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Cluster Computing
Erschienen in: Cluster Computing 2/2017

11.04.2017

Two-stage plant species recognition by local mean clustering and Weighted sparse representation classification

verfasst von: Shanwen Zhang, Harry Wang, Wenzhun Huang

Erschienen in: Cluster Computing | Ausgabe 2/2017

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Abstract

Aiming at the difficult problem of plant leaf recognition on the large-scale database, a two-stage local similarity based classification learning (LSCL) method is proposed by combining local mean-based clustering (LMC) method and local sparse representation based classification (SRC) (LWSRC). In the first stage, LMC is applied to coarsely classifying the test sample. k nearest neighbors of the test sample, as a neighbor subset, is selected from each training class, then the local geometric center of each class is calculated. S candidate neighbor subsets of the test sample are determined with the first S smallest distances between the test sample and each local geometric center. In the second stage, LWSRC is proposed to approximately represent the test sample through a linear weighted sum of all \(k\times S\) samples of the S candidate neighbor subsets. Experimental results on the leaf image database demonstrate that the proposed method not only has a high accuracy and low time cost, but also can be clearly interpreted.
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Literatur
1.
Valentini, G.L., Lassonde, W., Khan, S.U., et al.: An overview of energy efficiency techniques in cluster computing systems. Cluster Comput. 16(1), 3–15 (2013)CrossRef
2.
3.
Yang, J., Zhang, L., Yang, J.Y., Zhang, D.: From classifiers to discriminators: a nearest neighbor rule induced discriminant analysis. Pattern Recognit. 44, 1387–1402 (2011)CrossRefMATH
4.
Kang, S.H., Kim, K.J.: A feature selection approach to find optimal feature subsets for the network intrusion detection system. Cluster Comput. 19(1), 325–333 (2016)CrossRef
5.
Jang, S.W., Jung, M.: Robust detection of mosaic regions in visual image data. Cluster Comput. 19(4), 2285–2293 (2016)CrossRef
6.
Zhao, L., Jiang, L., Dong, X.: Supervised feature selection method via potential value estimation. Cluster Comput. 19(4), 2039–2049 (2016)CrossRef
7.
Martinez, A.M., Kak, A.C.: PCA versus LDA. IEEE Trans. Pattern Anal. Mach. Intell. 23, 228–233 (2001)CrossRef
8.
Wright, J., Yang, A.Y., Ganesh, A., et al.: Robust face recognition via sparse representation. IEEE Trans. Pattern Anal. Mach. Intell. 31, 210–227 (2009)CrossRef
9.
Wright, J., Ma, Y., Mairal, J., et al.: Sparse representation for computer vision and pattern recognition. Proc. IEEE 98, 1031–1044 (2010)CrossRef
10.
Deng, W., Hu, J., Guo, J.: Extended SRC: under sampled face recognition via intraclass variant dictionary. IEEE Trans. Pattern Anal. Mach. Intell. 34(9), 1864–1870 (2012)CrossRef
11.
Yang, J., Zhang, L., Xu, Y., et al.: Beyond sparsity: the role of L1-optimizerin pattern classification. Pattern Recognit. 45(3), 1104–1118 (2012)CrossRefMATH
12.
Guo, S., Ruan, Q., Miao, Z.: Similarity weighted sparse representation for classification. In: International conference on pattern recognition (ICPR), pp. 1241–1244 (2012)
13.
Lu, C.Y., Min, H., Gui, J., et al.: Face recognition via weighted sparse representation. J. Vis. Commun. Image Represent. 24(2), 111–116 (2013)CrossRef
14.
Li, C., Guo, J., Zhang, H.G.: Local sparse representation based classification. In: International conference on pattern recognition, pp. 649-653 (2010)
15.
Zhang, S.W., Lei, Y.K., Wu, Y.H.: Semi-supervised locally discriminant projection for classification and recognition. Knowl.-Based Syst. 24(2), 341–346 (2011)CrossRef
16.
Zhang, S.W., Lei, Y.K.: Modified locally linear discriminant embedding for plant leaf recognition. Neurocomputing 74(14–15), 2284–2290 (2011)CrossRef
17.
Zhao, C., Chan, S.F., Cham, W.K., et al.: Plant identification using leaf shapes—a pattern counting approach. Pattern Recognit. 48(10), 3203–3215 (2015)CrossRef
18.
Munisami, Trishen, Ramsurn, Mahess, Kishnah, Somveer, et al.: Plant leaf recognition using shape features and colour histogram with K-nearest neighbour classifiers. Proc. Comput. Sci. 58, 740–747 (2015)CrossRef
19.
Ahmed, N., UG, Khan, Asif, S.: An automatic leaf based plant identification system. Sci.Int. 28(1), 427–430 (2016)
20.
Zhang, Shanwen, Lei, YingKe, Zhang, Chuanlei, et al.: Semi-supervised orthogonal discriminant projection for plant leaf classification. Pattern Anal. Appl. 19(4), 953–961 (2016)MathSciNetCrossRef
21.
Munisami, T., Ramsurn, M., Kishnah, S., et al.: Plant leaf recognition using shape features and colour histogram with K-nearest neighbour classifiers. Proc. Comput. Sci. 58, 740–747 (2015)
22.
Chaki, J., Parekh, R., Bhattacharya, S.: Plant leaf recognition using texture and shape features with neural classifiers. Pattern Recognit. Lett. 58, 61–68 (2015)CrossRef
23.
Hsiao, J.K., Kang, L.W., Chang, C.L., et al.: Learning sparse representation for leaf image recognition. In: IEEE International Conference on Consumer Electronics. IEEE, pp. 209–210 (2014)
24.
Jin, Taisong, Hou, Xueliang, Li, Pifan, et al.: A novel method of automatic plant species identification using sparse representation of leaf tooth features. PLoS ONE 10(10), 1–20 (2015)CrossRef
25.
He, R., Hu, B.G., Zheng, W.S., et al.: Two-stage sparse representation for robust recognition on large-scale database. In: Proceedings of the Twenty-Fourth AAAI Conference on Artificial Intelligence (AAAI-10), pp. 475–480 (2014)
26.
Yong, Xu, Zhu, Qi, Fan, Zizhu, et al.: Using the idea of the sparse representation to perform coarse-to-fine face recognition. Inf. Sci. 238, 138–148 (2013)
27.
Elhamifar, E., Vidal, R.: Sparse subspace clustering: algorithm, theory, and applications. IEEE T Pattern Anal. Mach. Intell. 35(11), 2765–2781 (2013)CrossRef
28.
Kim, S.J., Koh, K., Lustig, M., et al.: A method for large-scale \(l_{1}\)-regularized least squares. IEEE J. Sel. Top. Signal Process. 1(4), 606–617 (2007)CrossRef
29.
Canny, J.A.: A computational approach to edge detection. IEEE Trans. Pattern Anal. Mach. Intell. 8(6), 679–698 (1986)CrossRef
Metadaten
Titel
Two-stage plant species recognition by local mean clustering and Weighted sparse representation classification
verfasst von
Shanwen Zhang
Harry Wang
Wenzhun Huang
Publikationsdatum
11.04.2017
Verlag
Springer US
Erschienen in
Cluster Computing / Ausgabe 2/2017
Print ISSN: 1386-7857
Elektronische ISSN: 1573-7543
DOI
https://doi.org/10.1007/s10586-017-0859-7

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