anbul 2004
lages using
ation feed-
plying the
competitive
| multilayer
re shown in
competitive
competitive
'd multilayer
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
S. CONCLUSIONS
The advantages, stable training results and no requirement of a
priori knowledge provided by the simple competitive learning, and
optimization for preventing fixation to the local minima provided
by simulated annealing, are integrated in this modified model.
Like most. competitive learning models, this modified model can
be applied in different areas such as computer vision, pattern
classification, industrial product inspection, etc. In this study, the
results of the proposed combined technique are compared with the
results of the backpropagation feed-forward neural networks used
to classify the same image. The one-hidden layer feed-forward
network trained with backpropagation algorithm was developed.
The preliminary results showed that the modified competitive
learning networks are promising. The time complexity and the
overall classification accuracy assessment will be performed in
our experiments.
REFERENCES
1. Thomas, I. L., Benning, V. M., and Ching, N. P., 1987.
Classification of Remotely-Sensed Images, Adam Hilger.
2. Schowengerdt, R. A., 1983. Techniques for Image
Processing and Classification in Remote Sensing,
Academic Press, Inc.
3. Lillesand, T. M. and Kiefer, R. W., 1987. Remote Sensing
and Image Interpretation, John Wiley & Sons, Inc.
4. Bishop C.M. 1995. Neural Networks for Pattern
Recognition, Oxford.
5. Hertz, J., Krogh A., and Palmer, R., 1991. Introduction to
the Theory of Neural Computation, Addison-Wesley.
6. Lippmann, R. P., 1989. Pattern Recognition Using Neural
Networks, /EEE Comm. Mag., 27 (11), pp. 47-63.
7. Ahalt, S. C., Krishnamurphy, A. K. Chen, and Melton, D.
E., 1990. Competitive Learning Algorithms for Vector
Quantization, Neural Networks, 3, pp. 277-290.
8. Hung, C. C,, 1993. Competitive Learning Networks for
Unsupervised Training, Int. J. Remote Sensing, Vol. 14,
No. 12, pp. 2411-2415.
9. Atur, V. Hung, C.C., and Coleman, T.L., 1999. An
Artificial Neural Network for Classifying and Predicting
Soil Moisture and Temperature Using Levenberg-
Marquardt Algorithm, Proceedings of IEEE Southeastcon
'99, Lexington, KY, pp. 10-13.
10. D. L. Civco and Y. Wang, 1994. Classification of
Multispectral, Multitemporal, Multisource Spatial Data
Using Artificial Neural Networks, Proceedings of
ASPRS/ACSM Annual Convention & Exposition, Reno,
Nevada, pp. 123-133.
I1. T. A. Warner and M. Shank, 1997. An Evaluation of the
Potential for Fuzzy Classification of Multispectral Data
Using Artificial Neural Networks, Photogrammetric
Engineering & Remote Sensing, Vol. 63, No. 11, pp. 1285-
1294.
12. G. M. Foody and M. K. Arora, 1997. An Evaluation of
Some Factors Affecting the Accuracy of Classification by
an Artificial Neural Network, Int. J. Remote Sensing, Vol.
18, No. 4, pp. 799-810.
13. Alabas, C., Atiparmak, F., and Dengiz, B, 1999. The
Optimization of Number of Kanbans with Genetic
Algorithms, Simulated Annealing, and Tabu Search, Gazi
University, Department of Industrial Engineering.
14. Battiti, R., and Tecchiolli, G., 1992. Simulated Annealing
and Tabu Search in the Long Run: A Comparison on QAP
Tasks, ORSA Journal on Computing, 6 , pp. 126-140.
107
ACKNOWLEDGEMENTS
The authors, Hung and Coleman, wish to acknowledge the
support of the Center for Hydrology, Soil Climatology, and
Remote Sensing (HSCaRS) staff. Contribution by the HSCaRS
Research Center, Department of Plant and Soil Sciences, the
Agricultural Experiment Station, Alabama A&M University,
Normal, AL 35762. Journal no. 538. Research supported by
NAG5-10721 from the National Aeronautics and Space
Administration (NASA), Washington, DC, USA. Any use of
trade, product, or firm names is for descriptive purposes only
and does not imply endorsement by the U.S. Government.
