International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004
4. CONCLUSIONS AND FUTURE WORKS
This study developed a method for extracting feature change
using time series analysis on multitemporal JERS-1/SAR
images. The method consisted of two steps. In the first step, the
stationarity of land surface change was extracted as a change
process model, and in the second step, the stationarity of the
newly acquired data was evaluated by comparing it with the
change process model. Also the practicality of the method was
examined from the view point of the "time inconsistency"
problem. The results showed satisfactory values for change
detection. The method is expected to provide an effective
solution to “time inconsistency” problem.
In addition, insufficient results were observed in the developed
method, which mostly stemmed from the limitation of using a
single type of data. The goal of this study was to develop a
method for automated change detection in near real-time which
was capable of practical use. Improvement in the accuracy of
the change detection in multiple aspects (e.g. spatial, temporal,
thematic) will be conducted in the future through assimilating
additional techniques such as construction of a detailed base
data, use of optical sensor imagery, and development of spatial
analysis algorithms.
Constructing the detailed base data
Although the method developed in this study was designed to
detect change, it is still difficult to determine thematic aspects
of the change. This limitation mainly stems from the fact that
the method is relying on a single type of data (i.e. SAR image).
Therefore, integration of other spatial data will be conducted to
improve the interpretation of the change and determine thematic
aspects. The base data will be constructed to archive the
thematic information of the intended area to identify the
thematic aspects “before” the change. The base data will
include land cover data, land use data and topographic data. The
spatial resolution will be 1-10m. Higher resolution than SAR
data will be required for the base data. High resolution optical
images (e. g. IKONOS, aerial photograph) and laser profiler
data will be used to satisfy this requirement. The construction
of the base data may enable the estimation of stationary changes
itself. The method of integrating this estimation into the time
series analysis of multitemporal SAR images will also be
considered as a future work.
Use of the optical sensor image (not periodical)
Additionally, the utilization of optical sensor images will be
conducted to enable the identification of thematic aspects
“after” the change. It is true that the periodicity of optical
sensor images is poor because of the effect of cloud cover. Even
so, optical images contain very rich information and they will
be useful for understanding thematic information about the land
surface. There are several studies of integrating multitemporal
SAR images and optical sensor images (e.g. Michelson er al,
2000; Le ef al., 2000; Lombardo et al., 2003).
Integrating the result of spatial analysis into time series
analysis
Most of the conventional time series analysis is done by pixel
based analysis, which does not consider the relations among
surrounding pixels. The pixel values of SAR images are mostly
reflecting the shape of the terrain (and some of roughness and
material). The classification result may improve if each pixel is
Un
n3
understood through the segmented features. The information of
the relation among pixels and its corresponding segment may be
used as a parameter to improve the precision of the time series
analysis on multitemporal SAR images. The segmentation
technique used for the high-resolution satellite image (Baatz
and Schape, 1999) is also planned to be used.
5. REFERENCES
Baatz, M.,and Schape, A., 1999. Object-Oriented and Multi-
Scale Image Analysis in Semantic Networks. Proc. of the 2nd
International Symposium on Operationalizaion of Remote
Sensing August 1 6" -20”, Netherlands, http://www definiens-
imaging.com/documents/publications/itc 1999.pdf, (accessed 27
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Bruniquel, J. and Lopés, A. 1997. Multi-variate optimal
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Remote Sensing, 18(3), pp. 603—627.
Ciuc, M., Bolon, P., Trouve, E., Buzuloiu, V. and Rudant, J.P.,
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Coltuc, D., Trouvé, E., Bujor, F., Classeau, N. and Rudant J. P.,
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Lombardo, P., Oliver, C. J., Macri Pellizzeri, T. and Meloni, M.,
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Michelson, D. B., Liljeberg, M. and Pilesjó, P., 2000.
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Saito, K., Koyama, A., Yoneyama, K., Sawada, Y. and Ohtomo,
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