Abstract
In this paper, we present a novel approach for stereo visual odometry with robust motion estimation that is faster and more accurate than standard RANSAC (Random Sample Consensus). Our method makes improvements in RANSAC in three aspects: first, the hypotheses are preferentially generated by sampling the input feature points on the order of ages and similarities of the features; second, the evaluation of hypotheses is performed based on the SPRT (Sequential Probability Ratio Test) that makes bad hypotheses discarded very fast without verifying all the data points; third, we aggregate the three best hypotheses to get the final estimation instead of only selecting the best hypothesis. The first two aspects improve the speed of RANSAC by generating good hypotheses and discarding bad hypotheses in advance, respectively. The last aspect improves the accuracy of motion estimation. Our method was evaluated in the KITTI (Karlsruhe Institute of Technology and Toyota Technological Institute) and the New Tsukuba dataset. Experimental results show that the proposed method achieves better results for both speed and accuracy than RANSAC.
Highlights
IntroductionMobile robot localization is a fundamental challenge for autonomous mobile robots navigation
Mobile robot localization is a fundamental challenge for autonomous mobile robots navigation.A robot needs to know its position to accomplish autonomous navigation
We show the results of our approach for robust stereo visual odometry
Summary
Mobile robot localization is a fundamental challenge for autonomous mobile robots navigation. A robot needs to know its position to accomplish autonomous navigation. Different sensors and techniques have been used to achieve robot localization, such as global navigation satellite system (GNSS), inertial navigation system (INS), and vision-based localization. Each method has its advantages and disadvantages. GNSS is a very common method for localization by reason of its absolute position without error accumulation, but its accuracy is highly affected by buildings, trees and weather situations, and it’s even not available for indoor situations. INS is fast but has highly accumulated drift, and a highly precise INS is expensive for mobile robots as commercial purposes
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