Abstract
Today, more and more deep learning frameworks are being applied to hyperspectral image classification tasks and have achieved great results. However, such approaches are still hampered by long training times. Traditional spectral–spatial hyperspectral image classification only utilizes spectral features at the pixel level, without considering the correlation between local spectral signatures. Our article has tested a novel hyperspectral image classification pattern, using random-patches convolution and local covariance (RPCC). The RPCC is an effective two-branch method that, on the one hand, obtains a specified number of convolution kernels from the image space through a random strategy and, on the other hand, constructs a covariance matrix between different spectral bands by clustering local neighboring pixels. In our method, the spatial features come from multi-scale and multi-level convolutional layers. The spectral features represent the correlations between different bands. We use the support vector machine as well as spectral and spatial fusion matrices to obtain classification results. Through experiments, RPCC is tested with five excellent methods on three public data-sets. Quantitative and qualitative evaluation indicators indicate that the accuracy of our RPCC method can match or exceed the current state-of-the-art methods.
Highlights
There are more and more remote sensing applications based on hyperspectral images (HSIs)
The obtained multi-scale spatial information and spectral covariance matrix are merged into spectral-spatial features
Parameters for the proposed random patches convolution and local covariance-based Our method was compared with RAW [59], maximum noise fraction (MNF) [21], and the five state-of-the-art HSIs clcalsassisfiifciactaitoionnm(RetPhCoCd)s,mSeMthLoRd-.SpTV [60], Gabor-based [33], EMAP [35], LMRC [29], and RPNet [49], Remoatne Sdenas.d2e0t1a9i,le1d1, ax;ndaolyi:sFiOs RwPaEsEcRarRrEieVdIEoWut using the quantitative and quawlitwawtiv.medepxi.pcoemrim/joeunrntaall/rreemsuolttess.ensing
Summary
There are more and more remote sensing applications based on hyperspectral images (HSIs). The latest hyperspectral sensors can obtain hundreds of spectral channel data points in high spatial resolution [1]. Rich spectral-spatial information is widely used in HSIs for scene recognition [2], regional variation of urban areas [3], and classification of features [4,5,6]. Classification of HSIs for ground objects can be widely used in precision agriculture [7], urban mapping [8], and environmental monitoring [9]. HSI classification uses a small number of manual tags to indicate the category label of each pixel [10]. If the label data are very limited, more spectral data will reduce the accuracy of classification [12]
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