3D pose estimation using joint-based calibration in distributed RGB-D camera system.

This paper proposes a new approach that acquires camera parameters and generates an integrated 3D joint using an RGB-D camera network distributed in an arbitrary location in space. The proposed technique consists of three steps. In the first step, camera parameters are calculated using partial joints as feature points. The internal and external parameters between cameras are not calculated using a specially manufactured calibration plate. In the second step, a 3D joint set is estimated by integrating the joints obtained from each camera using the calculated camera parameters. At the same time, a 3D volumetric model in the form of a point cloud is reconstructed. The third step consists of a joint correction algorithm. The resultant 3D joint with high reliability is estimated by correcting the position of the joint using the 3D point cloud reconstructed previously. The generated 3D joint can accurately express the shape and movement of 3D human. The estimated 3D joint was compared with the joint measured using a motion capture device to evaluate its performance. The temporal standard deviation between two measurements shows very low value from 1.966 mm to 7.99 mm. [Display omitted] • Performing camera calibration using incomplete or partial joints obtained from images output from cameras installed in irregular positions. • Temporal improvement of the precision of transformation parameters obtained through camera calibration. • 3D joint generation while minimizing the error of pose estimation algorithm. • Correction of 3d joint using 3d point cloud registration. • Simultaneous 3D reconstruction of 3D indoor space and humans. [ABSTRACT FROM AUTHOR]