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3437, pp.
Andreas Keim
STRAIGHT LINES IN LINEAR ARRAY SCANNER IMAGERY
Ayman Habib, Devin Kelley, Andinet Asmamaw
Department of Civil and Environmental Engineering and Geodetic Science
The Ohio State University
habib.1 € osu.edu, kelley.83 @osu.edu, asmamaw. 1 @osu.edu
ISPRS Commission III
KEY WORDS: Linear Features, Linear Array Scanners, Aerial Triangulation
ABSTRACT
Increased use of digital imagery has facilitated the opportunity to use features, in addition to points, in photogrammetric
applications. Straight lines are often present in object space, and prior research has focused on incorporating straight-
line constraints into the bundle adjustment for frame imagery. In this research, we introduce a straight-line constraint
in the bundle adjustment for linear array scanners. A linear array scanner scene is acquired using different geometry
than frame cameras. A scene is composed of a sequence of images, each of which may be slightly shifted against each
other due to slight changes in the system’s trajectory. As a result, straight lines in object space do not appear as
straight lines in image space. The proposed bundle adjustment constraint accommodates this distortion. The underlying
principal in this constraint is that the vector from the perspective center to a scene point on a straight-line feature lies on
the plane defined by the perspective center and the two object points defining the straight line. This constraint utilizes
the perspective transformation model for point features in linear array scanner imagery. The proposed technique makes
use of straight-line features in object space, and aids in the recovery of the exterior orientation parameters as well as
adding to the geometric strength of the bundle adjustment. This constraint has been embedded in a bundle adjustment
software application, developed at the Ohio State University, that models frame and linear array scanner imagery
1. INTRODUCTION
Most photogrammetric applications are based on the use of distinct points. These points are often obtained through
measurements in an analog or digital environment. Recently, more attention has been drawn to linear features. There
are several motivations for the utilization of linear features in photogrammetry:
* Points are not as useful as linear features when it comes to higher level tasks such as object recognition.
* Automation of the map making process is one of the major tasks in digital photogrammetry and cartography. It is
easier to automatically extract linear features from the imagery rather than distinct points (Kubik, 1988).
* Images of a man made environment are rich with linear features.
Habib (1999) discusses the various options for straight-line representation in photogrammetric applications. The
primary representation considerations are uniqueness and singularities. In this research, straight lines in object space
are represented by using two points along the line. In this way, the line segment is well localized in the object space.
This representation is attractive because such coordinates can be easily introduced or obtained from a GIS database.
Previous research on linear features in photogrammetry has focused primarily on frame imagery. Straight-line
constraints can be incorporated into the bundle adjustment by utilizing the fact that the perspective transformation of a
straight line is also a straight line. Mikhail and Weerawong (1994) proposed a straight-line constraint that constrains a
unit vector defining the object space line, the vector from the perspective center to a point on the object line, and the
Vector from the perspective center to the image point to be coplanar. In their approach, the object line is represented as
an infinite line segment. Habib (1999) proposed a straight-line constraint, which forces the plane defined by the image
line to be coplanar with the plane defined by the perspective center and two object points defining the line. In this
approach the object line is defined by two points, localizing it in space. These techniques rely on the use of frame
Imagery.
International Archives of Photogrammetry and Remote Sensing. Vol. XXXIII, Part B1. Amsterdam 2000. 173