ACCURACY IMPROVEMENT IN AUTOMATED SURFACE MEASUREMENT 
   
Mushairry Mustaffar 
Postgraduate Student * 
Deptartment of Civil Engineering and Surveying 
University of Newcastle, NSW 2305 
AUSTRALIA 
Commission IIl, Working Group III/2 
KEY WORDS : digital image matching, surface measurement, object reconstruction, accuracy, surface model 
ABSTRACT 
Area-based matching has been acknowledged as being more precise than feature-based matching at finding 
corresponding points on digital images. This paper investigates a method of further improving the accuracy of the area- 
based technique by modifying the functional model describing the relationship between the windows. The method 
replaces the approximations made using an affine transformation. It makes use of a surface model and the collinearity 
conditions in determining the transformation needed. Since there is greater fidelity involved in the transformation, it is 
hypothesised that the improved functional model will allow the use of larger windows for matching and hence improve 
accuracy. The derivation of the theory and some experimental results will be presented. Initial experimental results show 
that the proposed method is capable of attaining absolute accuracy mildly superior to conventional area-based 
matching. 
1.0 INTRODUCTION 
Techniques in digital image matching, or ^ image 
correlation, have been developed within various 
disciplines over the last few decades and a vast number 
of approaches exists. These techiques can be classified 
into two main groups, viz, feature-based and area-based 
matching. Stereo image matching techniques make use 
of a selected area or features within the image or the 
combination of both for matching (Li 1991). However, it is 
well accepted that area-based matching (ABM) method is 
more precise than feature-based matching for finding 
corresponding points on digital images. Methods in area- 
based matching have been developed by Foerstner 
(1982) and Gruen (1985). Some examples of the 
applications and experiments done on ABM in various 
fields have been reported by Ackermann (1984), Pertl 
(1985), Rosenholm (1987b), Crippa et. al. (1993), Hahn & 
Brenner (1995). Further extensions of area-based 
matching were proposed by Gruen & Baltsavias (1987) 
whereby methods of constraining the matching with 
model coordinates (X,Y,Z) through the collinearity 
conditions were proposed. Their methods, known as 
geometrically constrained area-based matching, use a 
unified (combined) least squares solution in which 
corrections to the affine parameters and model 
coordinates (X,Y,Z) were solved iteratively. Rosenholm 
(1987a) proposed the method of multi-point area-based 
matching technique in evaluating three-dimensional 
models. Area-based method is further extended by 
Baltsavias (1991) through the use of images from several 
viewpoints (multi-image). Recent development of the 
area-based method is proposed by Wrobel (1991), 
Heipke (1992) whereby matching is done on a global 
approach by integrating multi-image matching and object 
surface reconstruction. 
  
* Currently on study leave from : 
The Faculty of Civil Engineering 
Universiti Teknologi Malaysia 
80990 Johor Bahru, MALAYSIA. 
555 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996 
This paper investigates a method of improving the 
accuracy of the traditional area-based technique by 
modifying the functional model through the use of a 
surface model to describe the relationship between the 
windows. The method replaces the assumptions made 
using an affine transformation. It also serves as a 
compromise to the more complex global area-based 
matching method. The method proposed here makes use 
of a surface model and the collinearity conditions in 
determining the transformation needed. It solves, through 
an iterative least squares solution, directly the corrections 
to image coordinates (x,y) of the search window. In 
addition, two ‘new’ unknowns, the gradients in X and Y 
directions on the surface at the point on the surface which 
corresponds to the centre of the search window and their 
second derivatives are introduced. Since the 
transformation used is more rigorous than the affine, it is 
hypothesised that the improved functional model will 
allow the use of larger windows for matching and hence 
improve accuracy. It is also hypothesised that the use of 
a better functional model will converge more quickly to 
give a solution. 
2.0 AREA-BASED IMAGE MATCHING USING A 
SURFACE MODEL 
The basic area-based observation equation, which gives 
a relationship between the radiometric values of 
corresponding pixels in the left and right image windows, 
can be written as follows :- 
IL(xL.yL)* n(xy) 2 IR(XR.YR) (D 
where, 
IL, IR are the intensities of the left and right pixels 
respectively 
XL, yL are the image coordinates of the left pixel 
XR, yRare the corresponding image coordinates on 
the right image 
n(x,y) is the difference caused by noise at the point 
(x,y) on the left image