tanbul 2004
we errors of
1) (9)
2) (10)
| point pair
points.
(GLE BY
ly collected,
red can be
, which is
nsformation
o fulfill the
launay TIN,
| is close to
d after the
sions which
' points are
'ondition to
method is
adopted to
t, then find
of the two
The initial
first triangle.
and ps, and
sly that the
cated at the
also not the
f the line; if
0, (x’y°) is
en obtained
on (13), we
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B3. Istanbul 2004
can get the point that will be expanded, which is corresponding
to the maximum C.
cosC - (a! «b? -c^)/2ab (13)
When the first edge of the triangle & has been expanded, apply
the same method to expand the other two edges; then turn to the
k+1 triangle until all the points have been gone through.
a
Fig. 3 Straight line judgment method
4.2 Fulfill Registration Triangle By Triangle
Within each triangle pair, construct the regional rectification
model using the affine transformation, equation (14), together
with the coordinates of the vertexes of the two triangles. Then
fulfill the high precise registration of the two images triangle by
triangle.
[x =d,+ax+a,y
; (14)
ly = b, + b, X + b,y
After the regional rectification model has been established, the
key point of this rectification method is to judge which triangle
that the point to be rectified is located in. In order to speed the
process, we can judge if the point is located in the
circumrectangle of the triangle. If it is true, we can further
judge if the point is located within the triangle.
S. EXPERIMENTS AND CONCLUSIONS
Using the method presented by this paper, the software that
realizes the high precise rectification and registration of multi-
source remote sensing imagery has been developed in VC++
language, based on personal computer, and this software has
been successfully used in land use and land cover change
detection based on multi-temporal remote sensing imagery and
dynamic land use monitoring based on TM 30m multi-spectral
data and SPOT 10m panchromatic data. Figure 4,5 and 6 are the
experimental results using the high precise TIN rectification
method presented by this paper.
IAEA lelxi
uj
MR, Fr
Fig.4 TIN constructed on the geo-referencing image
859
Fig.6 The rectified result
Experimental results and practical work show that the approach
presented by this paper is simple and applicable without
employing DEM, satellite ephemeris data and orientation
information of the sensor, and it is an effective method to
realize the high precise rectification and registration of multi-
source remote sensing imagery. Because of the speciality of the
radar imaging mode, the method presented by this paper is not
applicable to radar imagery. In addition, after the control points
have been selected by human-computer interaction, the high
precise registration of the thematic data and the image data can
be fulfilled by TIN rectification developed in this paper.
REFERENCES
Zhang Jixian, Lin Zongjian, Zhang Yonghong, et al., 2000.
Remote Sensing Orthophotoquad Generation without
Employing DEM. Journal of Remote Sensing, 4(3), pp. 202-207.
Zhang Zuxun, Zhang Jianging, 1997. Principles of Digital
Photogrammetry. Publishing House of Wuhan Technical
University of Surveying and Mapping, Wuhan,
Yang Delin, 1982. Principles, Methods and Applications of
Large-scale Digital Mapping. Publishing House of Surveying
and Mapping, Beijing.
