固定下双视图自校准问题的封闭解

Proceedings. 2nd International Symposium on 3D Data Processing, Visualization and Transmission, 2004. 3DPVT 2004. Pub Date : 2004-09-06 DOI:10.1109/TDPVT.2004.1335300

T. Ueshiba, F. Tomita

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引用次数: 2

摘要

众所周知，两个未校准的透视视图之间的极层几何完全封装在基本矩阵中。由于基本矩阵有7个自由度(DOF)，如果从基本矩阵中提取出最多7个未知的相机内部或外部参数，则可以进行自校准。这项工作提出了一种线性算法，用于自校准透视相机经历固定，即一个特殊的运动，其中相机的光轴被限制在一个平面。由于该固定具有四个自由度，比一般运动的自由度小一个，因此我们最多可以从基本矩阵中提取三个固有参数。我们在这里假设焦距(1 DOF)和主点(2 DOF)是未知的，但对于两个视图是固定的。将证明这三个参数是由基本矩阵以解析的方式得到的，并推导出一个封闭的解。我们还描述了存在无限解集的所有简并运动。

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A closed-form solution for a two-view self-calibration problem under fixation

It is well known that the epipolar geometry between two uncalibrated perspective views is completely encapsulated in the fundamental matrix. Since the fundamental matrix has seven degrees of freedom (DOF), self-calibration is possible if at most seven of the intrinsic or extrinsic camera parameters are unknown by extracting them from the fundamental matrix. This work presents a linear algorithm for self-calibrating a perspective camera which undergoes fixation, that is, a special motion in which the camera's optical axis is confined in a plane. Since this fixation has four degrees of freedom, which is one smaller than that of general motion, we can extract at most three intrinsic parameters from the fundamental matrix. We here assume that the focal length (1 DOF) and the principal point (2 DOF) are unknown but fixed for two views. It will be shown that these three parameters are obtained from the fundamental matrix in an analytical fashion and a closed-form solution is derived. We also characterize all the degenerate motions under which there exists an infinite set of solutions.

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Proceedings. 2nd International Symposium on 3D Data Processing, Visualization and Transmission, 2004. 3DPVT 2004.

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