UL-Isomap based nonlinear dimensionality reduction for hyperspectral imagery classification

The paper proposes an upgraded landmark-Isometric mapping (UL-Isomap) method to solve the two problems of landmark selection and computational complexity in dimensionality reduction using landmark Isometric mapping (LIsomap) for hyperspectral imagery (HSI) classification. First, the vector quantizat...

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Bibliographic Details
Published in:ISPRS journal of photogrammetry and remote sensing 2014-03, Vol.89, p.25-36
Main Authors: Sun, Weiwei, Halevy, Avner, Benedetto, John J., Czaja, Wojciech, Liu, Chun, Wu, Hangbin, Shi, Beiqi, Li, Weiyue
Format: Article
Language:English
Subjects:
Algorithms
Animal, plant and microbial ecology
Applied geophysics
Biological and medical sciences
Classification
Computation
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
General aspects. Techniques
Hyperspectral imagery classification
Internal geophysics
Landmark selection
Landmarks
LIsomap
Mapping
Mathematical models
Nonlinear dimensionality reduction
Projection
Reduction
Teledetection and vegetation maps
UL-Isomap
Vector quantization
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Summary:The paper proposes an upgraded landmark-Isometric mapping (UL-Isomap) method to solve the two problems of landmark selection and computational complexity in dimensionality reduction using landmark Isometric mapping (LIsomap) for hyperspectral imagery (HSI) classification. First, the vector quantization method is introduced to select proper landmarks for HSI data. The approach considers the variations in local density of pixels in the spectral space. It locates the unique landmarks representing the geometric structures of HSI data. Then, random projections are used to reduce the bands of HSI data. After that, the new method incorporates the Recursive Lanczos Bisection (RLB) algorithm to construct the fast approximate k-nearest neighbor graph. The RLB algorithm accompanied with random projections improves the speed of neighbor searching in UL-Isomap. After constructing the geodesic distance graph between landmarks and all pixels, the method uses a fast randomized low-rank approximate method to speed up the eigenvalue decomposition of the inner-product matrix in multidimensional scaling. Manifold coordinates of landmarks are then computed. Manifold coordinates of non-landmarks are computed through the pseudo inverse transformation of landmark coordinates. Five experiments on two different HSI datasets are run to test the new UL-Isomap method. Experimental results show that UL-Isomap surpasses LIsomap, both in the overall classification accuracy (OCA) and in computational speed, with a speed over 5 times faster. Moreover, the UL-Isomap method, when compared against the Isometric mapping (Isomap) method, obtains only slightly lower OCAs.
ISSN:0924-2716
1872-8235
DOI:10.1016/j.isprsjprs.2013.12.003