Affiliations: Laboratoire SIS/AI (Signaux Informations et Systèmes / Automatique et Image), Université de Toulon et du Var, BP 132, 83957 La Garde Cedex, France. Tel.: +33 4 94 14 20 77, 24 93, 22 48; E-mail: [email protected], [email protected], [email protected]
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Corresponding author.
Abstract: The Robotic systems for disabled people, aims at bringing a piloting assistance to powered wheelchairs in answer to the needs of mobility aid using dynamic vision techniques from mobile robotics. People start to design the robot with the fastest computers to process the information, together with high quality camera to serve as its eye, and precise mechanical motion control. The main working mode for this purpose is a contribution to dynamic vision, in the aim to improve a visio-space behavior of handicapped children. A self-calibration technique of a visual sensor is described: self-calibration implying the adoption of methods allowing to calibrate automatically a camera without using of special calibration set-ups. This paper examines what can be done within a Euclidean calibration, when the internal parameters must remain constant any more. So, we look at a Euclidean basis being a projective and one where some constraints must be observed. This work shows theoretically along with real experiments, how it is possible to completely calibrate a camera in line, that is to determine the intrinsic parameters and the relative displacement between two or three images, without any a priori knowledge of the scenes. The infinite homography computing method is used to estimate intrinsic and extrinsic parameters. This procedure consists of a closed-form solution, followed by a nonlinear refinement based on a bundle adjustment criterion.
