半监督条件随机场的高光谱遥感图像分类

吴俊峰; 姜志国; 张浩鹏; 蔡博文; 罗鹏浩

doi:10.11834/jrs.20176121

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半监督条件随机场的高光谱遥感图像分类
Hyperspectral remote sensing image classification based on semi-supervised conditional random field
2017年21卷第4期页码：588-603
纸质出版日期： 2017-5 ，

录用日期： 2017-1-10
DOI： 10.11834/jrs.20176121

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吴俊峰, 姜志国, 张浩鹏, 蔡博文, 罗鹏浩. 2017. 半监督条件随机场的高光谱遥感图像分类. 遥感学报, 21(4): 588–603

Wu J F, Jiang Z G, Zhang H P, Cai B W and Luo P H. 2017. Hyperspectral remote sensing image classification based on semi-supervised conditional random field. Journal of Remote Sensing, 21(4): 588–603
吴俊峰, 姜志国, 张浩鹏, 蔡博文, 罗鹏浩. 2017. 半监督条件随机场的高光谱遥感图像分类. 遥感学报, 21(4): 588–603 DOI： 10.11834/jrs.20176121.

Wu J F, Jiang Z G, Zhang H P, Cai B W and Luo P H. 2017. Hyperspectral remote sensing image classification based on semi-supervised conditional random field. Journal of Remote Sensing, 21(4): 588–603 DOI： 10.11834/jrs.20176121.

摘要

善于捕捉空间信息的条件随机场模型虽然已被应用于高光谱遥感图像分类，但条件随机场的性能受到了标注训练样本数量的制约。为解决上述问题，本文提出了一种半监督条件随机场模型用于高光谱遥感图像分类。在该模型中，首先，利用空间-光谱拉普拉斯支持向量机定义关联势函数，以利用未标注样本中包含的信息获取样本类别概率；然后，在交互势函数中嵌入未标注的空间邻域样本，以充分利用空间信息实现对样本类别概率的修正；最后，采用分布式学习策略和平均场完成半监督条件随机场的训练和推断。本文在两个公开的高光谱数据集(Indian Pines数据集，Pavia University数据集)上进行了实验。实验结果表明Kappa系数提升3.94%。

Abstract

Hyperspectral remote sensing image classification is one of the enormous challenges in the field of applied remote sensing. Traditionally

supervised methods

such as Support Vector Machine (SVM)

dominate this area. Especially

Conditional Random Field (CRF) excels in solving this kind of problem in most cases

due to its prominent ability in formulating the spatial relationship. However

CRF suffers from the availability of large amount of labeled samples

which is labor- and time-consuming to obtain in practice. The accuracy tends to decrease dramatically once labeled samples are not adequate or informative enough. To solve the above problem

a semi-supervised CRF model is proposed in this paper. In the semi-supervised CRF model

the association potential is defined as the spatio-spectral Laplacian Support Vector Machine (ssLapSVM)

to exploit the information contained in the unlabeled samples. And the multi-class probability for each sample is obtained by the ssLapSVM with the one-versus-one scheme. In addition

the interaction potential is newly designed by introducing a weight into the Potts model. Note that

in the classification of hyperspectral remote sensing with limited labeled samples

unlabeled neighbors of one labeled samples may often exist. Thus

the labels of these unlabeled neighbors are assigned based on maximum probability acquired by the ssLapSVM

and use the maximum probability as a weight. In the training phrase

the optimal parameters in the association potential

i.e. ssLapSVM

is firstly trained

and then the whole semi-supervised CRF model is trained to get the optimal parameters in the interaction potential. In the inference phrase

mean-field is adopted to find the optimal label configuration over the testing set. The performance of the proposed semi-supervised CRF model is evaluated on two well-known benchmarks

i.e. Indian Pines scene and Pavia University scene. The objective comparison experiments are carried out among some state-of-the-art methods in terms of kappa statistic. On both Indian Pines (IP) scene and Pavia University (PU) scene

the proposed method can exhibits completely better performance

improve by 4.94%@IP and 3.28%@PU

respectively. In addition

the kappa of the proposed method rises with the increase of the number of labeled training samples. And in most cases

the proposed method shows better performance than other contrast methods under the case of the same training labeled samples. With the increase of trade-off coefficient

kappa statistic rise first and tend to steady

and then degrades dramatically. The proposed method also shows better performance when the larger scope of samples participating in the construction of the interaction potential. In this paper

we have developed a semi-supervised CRF to address the problem of hyperspectral image classification. Our method can effectively improve the kappa statistic under limited labeled-training set by newly designed association and interaction potential. Experiments conducted on two well-known hyperspectral datasets demonstrate the effectiveness of the proposed method. And when compared to related semi-supervised algorithms

the proposed method shows its superiority.

关键词

高光谱遥感分类半监督条件随机场

Keywords

hyperspectralremote sensingclassificationsemi-supervisedconditional random field

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