with the relative attitude sensors in a framework of nonlinear filters. The nonlinear Extended Kalman filter (EKF) and Unscented Kalman filter (UKF) were compared in pursuit of better accuracy and reliability in this nonlinear estimation problem, using only on-board low cost MEMS sensors. Experimental results confirmed the viability of the proposed algorithms and the sensor suite, for low cost and low weight micro planetary rovers. It is demonstrated that integrating the relative and absolute navigation MEMS sensors reduces the navigation errors to the desired level.
Highlights
IntroductionPlanetary rovers are wheeled robots characterized by extremely slow speed and rotation
Planetary rovers are wheeled robots characterized by extremely slow speed and rotation.They typically move in a stop-and-go fashion so that they can scan their surroundings to find a drivable path, and discover scientific targets in the exploration area
Navigation would appear to be easy for planetary rovers due to their slow dynamics, but the sensors that are available for terrestrial robot navigation are not always available onboard the planetary rovers
Summary
Planetary rovers are wheeled robots characterized by extremely slow speed and rotation. They typically move in a stop-and-go fashion so that they can scan their surroundings to find a drivable path, and discover scientific targets in the exploration area. Rovers have an average speed of 1 cm/s when moving on hard and flat surfaces and even less in normal motion [1]. Typical motion scenarios of planetary rovers include straight drives, arc turns and turn-in-place maneuvers, etc. To explore an unknown environment, the rover must know two things: “where am I?” and at the same time, “where am I heading to?” The answers to these questions are essential to allow the manned/unmanned robot to perform reliably and not become lost in a given environment. Navigation would appear to be easy for planetary rovers due to their slow dynamics, but the sensors that are available for terrestrial robot navigation are not always available onboard the planetary rovers
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