15 
58/ 
| 
| S 
05 
85 
  
  
uoZo 
)etter 
and 
e not 
tems. 
anual 
igital 
rs are 
"user, 
1atic 
ntrol 
hundred thousands of points. Both systems provide certain 
indications of the matching quality and means to edit the data. 
DPW 770 stores in a file a quality code from 0 to 100. Points with 
code less than 33 are considered unreliable and are mostly 
interpolated from other good points (see Figure 5). In a test all 
these points (11.296) were deleted and the rest was interpolated in 
a 5 m regular grid of the manual measurements for accuracy 
analysis (see Tables 1 and 2). Only 39% of the deleted points (i.e. 
ca. 4% of all points) were in reality blunders (error > 3 m). The 
resulting RMS was much lower and the big blunders were 
severely reduced. Thus, operationally all low quality code points 
could be deleted and manual measurements could be made to fill- 
in the resulting DTM gaps. Still, the remaining blunders (» 3 m) 
are 4% (ca. 15,000 points) and not indicated by the quality code. 
VirtuoZo divides the points in three quality classes that are 
displayed on the screen with different colours. The worst class 
includes points that have been interpolated. Again blunders are 
included in the "reliable" classes and additionally this quality 
code is not saved in any file for user access. So, the quality 
measures provided by the systems must be made more reliable 
and additional diagnostic tools should be used. However, DPW 
led after deletion of the low quality code points to 2.5% less 
blunders than VirtuoZo, which means less editing time or higher 
DTM accuracy, if no manual editing is performed. 
Both systems provide tools to indicate errors (contours, 3D 
views, overlay of contours on orthoimages or in the stereomodel) 
and means to edit the data pointwise or regionwise, but since the 
blunders are not reliably highlighted, the user must control the 
whole data set. The editing tools should, at least partially, used 
before matching (e.g. exclusion of textureless areas, water bodies 
etc.). Thus, time is saved and the given information can be used 
in matching. Nevertheless, automatic DTM generation does have 
certain advantages over manual measurements like processing 
speed (over 100 points per sec) and the possibility to derive a 
very dense DTM. This is significant because it leads to a much 
more accurate terrain representation (implicit measurement of 
breaklines, form lines etc.). 
5. COMPARISON BETWEEN DIGITAL AND 
ANALYTICAL SYSTEMS - CONCLUSIONS 
Compared to analytical plotters digital photogrammetric systems 
show following characteristics. The price of digital 
photogrammetric systems is similar to much lower that the one of 
the analytical plotters. They also offer additional functionality 
like geometric sensor models for satellite imagery, image 
rectification, orthoimage and orthoimage map generation, 
mosaicking, 3D perspective views, animation and flyovers, 
image processing, support of many input/output raster and vector 
data formats etc. The cheaper systems however do not have all 
these functions. VirtuoZo does not have for example 
triangulation, mapping software (except simple feature 
digitisation with an attribute code using an extra package), 
orthoimage map generation (except of overlay of contours on 
orthoimages), animation and flyovers, and image rectification. 
Deficiencies that were observed during this project include the 
following: 
* The systems are not open and flexible enough. The content 
and format of some files is unknown (e.g. metadata image 
files with orientation etc. in DPW). Intermediate results like 
109 
pixel and photo coordinates can not be accessed. The user is 
bound to the standard streamlined processing flow, so limited 
operations (like import of a foreign orthoimage and creation 
of an orthoimage map in DPW) are not possible or very 
cumbersome. 
VirtuoZo does not provide some common input/output 
formats. Both systems input uncommon image formats (raw, 
VITEC) which leads to an increase of required disk space 
and processing delays. 
* The documentation, especially of VirtuoZo, is poor and 
explains very little on what exactly and how it is done. 
Fully fledged systems like the DPW 770 are quite complicated to 
handle and require significant training, whereby VirtuoZo is 
easy-to-use and its user interface quite intuitive. The size of 
digital data is still a problem. Large images can only be processed 
a few at a time or not at all. Many processes appear as a blackbox 
to the user, case which is not always desirable especially in 
education and research. Digital photogrammetric systems have to 
a large extent transferred the working mode of the analytical 
plotters in the digital domain. Thus, for example they concentrate 
on processing of stereo images without exploiting the existing 
possibility of simultaneous processing of multiple images in 
order to improve accuracy and reliability of the results 
(especially for DTM generation and automated feature 
extraction). Functionality should be extended (semi-automated 
feature extraction, monoplotting, structuring of measurements, 
import and integration of other data, data/metadata storage and 
management, GIS functionality for data analysis). A comparison 
between DPW 770 and VirtuoZo shows that both systems have 
their strong and weak points. DPW 770 has more functions, but is 
also more expensive and complicated to use. VirtuoZo on the 
other hand offers the advantage of user-friendliness and low 
price. It can certainly be used for DTM and orthoimage 
generation, but it is not suitable for aerial triangulation or 
mapping. Even with their present weaknesses digital 
photogrammetric systems offer significant advantages in 
comparison to analytical plotters and can be fully employed in 
research and professional practise. The expected improvement of 
their performance, especially in the algorithms and the user 
interface, will expand their use even further. 
Acknowledgements 
The authors would like to thank A. Kääb and H. Bósch, 
Glaciology, ETHZ for proposing the glacier project, supplying 
data and helping in the recognition of the control points, as well 
as the students A. Bleisch and C. Räuftlin for their engaged work 
on this project within their “Praktikum” in photogrammetry. 
References 
Miller, S.B., Thiede, J. E., Walker, A. S., 1992. A Line of High 
Performance Digital Photogrammetric Workstations - The 
Synergy of General Dynamics, Helava Associates, and Leica. 
In: International Archives of Photogrammetry and Remote 
Sensing, Vol. 29, Part B2, pp. 87 - 94. 
Zhang, J., Zhang, Z., Wu, X., Wang, Z., Qiu, T., Chao, H., 1994. 
A Photogrammetric Workstation from WTUSM. In: 
International Archives of Photogrammetry and Remote 
Sensing, Vol. 30, Part 3/2, pp. 939 - 944. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996