Abstract
We present a new method for image feature-extraction which is based on representing an image by a finite-dimensional vector of distances that measure how different the image is from a set of image prototypes. We use the recently introduced Universal Image Distance (UID) [1] to compare the similarity between an image and a prototype image. The advantage in using the UID is the fact that no domain knowledge nor any image analysis need to be done. Each image is represented by a finite dimensional feature vector whose components are the UID values between the image and a finite set of image prototypes from each of the feature categories. The method is automatic since once the user selects the prototype images, the feature vectors are automatically calculated without the need to do any image analysis. The prototype images can be of different size, in particular, different than the image size. Based on a collection of such cases any supervised or unsupervised learning algorithm can be used to train and produce an image classifier or image cluster analysis. In this paper we present the image feature-extraction method and use it on several supervised and unsupervised learning experiments for satellite image data. The feature-extraction method is scalable and is easily implementable on multi-core computing resources.
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References
Chester, U., Ratsaby, J.: Universal distance measure for images. In: 2012 IEEE 27th Convention of Electrical Electronics Engineers in Israel (IEEEI), pp. 1–4 (November 2012)
Canty, M.J.: Image Analysis, Classification and Change Detection in Remote Sensing: With Algorithms for Envi/Idl. CRC/Taylor & Francis (2007)
Lillesand, T.M., Kiefer, R.W., Chipman, J.W.: Remote sensing and image interpretation. John Wiley & Sons (2008)
Sayood, K., Otu, H.H.: A new sequence distance measure for phylogenetic tree construction. Bioinformatics 19(16), 2122–2130 (2003)
Ziv, J., Lempel, A.: On the complexity of finite sequences. IEEE Transactions on Information Theory 22(3), 75–81 (1976)
Ratsaby, J., Sirota, V.: Fpga-based data compressor based on prediction by partial matching. In: 2012 IEEE 27th Convention of Electrical Electronics Engineers in Israel (IEEEI), pp. 1–5 (November 2012)
Ratsaby, J., Zavielov, D.: An fpga-based pattern classifier using data compression. In: Proc. of 26th IEEE Convention of Electrical and Electronics Engineers, Israel, Eilat, November 17-20, pp. 320–324 (2010)
Kaspi, G., Ratsaby, J.: Parallel processing algorithm for Bayesian network inference. In: 2012 IEEE 27th Convention of Electrical Electronics Engineers in Israel (IEEEI), pp. 1–5 (November 2012)
Cilibrasi, R., Vitanyi, P.: Clustering by compression. IEEE Transactions on Information Theory 51(4), 1523–1545 (2005)
Deza, M., Deza, E.: Encyclopedia of Distances. Series in Computer Science, vol. 15. Springer (2009)
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Chester, U., Ratsaby, J. (2013). Machine Learning for Image Classification and Clustering Using a Universal Distance Measure. In: Brisaboa, N., Pedreira, O., Zezula, P. (eds) Similarity Search and Applications. SISAP 2013. Lecture Notes in Computer Science, vol 8199. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-41062-8_7
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DOI: https://doi.org/10.1007/978-3-642-41062-8_7
Publisher Name: Springer, Berlin, Heidelberg
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