In: Wagner W., Szfltely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
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AN INVENTED APPROACH IN IMAGE REGISTRATION
“NEW ERA IN PHOTOGRAMMETRY”
A. S. Homainejad
Independent Research Group on Geospatial, Tehran, I.R. IRAN - s_homain@yahoo.com
KEY WORDS: Digital Image, Laser Scanning, Transformation, Ortho-image
ABSTRACT:
This paper will discuss an invented approach which focuses on providing an output from registration of an aerial
photograph on a 3D model such as DTM, DMS, or 3D model. The approach has been developed in order to omit
distortions from output and to increase the reliability. In contrast of other image registration methods which their
outputs are an image, this approach provide a 3D model which can be used for mapping, visualising, 3D GIS, ortho
rectify image. The approach is able to register a mono image on DEM, DTM, DMS, or 3D model with the minimum
requirement to camera calibration parameters. The paper will give a discussion on analysis of registration of an aerial
image on laser scanning data and registration of a terrestrial image on a 3D model by using this approach.
1. INTRODUCTION
Photogrammetry since its emergence has had at least two
major transitions. The first transition was begun at late
60s or early 70s when analytical stereoplotters were come
into the market and edged out analogue stereoplotters.
The second transition was started at mid 90s or late 90s
when digital photogrammetry was emerged and gradually
pushed analytical stereoplotters out. In digital
photogrammetry system a simulated stereoplotter
digitally created in the computer and all processing have
been implemented digitally, but the mathematical
concepts are the same. Consequently, all processes in
digital photogrammetry were computerised and a
supplementary image processing package was integrated
to the system. However, before emergence of digital
photogrammetry, digital images, digital image
processing, and digital image transformation were
successfully implemented in remote sensing and in digital
close range photogrammetry as well.
For ascertaining a reliable photogramme trie output,
enormous studies on photos, cameras, and mathematical
modelling have been fulfilled. With a glance research on
all studies, it will be recognised that all those studies,
despite of in which period they have been fulfilled, have
focused on the determination of interior parameters. For
example, Hallert (1968) and Hakkarainen and
Rosenbruch (1982) measured angles of rays with help of
a theodolite and collimator for defining the focal length.
Brown (1956) developed analytical camera calibration,
and Brown (1966) mathematically modelled the
decentring distortion. Kenefick et al (1972) developed an
analytical camera self-calibration with eight physical
parameters. Fraser (1997) explained parameters and
mathematical model for digital camera self-calibration.
Amiri Parian and Gruen (2010) developed a method of
self-calibration for panoramic camera.
Photogrammetry has embraced of a number of physics’
laws and it needs to fully familiar with them for
calibration. Investigation on these physical rules is not the
scope of this paper. More details regarding to above
issues can be found in photogrammetry and remote
sensing textbook, for example Slama (1980) and
Lillesand and Kiefer (1987). Photogrammetry during its
evolution has tested and implemented different
approaches for coping with these issues and producing a
reliable and precise output.
This paper will give a report on implementation of the
developed approach in two different projects. The first
project focused on registering an aerial image on a laser
scanning data and the second project registered a
terrestrial image on a 3D model.
This paper has been organised as follows. A brief
investigation on data fusion and the proposal of data
fusion for this project will be given in chapter 2. Chapter
3 will explain the study area. Chapter 4 will describe and
evaluate tests and outputs. A conclusion and remarks will
be given in chapter 5.
