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AIRBORNE GPS
K. Jeyapalan
Professor of Civil Engineering
Iowa State University
Ames, Iowa 50011
United States of America
KEY WORDS: GPS, Photogrammetry, Calibration
ABSTRACT:
The paper gives the theory of airborne GPS related to Photogrammetry and the results of a self calibration used to validate the theory.
Accordingly, no ground control points are required for mapping using a strip or block of photographs provided the site is within 10 Km of
the calibration site.
INTRODUCTION
Global Positioning System (GPS) technology has been developed in
recent years such that the position of moving objects can be
determined to about +0.2mm relative accuracy and about + 2cm
absolute accuracy. The airborne GPS research was conducted at
Iowa State University from April 1993 to May 1995. A series of
four tests were carried out in St. Louis, Missouri and in Ames, Iowa.
All tests, except one, were done in cooperation with Ashtech and
Surdex Inc., using Cessna aircraft, LMK 2000 camera and Ashtech
receivers. The objective of this research was to use airborne GPS to
take aerial photographs at predetermined locations, to determine the
best aerial camera location and orientation for mapping.
The research showed that Airborne GPS is feasible. In block
triangulation no ground controls are required. In a strip, no ground
controls are required provided either the omega angle (rotation about
the y axis) of the camera is known or the height difference between
2 or more points in the y direction are known. The research showed
that the omega angle of the camera can be determined to an
accuracy of 0.0001 radians by a self calibration from the omega
angle of the aircraft determined by airborne GPS, provided the
calibration site is within 10km of the photographic site.
The objectives of this paper are to describe briefly photogrammetry
and kinematic GPS as they relate to airborne GPS, give the
summary of the self calibration used to test airborne GPS, and the
conclusions and recommendation.
PHOTOGRAMMETRY
In photogrammetry the photo coordinates (x, y) are related to the
ground coordinates (X5,yg,z5) by the following equation:
X- X, = f(all(x; - x) * a12 (yo-y,)*a13(25-2,)) (a3 1 (xg -
X,) + 332 (yo-y,)*a33(25-7,)) * radial distortion ** decentering
distortion + refraction
y-y, = f(a21(Xg - X,) + 822 (Yo-Yo) +a23(26-2,))/(a31(X; - X,)
* a32 (yo-y,)*a33(z5-27,)) * radial distortion +
decentering distortion + refraction (1)
where x,, y,, f are interior orientation elements, (x , y , z ) are the
nodal point coordinates in the ground coordinates system.
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996
and A =R,RORG = all al2 al3
a21 a22 a23
a3l a32 a33
Where R£R®,Rd are the rotation matrix required to make the photo
coordinates axes (x,y,z) parallel to the ground coordinate axes by
rotating first about x axis by à , then about y axis by ¢ and finally
about z axis by K. The K,$,Ó are known as the orientation angles.
The x,, y, z,, K,$,Ó are known as the exterior orientation elements.
The objective of photogrammetry is to determine (Xs, yo, za) of a
point from the photo coordinates of two or more photographs. This
is done by three methods: Analog, analytical and self calibration.
In the analog method, the interior orientation, radial and decentering
distortions are assumed small. The projectors are used to project the
images and produce the stereo models. When producing the stereo
model, five of the twelve exterior orientation elements are
determined by relative orientation. The stereo model is scaled and
leveled using external ground control points, thus determining the
other seven exterior orientation elements. Special instruments such
as Zeiss Z8 are designed to produce the stereo model and then plot
the map.
In the analytical method, the photo coordinates are corrected for
interior orientation, radial and decentering distortions given by the
calibration of the camera. The photo coordinates of two or more
photos, together with three or more known ground control are
simultaneously adjusted to give the ground coordinates. Software
such as "Albany" is capable of such adjustment. Some stereo
plotters which are connected to computers for doing these
computations in real time and which assist in driving the plotters are
known as analytical plotters.
In self calibration, the interior orientation elements, the radial and
decentering lens distortion elements, and the exterior orientation
elements are simultaneously determined with unknown ground
control points using the photo coordinates of two or more photos
and a number of ground control points. The method used is
normally the least squares constraint method in which any of the
parameters are constrained to its known accuracy. The program
such as *Calib" is capable of this adjustment.
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