TY - GEN
T1 - Mitigation of odometry drift with a single ranging link in GNSS-limited environments
AU - Lee, Young Hee
AU - Zhu, Chen
AU - Giorgi, Gabriele
AU - Günther, Christoph
N1 - Publisher Copyright:
© 2020 ION 2020 International Technical Meeting Proceedings. All rights reserved.
PY - 2020
Y1 - 2020
N2 - Vision-based systems can estimate the vehicle's positions and attitude with a low cost and simple implementation, but the performance is very sensitive to environmental conditions. Moreover, estimation errors are accumulated without a bound since visual odometry is a dead-reckoning process. To improve the robustness to environmental conditions, vision-based systems can be augmented with inertial sensors, and the loop closing technique can be applied to reduce the drift. However, only with on-board sensors, vehicle's poses can only be estimated in a local navigation frame, which is randomly defined for each mission. To obtain globally-referred poses, absolute position estimates obtained with GNSS can be fused with on-board measurements (obtained with either vision-only or visual-inertial odometry). However, in many cases (e.g. urban canyons, indoor environments), GNSS-based positioning is unreliable or entirely unavailable due to signal interruptions and blocking, while we can still obtain ranging links from various sources, such as signals of opportunity or low cost radio-based ranging modules. We propose a graph-based data fusion method of the on-board odometry data and ranging measurements to mitigate pose drifts in environments where GNSS-based positioning is unavailable. The proposed algorithm is evaluated both with synthetic and real data.
AB - Vision-based systems can estimate the vehicle's positions and attitude with a low cost and simple implementation, but the performance is very sensitive to environmental conditions. Moreover, estimation errors are accumulated without a bound since visual odometry is a dead-reckoning process. To improve the robustness to environmental conditions, vision-based systems can be augmented with inertial sensors, and the loop closing technique can be applied to reduce the drift. However, only with on-board sensors, vehicle's poses can only be estimated in a local navigation frame, which is randomly defined for each mission. To obtain globally-referred poses, absolute position estimates obtained with GNSS can be fused with on-board measurements (obtained with either vision-only or visual-inertial odometry). However, in many cases (e.g. urban canyons, indoor environments), GNSS-based positioning is unreliable or entirely unavailable due to signal interruptions and blocking, while we can still obtain ranging links from various sources, such as signals of opportunity or low cost radio-based ranging modules. We propose a graph-based data fusion method of the on-board odometry data and ranging measurements to mitigate pose drifts in environments where GNSS-based positioning is unavailable. The proposed algorithm is evaluated both with synthetic and real data.
UR - http://www.scopus.com/inward/record.url?scp=85082496638&partnerID=8YFLogxK
U2 - 10.33012/2020.17213
DO - 10.33012/2020.17213
M3 - Conference contribution
AN - SCOPUS:85082496638
T3 - ION 2020 International Technical Meeting Proceedings
SP - 1117
EP - 1126
BT - ION 2020 International Technical Meeting Proceedings
PB - Institute of Navigation
T2 - Institute of Navigation International Technical Meeting 2020, ITM 2020
Y2 - 21 January 2020 through 24 January 2020
ER -