Abstract
Orthogonal subspace projection (OSP) developed by Harsanyi and Chang (IEEE Transactions on Geoscience and Remote Sensing 32:779–785, 1994) (see Hyperspectral image: spectral techniques for detection and classification, Kluwer Academic Publishers, New York, 2003; Hyperspectral data processing: algorithm design and analysis, Wiley, Hoboken, 2013) has found its potential in many hyperspectral data exploitation applications. It works in two stages: an OSP-based projector to annihilate undesired signal sources in the first stage, to improve background suppression so as to increase target detectability, followed by a matched filter in the second stage, to extract the desired signal source for target enhancement. However, for OSP to be effective it assumes that the signal sources are provided a priori. As a result, OSP can only be used as a supervised algorithm. In many real-world applications, there are many unknown signal sources that can be revealed by hyperspectral imaging sensors. It is highly desirable to extend OSP to an unsupervised version, called unsupervised OSP (UOSP) developed by Wang et al. (Optical Engineering 41:1546–1557, 2002), where the signal sources used for OSP can be found in an unsupervised manner. An issue arising in UOSP is how to determine the number of such found unsupervised signal sources, which must be known in advance. This chapter further extends UOSP to progressive OSP (P-OSP) so that P-OSP can not only generate a growing set of new unknown signal sources one at a time progressively but can also determine the number of unknown signal sources to be generated while OSP processing is taking place. Since the unknown signal sources generated by P-OSP remain unchanged after they are generated, OSP should be able to take advantage of it without reprocessing these signal sources. This leads to a new development of a recursive version of OSP, called recursive hyperspectral sample processing of OSP (RHSP-OSP).
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Chang, CI. (2017). Recursive Hyperspectral Sample Processing of Orthogonal Subspace Projection. In: Real-Time Recursive Hyperspectral Sample and Band Processing. Springer, Cham. https://doi.org/10.1007/978-3-319-45171-8_8
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DOI: https://doi.org/10.1007/978-3-319-45171-8_8
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