Litcius/Paper detail

Accurate and Robust Scale Recovery for Monocular Visual Odometry Based on Plane Geometry

Rui Tian, Yunzhou Zhang, Delong Zhu, Shiwen Liang, Sonya Coleman, Dermot Kerr

202135 citationsDOI

Abstract

Scale ambiguity is a fundamental problem in monocular visual odometry. Typical solutions include loop closure detection and environment information mining. For applications like self-driving cars, loop closure is not always available, hence mining prior knowledge from the environment becomes a more promising approach. In this paper, with the assumption of a constant height of the camera above the ground, we develop a light-weight scale recovery framework leveraging an accurate and robust estimation of the ground plane. The framework includes a ground point extraction algorithm for selecting high-quality points on the ground plane, and a ground point aggregation algorithm for joining the extracted ground points in a local sliding window. Based on the aggregated data, the scale is finally recovered by solving a least-squares problem using a RANSAC-based optimizer. Sufficient data and robust optimizer enable a highly accurate scale recovery. Experiments on the KITTI dataset show that the proposed framework can achieve state-of-the-art accuracy in terms of translation errors, while maintaining competitive performance on the rotation error. Due to the light-weight design, our framework also demonstrates a high frequency of 20 Hz on the dataset.

Topics & Concepts

RANSACVisual odometryComputer scienceOdometryArtificial intelligenceComputer visionGround planePoint cloudRotation (mathematics)MonocularScale (ratio)AlgorithmRobotMobile robotImage (mathematics)Antenna (radio)Quantum mechanicsPhysicsTelecommunicationsRobotics and Sensor-Based LocalizationAdvanced Vision and ImagingImage and Object Detection Techniques