THREE DIMENSIONAL DATA EXTRACTION FROM RADIOGRAPHS
D. Z. Seker a ,G. Birgin 3 , A.Goktepe b
a ITU, Civil Engineering Faculty, 80626 Maslak Istanbul, Turkey - (seker, gbirgin)@itu.edu.tr
b Selcuk University, Science Technical College-agoktepe@selcuk.edu.tr
Commission V, WG-V-6
KEY WORDS: Electrophotography, X-ray applications, X-ray measurements, three-dimensional displays
ABSTRACT:
The aim of the study is to produce three dimensional (3D) data from radiographs using photogrammetric techniques.
Photogrammetry is defined as the process of measurement on an object’s images taken in accordance with certain rules instead of
direct measurements on the object. This term includes whole operations of taking, processing, analyzing and evaluating the image.
Most important advantage of this method in medical studies is the high accuracy and cost effectiveness compared to classical
methods. Thus, this study is a photogrammetric approach to medical research and applications.
1. INTRODUCTION
For performing measurements on three dimensional models,
stereo X-Ray photogrammetry is a distinct approach. X-Ray
photogrammetry is based on central projection of X-Rays that
come from the focal point and fall on the film after passing
through the object. X-Ray techniques are commonly used in
medical sciences and industry. It is enables us to get physical
data from the human body or a live object and to produce three
dimensional images by using this data. By the help of this
imaging technique; tumor, cancer, other abnormal activities,
harmful unknown pieces like metal pieces in the stomach or
other metal pieces as a result of injuries and positional changes
and changes in the lengths of broken bones can be accurately
measured. For Stereo X-Ray photogrammetry two X-Ray
images with 50% or more overlap is required. Than these
images are observed in stereo and in order to regenerate the
object optically and mathematically, measurements are made on
points taken from different positions on the object (Ege et al.,
2004; Malian and Heuvel, 2004; Everine et al, 2005).
There are a few mathematical models used in X-Ray
photogrammetry. Main aim of these models is to determine the
positions of object points in a coordinates system. These
operations are done with basic geometrical correlations and
calibrations. Main mathematical models used in applications of
X-Ray photogrammetry are the Seattle, Cleveland and Direct
Linear Transformation (DLT) Model (Toz, 1987; Goktepe,
2004).
This study was conducted to incorporate photogrammetric
approach into medical sciences, where analyze and modeling of
bones were selected. The radiographs of forehand bones (ulna
and radius) have been taken using X-ray technology. During
this process, bones were nested into a specially designed and
produced mold in order to establish the relationship between
image and the object. Then, the radiographs have been scanned
and digitized. Three dimensional object coordinates were
obtained from picture (pixel) coordinates by means of DLT
method. With these object coordinates, the digital three
dimensional model of the bone was produced. The coordinates
of the control points, which were located on the mold, have
been recalculated by means of DLT method and then compared
with the model coordinates. Points and their locations have
been calculated and the 3-Dimensional model accuracy was
checked. The final product is a 3-Dimensional model, where
accurate measurements can be performed, visually
understandable and easily interpretable.
2. METHODOLOGY & RESULTS
A three dimensional mold was designed. The mold is a form of
box, which is made of plastic and a wood cover to protect the
system. The designed mold is establishing the reference system
and a coordinate base. The coordinate system surrounds the arm
bones (ulna and radius) and 63 points with known coordinates
are marked on the mold. 33 of these points have been
positioned at the lower base, which is forming a grid. The
remaining points were positioned asymmetrically on the right
and left sides of the lower base, which is like a ladder structure,
illustrated in Figure 1 and Figure 2. Thus, a three dimensional
coordinate system was formed to surround the arm bones .
Ergonomy of the human arm is also considered while designing
the model. Thus, an ergonomic external box was designed to
put the arm during the measurement process which also
contains coordinates and prevents harms (Birgin, 2007).
Figure 1. The Developed System
