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GENERATION OF ORTHORECTIFICATED IMAGE PATCHES 
FROM MULTIPLE IMAGES 
Shih-Hong CHIO* 
Dept. of Land Economics, National Chengchi University, Taipei City, 116, Taiwan, R.O.C. 
chio0119@nceu.edu.tw 
KEY WORDS: Photogrammetry, Automation, Fusion, Generation, Orientation, Triangulation, Orthorectification, Orthoimage, 
Aerial 
ABSTRACT: 
Orthoimages can be used for several purposes. One of them is used them as control information, instead of artificial targets, to 
determine the exterior orientation of new aerial images. For such a purpose, the image displacements on aerial photos, usually tilted 
photographs, caused by topographic relief (including the relief of topographic objects) should be removed. In that case the correct 
geometrical and radiometric information can be obtained from those orthoimages and provided for control information. That means 
“true” orthoimages should be generated. However the generation of “true” orthoimahes needs the accurate height information of 
terrain areas and the acquisition of accurate height information are always time-consuming and labour-intensive. Therefore this 
paper will try to propose a method to efficientally generate the orthorectificated image patches as controls for aerotrianguation. This 
proposed methodology will generate orthoimage patches from multiple aerial images without detailed terrain height information. A 
concept of floating plane, similar to the concept of floating mark, will be presented in this paper to produce several candidate sets of 
orthoimages for a terrain area at some height range. Each candidate set consists of several possible related orthoimage patches of a 
terrain area from multiple images at some height. Subsequently, a procedure will be developed to decide an optimal set from those 
candidate sets for this terrain area. A unique orthorectified image patch of this terrain area will be fused from this optimal set. The 
relevant assessment of accuracy will be also discussed and conducted in this paper. Finally, experiments prove the good geometric 
accuracy of proposed methodology. 
1. INTRODUCTION 
The procedure of orthorectification will remove the image 
displacements on tilted aerial photos caused by topographic 
relief and generate the orthoimages. Orthoimages will not only 
have the same property as the maps, but also have the detailed 
image information. Therefore, they are essential for urban plan, 
national plan, resource investigation, environmental monitoring 
and so on. Thereby, they play an important role for geographic 
information systems (GISs). Because of the same property as 
the maps, orthoimages can be also used for the extraction of 
topographic information. In addition, 3D Landscape simulation 
will be realized together with digital terrain model by using the 
relevant computer hardware and software. Moreover, 
orthoimages were also used as control information in these 
years, instead of artificial targets, for new aerial images [ Hóhle, 
1999,2001;Paszotta, 2000; Shan, 1999;Yang, 2003] Those 
studies select the existing orthoimage patch and DTM for 
automatic exterior orientation. But for better quality of control 
information, the "true" orthimage should be produced. The 
process of orthoimage is called as orthorectification. During 
orthorectification process, the collinearity condition is utilized 
to remove the image displacements when the camera exterior 
orientation and terrain relief information, including the height 
of topographic objects, should be known accurately. That 
means “true” orthoimages should be generated from the 
accurate height information of terrain area. However the 
acquisition of accurate height information is always time- 
consuming and labour-intensive. Hence, this paper is going to 
propose an approach to efficientally generating the “true” 
orthorectificated image patches as controls in aerotrianguation 
from multiple aerial images with known exterior orientation, 
but without detailed height information of a terrain area. A 
concept of floating plane, similar to the concept of floating 
mark, will be presented in this paper to produce several 
875 
candidate sets of orthoimage patches of a terrain area at 
different height after the approximation height information of 
this terrain area is given. Each candidate set consists of several 
possible related orthoimage patches at some height for this 
terrain area. Then a procedure to decide an optimal set from 
those candidate sets for this terrain area will be also developed. 
At last, a unique orthorectified image patch for this terrain arca 
will be fused from this optimal set of orthoimage patches. The 
relevant assessment of accuracy will be also discussed and 
conducted in this paper. Unlike the tests of Hóhle, [1999, 2001 ], 
Paszotta [2000], Shan [1999], and Yang [2003] existing 
orthoimage and height data are used and the ground coordinates 
(XY) with an interpolated height value (Z) are used together 
with the corresponding image coordinates in an orientation 
program. We hope the proposed orthorectification procedure 
will be much more efficient to establish the more accurate 
control information for automatic determination of exterior 
orientation of new aerial images. 
2. METHODOLOGY 
In this study, a method to generate a unique orthorectified 
image patch of a terrain area from multiple acrial images with 
known exterior orientation will be proposed. The basic 
assumption is that this terrain area is composed of horizontal 
plane and the approximation of height information about this 
terrain area is provided. That is, only the approximation of 
height information is used for the orthorectification. No precise 
height information must be measured by the operator. 
After the approximation of height information of a terrain area 
is provided, this corresponding 3-D space is subdivided into 
several equal-spacing horizontal planes according to the 
desirable height accuracy, e.g. 20cm, and the possible range of 
height. Each horizontal plane will be further divided into the