Inverse Depth to Depth Conversion for Monocular SLAM

Inverse Depth to Depth Conversion for Monocular SLAM

Recently it has been shown that an inverse depth parametrization can improve the performance of real-time monocular EKF SLAM, permitting undelayed initialization of features at all depths. However, the inverse depth parametrization requires the storage of 6 parameters in the state vector for each ma...

Full description

Saved in:
Bibliographic Details
Published in:Proceedings 2007 IEEE International Conference on Robotics and Automation pp. 2778 - 2783
Main Authors: Civera, J., Davison, A.J., Montiel, J.M.M.
Format: Conference Proceeding
Language:English
Published: IEEE 01-04-2007
Subjects:
Analytical models
Computational complexity
Computational efficiency
Computational modeling
Encoding
Equations
Linearity
Measurement standards
Real time systems
Simultaneous localization and mapping
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recently it has been shown that an inverse depth parametrization can improve the performance of real-time monocular EKF SLAM, permitting undelayed initialization of features at all depths. However, the inverse depth parametrization requires the storage of 6 parameters in the state vector for each map point. This implies a noticeable computing overhead when compared with the standard 3 parameter XYZ Euclidean encoding of a 3D point, since the computational complexity of the EKF scales poorly with state vector size. In this work we propose to restrict the inverse depth parametrization only to cases where the standard Euclidean encoding implies a departure from linearity in the measurement equations. Every new map feature is still initialized using the 6 parameter inverse depth method. However, as the estimation evolves, if according to a linearity index the alternative XYZ coding can be considered linear, we show that feature parametrization can be transformed from inverse depth to XYZ for increased computational efficiency with little reduction in accuracy. We present a theoretical development of the necessary linearity indices, along with simulations to analyze the influence of the conversion threshold. Experiments performed with with a 30 frames per second real-time system are reported. An analysis of the increase in the map size that can be successfully managed is included.
ISBN:1424406013
9781424406012
ISSN:1050-4729
2577-087X
DOI:10.1109/ROBOT.2007.363892