This paper proposes a contribution to the adjustment problem of airborne laser scanner strips. Based the comparison of each laser strips with a photogrammetric derived Digital Surface Model (DSM), and on the modeling of the discrepancies between these two data sets, the algorithm produces an homogeneous 3D deformation field. The measurements of these deformations is performed using a modified Hough transform and we search for the maximum of the accumulator whereupon we assign a probability of correctness. Depending of this probability, we estimate a global affine transform over the cloud of points. For transitivity properties, all strips are registered with regard to this DSM and therefore they all perfectly fit on overlapping areas. This fine registration is of importance for many applications, especially when fusionning photogrammetric data and lidar data for feature extraction. More generally, this method can be applied to any other sorts of 3D data and provides an efficient algorithm for matching 3D datasets
[1]
H. Maas.
On the use of pulse reflectance data for laserscanner strip adjustment
,
2001
.
[2]
G. Vosselman.
ON THE ESTIMATION OF PLANIMETRIC OFFSETS IN LASER ALTIMETRY DATA
,
2002
.
[3]
Sagi Filin,et al.
Analysis and implementation of a laser strip adjustment model
,
2003
.
[4]
Gang Xu,et al.
Epipolar Geometry in Stereo, Motion and Object Recognition
,
1996,
Computational Imaging and Vision.
[5]
W. Kornus,et al.
STRIP ADJUSTMENT OF LIDAR DATA
,
2003
.
[6]
ESTIMATING INTRINSIC ACCURACY OF AIRBORNE LASER DATA WITH LOCAL 3D-OFFSETS
,
2003
.
[7]
C Baillard,et al.
A STEREO MATCHING ALGORITHM FOR URBAN DIGITAL ELEVATION MODELS
,
2000
.
[8]
H. Maas.
Methods for measuring height and planimetry discrepancies in airborne laserscanner data
,
2002
.