Title :
Extended kalman filter for improved navigation with fault awareness
Author :
Oonk, Stephen ; Maldonado, Francisco J. ; Zongke Li ; Reichard, Karl ; Pentzer, Jesse
Author_Institution :
American GNC Corp., Simi Valley, CA, USA
Abstract :
Most unmanned mobile robotic platforms contain multiple sensors that can be leveraged to measure vehicle motion states, where there often exists redundancies among the different sensor types. Kalman filter based sensor fusion between inertial navigation sensors, GPS readings, encoders, etc. is a very popular approach in the literature to improve the accuracy of navigation readings. However, such redundancies can also be exploited for simultaneously conducting fault detection and identification of the sensors and the robot. This paper presents theory and results for an Extended Kalman Filter (EKF) approach fusing IMU/INS readings with GPS and/or visual odometry (VO) data to diagnose faults in wheel odometry readings (encoders). A key advantage is that the approach works for detecting faults, even when relatively low grade and inexpensive sensors are installed in the vehicle.
Keywords :
Global Positioning System; Kalman filters; distance measurement; fault diagnosis; mobile robots; motion control; nonlinear filters; path planning; remotely operated vehicles; sensor fusion; EKF approach; GPS; IMU/INS readings; VO data; encoders; extended Kalman filter; fault awareness; fault detection; fault identification; multiple sensors; navigation; sensor types; unmanned mobile robotic platforms; vehicle motion states; visual odometry; wheel odometry readings; Global Positioning System; Kalman filters; Mathematical model; Robots; Sensors; Vehicles; Kalman filtering; fault detection; health monitoring; inertial measurements; mobile robots; navigation; sensor fusion;
Conference_Titel :
Systems, Man and Cybernetics (SMC), 2014 IEEE International Conference on
Conference_Location :
San Diego, CA
DOI :
10.1109/SMC.2014.6974332
