tions. 
-266. 
try in 
1g ar- 
mpu- 
01. A 
ent of 
rkish- 
|. pp. 
on in 
tems. 
B no. 
tima- 
ICCV 
d for 
hicles 
GIM, 
plica- 
eying 
IMAGE-VARIANT INTERIOR ORIENTATION AND SENSOR MODELLING OF HIGH- 
QUALITY DIGITAL CAMERAS 
H. Hastedt*, Th. Luhmann, W. Tecklenburg 
Institute for Applied Photogrammetry and Geoinformatics, University of Applied Sciences Oldenburg, 
Ofener Strafe 16/19, D-26121 Oldenburg, Germany - iapg(a)fh-oldenburg.de/*h.hastedt(g)vermes.fh-oldenburg.de 
Commission V, WG V/1 
KEY WORDS: camera calibration, image-variant interior orientation, finite elements, distortion, accuracy, bundle adjustment, 
guideline VDI/VDE 2634 
ABSTRACT: 
Nowadays digital high-resolution consumer cameras are increasingly used in closerange photogrammetry. These partial-metric 
cameras do not meet photogrammetric requirements as (conventional) metric cameras do. Especially the mechanical constructon of 
these cameras is instable. Therefore extended mathematical models for camera calibration are required to model all instabilities and 
influences sufficiently. An approach including image-variant interior orientation for camera modelling is discussed. A correction 
model with finite elements is added to the mathematical model that provides the correction of remaining errors in sensor space. All 
parameters are estimated simultaneously in a bundle adjustment. Based on the German guideline VDI/VDE 2634 foracceptance and 
reverification test of optical 3D measuring systems the discussed camera modelling is tested by different camera lens combinations 
and configurations of imaging. The results express the importance of the camera model and the investigationsconcerning verification 
tests as described in this paper. Significant improvements of accuracy have been achieved with respect to conventional calibration 
techniques within self-calibration bundle adjustment. 
1. INTRODUCTION 
High quality digital cameras are increasingly used for industrial 
metrology and machine vision applications. Most of these 
cameras are designed for photo-journalism purposes and do not 
meet photogrammetric requirements as conventional metric 
cameras do (Shortis et al. 1998; Luhmann & Wendt 2000). In 
particular these partial-metric cameras show high instability 
concerning the fixed CCD-array with respect to the lens. The 
system’s accuracy mainly depends on image resolution, image 
scale, image measurement precision and network design (Fraser 
et al. 1998). Relative precision of 1:50000 up to 1:80000 is 
required for most industrial applications. Internal accuracy up to 
1:100000 can be achieved using a Kodak DCS 460 (Shortis et 
al. 1998). Image measurement precision of 0.02 — 0.05 Pixel, 
respectively 0.25um in image space can be achieved, hence it is 
fundamental for the accuracy of the photogrammetric bundle 
adjustment. 
The calibration of still-video cameras like the Kodak DCS 460 
or the Fuji S1 Pro is necessary to consider and elimirate 
systematic errors (Shortis et al. 1998). Conventional mathema- 
tical models for camera calibration assume a stable interior 
orientation for one set of images over the whole period of image 
acquisition. Principal distance (c;) principal point (xjy;), 
radial-symmetric lens distortion (a;,a,,a3), decentring of lenses 
by tangential and asymmetric distortion (b,,b,) and global 
sensor properties such as affinity and sheering (cı,c,) are 
estimated within self-calibrating systems. 
Different investigations have been made to take deformations of 
film and sensor plane into account (e.g. CAP). Munji (1986) 
reports on the application of finite elements for the determi 
nation of local imaging errors of partia-metric cameras. The 
behaviour of the principal point for Kodak cameras with 
assumed fix principal distance based on several sets of images is 
exposed at Shortis et al. (1998). Fraser et al. (1992) and Dold 
(1997) report on the influence of variation of distortion within 
the photographic field and gained improvement in accuracy for 
special applications. 
It can not be assumed that camera parameters remain stable over 
the whole period of image acquisition. Gravity takes effect with 
different viewing directions. Long periods of image acquisition 
yield to heat the camera with increasing influences on the 
photogrammetric system (Jantos et al. 2002). The camera is 
subject to intense mechanical influences by the user; especially 
hand-held shots are influenced by the users handling and can 
yield to varying strains of the camera body (Tecklenburg et al. 
2000). 
These effects are investigated by the discussed extended model 
for camera calibration. An image-variant interior orientation is 
added to the camera model which describes variation in 
principal distance and principal point. As a major result the 
possible displacement and rotation of the lens with respect to 
the image sensor are compensated by this model, similar to the 
approach of Maas (1998). In order to compensate sensor based 
influences (especially sensor unflatness) as well as all remaining 
lens effects not considered within radia-symmetric lens 
distortion, a finite-elements correction grid has been chosen. 
This raster-wise correction grid based on anchor points is 
distributed according to an a priori grid width. 
This approach is verified by various sets of images of a testfield 
based on the German guideline VDI/VDE 2634. Different 
photogrammetric projects are accessable of an own control field 
with reference points for comparability and quality of the 
camera and its parameters. Mainly two cameras (Kodak DCS 
460 and Fuji S1 Pro) are tested by different sets of images of the 
described testfield. The results are presented and discussed. 
2. MATHEMATICAL MODEL 
2.1 Image-variant parameters 
Usually camera parameters are applied identically for all images 
of a photogrammetric project. Distortion parameters are defined 
-27-