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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B3. Istanbul 2004 
T1 > T2 7 the threshold values 
f (i j)= a value of source image wavelet 
where 
transformation 
The above given thresholding is applied for two set of detailed 
sub-images: | LHI,HLI,HHI which come from first 
decomposition of the whole image and LH2,HL2,HH2 which 
come from the second decomposition of the LL sub-image. This 
thresholding respects the properties of sub-images: non- 
directionality of the LL sub-image and the directionality of the 
detailed sub-images. The results shown in figure ld is 
a evidence that wavelet transformation with the proposed 
thresholding is a useful method in de-noising. 
  
Figure 1. The way from original to de-noised image 
a = the original image 
b = the decomposition into four sub-images (first level) 
c = the result of the soft thresholding 
d = the de-noised image 
3. EDGE DETECTION USING LAPLACE OPERATOR 
Edge detection is the process of extracting out locations of high 
contrast in an image. 
The most popular methods of this process use high-pass filters 
of a specific size. The image convolution with a small filtering 
mask approximates the first or second derivative of the image 
intensity function. There are two detectors applied (Pitas, 
2000): 
* first order derivative — so called intensity gradient — i.e. 
Roberts, Sobel - result is a vector, 
* second order derivative - Laplace operator (laplacian) - 
result is a scalar: 
n 2 
o. Q^o Q^o 
&,)-7 9.78 (2) 
ex^ y^ 
639 
The intensity gradient is easy to perform but it gives very little 
control over smoothing and edge localization. The Laplace 
operator gives better results but it is very sensitive to noise, 
more than the intensity gradient method. Therefore it is often 
applied together with the Gaussian smoothing and they form so 
called the Laplacian of Gaussian (LoG) operator. But the LoG 
operator provides that the image intensity function operates in 
the same way in any direction from each pixel. This is the 
reason why both noise and detailed information are removed. 
In this work the Laplace operator is used as the next step after 
image de-noising.. The approximation of the equation (2) is 
realized as a result of image convolution with the Laplace mask 
and we obtain a laplassian image: 
Ki, ]) * g, )* Lug G) 
where = /(i, j) = laplasian image 
gli, j) = the intensity value of de-noised image 
)- 1954 
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1 1 ] 
4. THE EXECUTION OF ORTHORECTIFICATION 
WITH A SPECIAL RESAMPLING 
The orthorectification is the process of removing geometric 
errors inherent within aerial and satellite images due to 
a orientation of cameras and the influence on projection of 
ground surfaces. In the indirect way of orthorectification for 
the position on orthoimage the equivalent location in the source 
image is calculated by using a projecting equations and by 
applying a DEM and exterior orientation parameters of 
a camera (Kraus, 1997). The procedure starts from ground 
position (X,Y) and projects it towards to a coordinate system of 
the source image and the position (x,y) is received. The source 
image is a array where the position of pixels is represented 
thrugh an integer row-columns coordinate system. Therefore 
the orthorectification process comprises a digital resampling 
procedure. This resampling relies on an assessment of the 
intensity values of a group of pixels from source image to 
assign a value to the position (x,y). Three algorithms of 
resampling are normally employed in orthorectification 
software packages: the nearest neighbor method uses the 
intensity of one source pixel, the bicubic method interpolates a 
new value from four pixels and the cubic convolution method - 
from sixteen source pixels. 
The Bilinear Interpolation and the Cubic Convolution often 
produces similar results, however the Cubic Convolution 
method generally produces a smoother output raster. But these 
methods have the effect of a low-frequency convolution. Most 
of the edges are smoothed, and some extremes of the data file 
values are lost. Only the nearest neighbor method insures that 
the extremes and subtleties of the data values are not lost. But 
this method causes usually a stair-stepped effect around edges 
(Erdas, 1999). 
In the work described in this paper a special resampling method 
was tested — see formula (4). The result is shown in the figure 2.