Abstract

Filter is a well-known tool for noise reduction of very high spatial resolution (VHR) remote sensing images. However, a single-scale filter usually demonstrates limitations in covering various targets with different sizes and shapes in a given image scene. A novel method called multi-scale filter profile (MFP)-based framework (MFPF) is introduced in this study to improve the classification performance of a remote sensing image of VHR and address the aforementioned problem. First, an adaptive filter is extended with a series of parameters for MFP construction. Then, a layer-stacking technique is used to concatenate the MPFs and all the features into a stacked vector. Afterward, principal component analysis, a classical descending dimension algorithm, is performed on the fused profiles to reduce the redundancy of the stacked vector. Finally, the spatial adaptive region of each filter in the MFPs is used for post-processing of the obtained initial classification map through a supervised classifier. This process aims to revise the initial classification map and generate a final classification map. Experimental results performed on the three real VHR remote sensing images demonstrate the effectiveness of the proposed MFPF in comparison with the state-of-the-art methods. Hard-tuning parameters are unnecessary in the application of the proposed approach. Thus, such a method can be conveniently applied in real applications.

Highlights

  • A remote sensing image with very high resolution (VHR) has an improved visual appearance over imagery of conventional resolution [1]

  • The proposed MFPF is compared with the classification of raw and filtered images based on mean filtering (MF), median filtering (MedF), and modified mean filter (MMF) [23]

  • The classification performance in different filters shows that the proposed MFPF can achieve the optimal accuracy for most kinds of specific classes

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Summary

Introduction

A remote sensing image with very high resolution (VHR) has an improved visual appearance over imagery of conventional resolution [1]. The remote sensing image with VHR can capture and describe the details of ground targets in terms of size and shape. Such imagery plays an important role in various practical applications, such as land cover classification [2,3,4], target recognition [5,6,7], and change detection [8,9]. Quick Bird satellite image contains four spectral bands, and WorldView-3 image only has eight multi-spectral bands [10,11] This situation is attributed to remote sensors, which have physical limitations between spatial and spectral resolutions. The high resolution in geometry and low deliverance in spectral reflectance produce the Hughes phenomenon and cause considerable noise in the classification map [12,13,14,15,16]

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