inbul 2004 
  
    
  
ACCURACY ANALYSIS AND SURFACE MAPPING USING SPOT 5 STEREO DATA 
Hannes Raggam 
Joanneum Research, Institute of Digital Image Processing 
Wastiangasse 6, A-8010 Graz, Austria 
hannes.raggam@joanneum.at 
Commission I, WG I/2 
Key Words: Spot 5, Sensor Model, Accuracy Analysis, Image Matching, Elevation Model 
ABSTRACT 
On the Spot 5 satellite stereo data can be acquired simultaneously from the HRS (high resolution stereoscopic) instrument, which 
comprises 2 cameras looking forward and backward, respectively, at an off-nadir angle of +20 degrees. Enhanced along-track pixel 
resolution of 5 meters shall further assure a high accuracy with respect to 3D data extraction. In this concern, an HRS study team 
was installed and specific test sites designated in order to validate the geometric performance of Spot 5 HRS stereo data. This paper 
summarizes the results which have been achieved from the validation activities of the Institute of Digital Image Processing. The 
investigations were carried out using a test data set acquired over the city of Barcelona. Study areas showing different topographic 
characteristics have been investigated. Beside pure HRS stereo data, a glimpse has been further made onto the joint use of the HRS 
stereo data and a supermode THR image, which is basically a nadir scene with a pixel size of 2.5 meters. | 
1. INTRODUCTION 
In order to continue and strengthen the traditional Spot 
stereoscopic potential, the HRS instrument was realized on Spot 
5. allowing the acquisition of in-track stereo data during the 
same overflight. The HRS instrument comprises two CCD 
cameras looking forward and backward, respectively, at an off- 
nadir angle of +20 degrees, allowing stereo data capture at a 
time interval of about 90 seconds (Gleyzes et al., 2003). The 
resolution of the stereo data is 5 meters along and 10 meters 
across-track. Thus, the performance of image matching applied 
to such data is not degraded due to temporal changes in the 
scenes. 
An HRS assessment program has been established, involving an 
expert team as well as a number of designated test sites in order 
to verify mapping accuracies being predicted for Spot 5 HRS 
stereo data. Following the objectives of this program, this paper 
is devoted to the analysis of the topographic mapping potential 
of Spot 5 HRS stereo data. The following issues are specifically 
addressed: 
e Geometric modelling of HRS stereo data, including 
utilization of given orbital and imaging parameters 
e Analysis of a-priori 2-dimensional location accuracy for 
individual scenes as well as 3-dimensional location 
accuracy of stereo models using control points 
e Optimisation of sensor models utilizing control point 
measurements and least squares parameter adjustment 
e Discussion of the performance of image matching 
techniques being applied to Spot HRS as well as multi- 
sensor THR/HRS stereo data 
e Extraction of surface models from HRS as well as multi- 
sensor THR/HRS stereo data 
e Accuracy analysis of extracted elevation models through 
comparison with reference data 
For the study the Remote sensing Software package Graz (RSG, 
Joanneum Research, 2003) was used. This is designed for 
geometric processing of remote sensing images, including the 
aspects of geometric sensor modelling, block adjustment, stereo 
image matching, and surface model generation. At the Institute, 
Spot stereo mapping using analogue Spot stereo pairs and an 
analytical plotter was already an issue in the eighties (Raggam 
et al, 1989). Also the aspects of multi-sensor stereo data 
utilization as well as validation of stereo mapping potential 
(Raggam et al., 1990 and 1996) have been a matter of previous 
research. 
2. TEST DATA 
The city of Barcelona as well as the areas north(-west) of it 
were selected as a primary test site for the HRS assessment 
program. The related test data set was provided for this study 
and comprises the following image and reference data: 
e a Spot HRS stereo pair with a nominal pixel size of 5 
meters along- and 10 meters across-track; 
e a THR supermode product with a nominal pixel size of 
2.5 meters; 
e a digital elevation model with a mesh width of 15 meters; 
e ortho photo mosaics for 8 detailed study areas with a pixel 
size of 0.5 meters. 
Some 15 high precision control points were measured for each 
of the detailed study areas from the respective ortho photo 
mosaics, resulting in an overall pool of 116 points to be used 
for sensor modelling and accuracy analyses. 
3. SENSOR MODÉLLING 
In general, rather detailed and precise information is provided 
for the sensor model of a Spot 5 image, comprising orbital data 
as well as attitude parameters of the instrument (Spot Image, 
2002). This justifies the feasibility to generate value-added 
products: with high accuracy. Geolocation accuracies in the 
range of 15 meters in planimetry and 10 meters in height are 
anticipated with respect to HRS input images without using 
control points for optimisation (Spot Magazine, 2003).