AN OPERATIONAL SYSTEM FOR AUTOMATED ROAD DATABASE 
UPDATING FROM AERIAL IMAGERY 
C. Zhang, E. Baltsavias 
Institute of Geodesy and Photogrammetry, Swiss Federal Institute of Technology Zurich, ETH Hoenggerberg, CH-8093 Zurich, 
Switzerland — (chunsun, manos )(a)baug.geod.ethz.ch 
Commission III, WG I11/4 
KEY WORDS: 3D Road reconstruction, color, context, knowledge base, edge matching, DSM/DTM; roadmarks: multiple cue 
integration; performance evaluation; semi-automated system 
ABSTRACT: 
This paper presents a practical system for automated 3D road network reconstruction from aerial images using knowledge-based 
image analysis. The system integrates processing of color image data and information from digital spatial databases, extracts and 
fuses multiple object cues, takes into account context information, employs existing knowledge, rules and models, and treats cach 
road subclass accordingly. The key of the system is the use of know 
ofthe results, working in 2D images and 3D object space, and use o 
ledge as much as possible to increase success rate and reliability 
f 2D and 3D interaction when needed. Another advantage of the 
developed system is that it can correctly and reliably handle problematic areas caused by shadows and occlusions. This work is part 
of a project to improve and update the 1:25,000 vector maps of Sw 
itzerland. The system was originally developed to process stereo 
images, but it has been modified to work also with orthoimages, thus making it applicable to sensors of unknown geometry. The 
system has been implemented as a stand-alone software package, and has been tested on a large number of images with different 
landscape. In this paper, various parts of the developed system are discussed, and the results of our system in the tests conducted 
independently by our project partner in Switzerland, and the te 
presented together with the system performance evaluation. 
I. INTRODUCTION 
The extraction of roads from digital images has drawn 
considerable attention in the last few decades. This is 
increasingly stimulated by various existing and emerging 
applications requiring in particular up-to-date, accurate and 
sufficiently attributed road databases. The fact that most 
vendors of commercial photogrammetric, remote sensing and GI 
systems do not offer anything useful regarding automation of 
road extraction (not even practical semi-automatic methods) 
stresses the importance of this research topic. The existing 
approaches for road extraction cover a wide variety of 
strategies, using different resolution aerial or satellite images. À 
quite extensive overview of such approaches is given in Zhang 
(2003a). Semi-automatic schemes require human interaction to 
provide interactively some information to control the extraction. 
Roads are then extracted by profile matching (Vosselman and 
Knecht, 1995), cooperative algorithms (McKeown et al, 1988) 
and dynamic programming or LSB-Snakes (Grün and Li, 1997). 
Automatic methods usually extract reliable hypotheses for road 
segments through edge and line detection and then establish 
Connections between road segments to form road networks 
(Wiedemann et al. 1998). Data from different sources is often 
useful (Price, 1999). Contextual information is taken into 
account to guide the extraction of roads (Heipke et al., 2000). 
Roads can be detected in multi-resolution images (Baumgartner 
and Hinz, 2000), while Hinz and Baumgartner (2003) use 
context and scale-dependent models for extraction of urban 
roads in large-scale images. Several applications use map 
Information (Gerke et al., 2003). The map data is used either as 
approximation to start tracking or optimization process by 
Snakes (Bordes et al., 1997; Agouris et al., 2001), or to search 
for new roads (Vosselman and de Gunst, 1997). The road maps 
can be updated by map-image matching (Klang, 1998). The 
105 
st results with orthoimages in a test site in the Netherlands are 
existing approaches show individually that the use of road 
models and varying strategies for different types of scenes are 
promising. However, all the methods are based on relatively 
simplistic road models, and most of them make only insufficient 
use of a priori information, thus they are very sensitive to 
disturbances like cars, shadows or occlusions, and do not 
always provide good quality results. Furthermore, most 
approaches work in single 2D images, thus neglecting valuable 
information inherent in 3D processing. 
In this paper, we present a knowledge-based system for 
automatic extraction of 3D roads from stereo aerial images 
which integrates processing of color image data and existing 
digital spatial databases. The system has been developed within 
the project ATOMI (Automated reconstruction of Topographic 
Objects from aerial images using vectorized Map Information), 
in cooperation with the Swiss Federal Office of Topography 
(L*T), with aims to improve road centerlines from digitized 
1:25,000 topographic maps by fitting them to the real 
landscape, improving the planimetric accuracy to Im and 
providing height information with 1-2m accuracy (Eidenbenz et 
al., 2000). The usual input data include 1:16,000 scale color 
imagery, with 30cm focal length, and 6094/2096 forward/side 
overlap, scanned with 14 microns at a Zeiss SCAI. The other 
input data include: a nationwide DTM with 25m grid spacing 
and accuracy of 2-3/5-7m in lowland/Alps, the vectorized map 
data (VEC25) of 1:25,000 scale, and the raster map with its 6 
different layers. The VEC25 data have a RMS error of ca. 5- 
7.5m and a maximum one of ca. 12.5m, including 
generalization effects. They are topologically correct, but due to 
their partly automated extraction from maps, some errors exist. 
In addition, DSM data in the working area with 2m grid spacing 
was generated from stereo images using MATCH-T of INPHO. 
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