A Hierarchical Method for Aligning Warped Meshes

 

Leslie Ikemoto

Stanford University

Natasha Gelfand

Stanford University

Marc Levoy

Stanford University

 

Appears in
Fourth International Conference on
3D Imaging and Modeling (3DIM),
October 6-10, 2003, Banff, Alberta, Canada

 

Abstract

 

Current alignment algorithms for registering range data captured from a 3D scanner assume that the range data depicts identical geometry taken from different views. However, in the presence of scanner calibration errors, the data will be slightly warped. These warps often cause current alignment algorithms to converge slowly, find the wrong alignment, or even diverge. In this paper, we present a method for aligning warped range data represented by polygon meshes. Our strategy can be characterized as a coarse-to-fine hierarchical approach, where we assume that since the warp is global, we can compensate for it by treating each mesh as a collection of smaller piecewise rigid sections, which can translate and rotate with respect to each other. We split the meshes subject to several constraints, in order to ensure that the resulting sections converge reliably.

 

Paper

PDF (8 MB)

Powerpoint slides (9.5 MB)

 

 

 

Figure 1.  Marble fragment of the Forma Urbis Romae. Left: computer rendering of mesh from alignment and merging under incorrect calibration. Left inset: blurring of the map due to incorrect alignment. Plot shows that a sample incision is shallow (with a depth of 0.25 mm) and incorrectly shows two minima. Right: results of our technique on same input scan. Right inset: the blurring is greatly reduced, and the depth of the incision measures 0.5 mm, which is more consistent with the approximate depth of the Forma Urbis incisions.

 

 

Figure 2.  The face of Michelangelo's David. Top: alignment and merging under incorrect calibration. The lips exhibit gross misalignments on the order of 1.9 mm. Bottom: our results. The artifacts in the lips have been greatly reduced.