Relative Pose Estimation and Accuracy Verification of Spherical Panoramic Image

doi:10.11947/j.AGCS.2017.20160645

Abstract

Abstract:

This paper improves the method of the traditional 5-point relative pose estimation algorithm, and proposes a relative pose estimation algorithm which is suitable for spherical panoramic images. The algorithm firstly computes the essential matrix, then decomposes the essential matrix to obtain the rotation matrix and the translation vector using SVD, and finally the reconstructed three-dimensional points are used to eliminate the error solution. The innovation of the algorithm lies the derivation of panorama epipolar formula and the use of the spherical distance from the point to the epipolar plane as the error term for the spherical panorama co-planarity function. The simulation experiment shows that when the random noise of the image feature points is within the range of pixel, the error of the three Euler angles is about 0.1°, and the error between the relative translational displacement and the simulated value is about 1.5°. The result of the experiment using the data obtained by the vehicle panorama camera and the POS shows that:the error of the roll angle and pitch angle can be within 0.2°, the error of the heading angle can be within 0.4°, and the error between the relative translational displacement and the POS can be within 2°. The result of our relative pose estimation algorithm is used to generate the spherical panoramic epipolar images, then we extract the key points between the spherical panoramic images and calculate the errors in the column direction. The result shows that the errors is less than 1 pixel.

Key words: spherical panoramic images, relative pose estimation, epipolar line, essential matrix, SVD

CLC Number:

P237

XIE Donghai, ZHONG Ruofei, WU Yu, FU Han, HUANG Xiaochuan, SUN Zhenxing. Relative Pose Estimation and Accuracy Verification of Spherical Panoramic Image[J]. Acta Geodaetica et Cartographica Sinica, 2017, 46(11): 1822-1829.

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