Kr. Hoffmann et al., DETERMINATION OF 3D IMAGING GEOMETRY AND OBJECT CONFIGURATIONS FROM 2BIPLANE VIEWS - AN ENHANCEMENT OF THE METZ-FENCIL TECHNIQUE, Medical physics, 22(8), 1995, pp. 1219-1227
We present a new technique based on the method developed by Metz and F
encil for estimation of the 3D imaging geometry and 3D object configur
ations from biplane angiographic acquisitions. The new method employs
the 3D configuration of points calculated by the Metz-Fencil technique
as an initial estimate. A 3D Procrustes algorithm is employed to tran
slate, rotate, and scale the configuration until it aligns optimally w
ith the set of lines that connects a focal spot with the corresponding
set of image points. This alignment procedure is applied independentl
y for each view. The rotation and translation that relate the two alig
ned data sets are then determined by an additional 3D Procrustes calcu
lation. These steps are applied iteratively. Evaluations were based on
Monte Carlo simulation and phantom studies. With this new technique,
the mean absolute errors in magnification, in the relative position of
the points, and in the angles defining the rotation and translation m
atrices were approximately 3.0%, 1.5 mm, and 5 degrees and 3 degrees,
respectively, for rms input errors in the image data up to 2.0 pixels
(0.7 mm). Errors in the results can be as small as 0.5%, 0.16 mm, 0.6
degrees, and 0.3 degrees, respectively, if input image-data error is 0
.035 mm. The improvement of the Metz-Fencil technique described here m
ay provide a basis for precise estimation of the biplane imaging geome
try and the 3D positions of vessel bifurcation points.