Vision-Aided Inertial Navigation for Precise Planetary Landing: Analysis and Experiments

In this paper, we present the analysis and experimental validation of a vision-aided inertial navigation algorithm for planetary landing applications. The system employs tight integration of inertial and visual feature measurements to compute accurate estimates of the lander’s terrain-relative position, attitude, and velocity in real time. Two types of features are considered: mapped landmarks, i.e., features whose global 3D positions can be determined from a surface map, and opportunistic features, i.e., features that can be tracked in consecutive images, but whose 3D positions are not known. Both types of features are processed in an extended Kalman filter (EKF) estimator and are optimally fused with measurements from an inertial measurement unit (IMU). Results from a sounding rocket test, covering the dynamic profile of typical planetary landing scenarios, show estimation errors of magnitude 0.16 m/s in velocity and 6.4 m in position at touchdown. These results vastly improve current state of the art for non-vision based EDL navigation, and meet the requirements of future planetary exploration missions. Download: Bibtex: @INPROCEEDINGS{ Mourikis-RSS-07, AUTHOR = {A. Mourikis and N. Trawny and S. Roumeliotis and A. Johnson and L. Matthies}, TITLE = {Vision-Aided Inertial Navigation for Precise Planetary Landing: Analysis and Experiments}, BOOKTITLE = {Proceedings of Robotics: Science and Systems}, YEAR = {2007}, ADDRESS = {Atlanta, GA, USA}, MONTH = {June}, DOI = {10.15607/RSS.2007.III.019} }