Abstract
Digital images, and in particular satellite images acquired by different sensors, may present defects due to many causes. Since 2013, the Landsat 7 mission has been affected by a well-known issue related to the malfunctioning of the Scan Line Corrector producing very characteristic strips of missing data in the imagery bands. Within the vast and interdisciplinary image reconstruction application field, many works have been presented in the last few decades to tackle the specific Landsat 7 gap-filling problem. This work proposes another contribution in this field presenting an original procedure based on a variational image segmentation model coupled with radiometric analysis to reconstruct damaged images acquired in a multi-temporal scenario, typical in satellite remote sensing. The key idea is to exploit some specific features of the Mumford–Shah variational model for image segmentation in order to ease the detection of homogeneous regions which will then be used to form a set of coherent data necessary for the radiometric reconstruction of damaged regions. Two reconstruction approaches are presented and applied to SLC-off Landsat 7 data. One approach is based on the well-known histogram matching transformation, the other approach is based on eigendecomposition of the bands covariance matrix and on the sampling from Gaussian distributions. The performance of the procedure is assessed by application to artificially damaged images for self-validation testing. Both of the proposed reconstruction approaches had led to remarkable results. An application to very high resolution WorldView-3 data shows how the procedure based on variational segmentation allows an effective reconstruction of images presenting a great level of geometric complexity.
Highlights
Digital imaging is becoming increasingly common and is being used in a growing variety of fields spanning from computer vision to medical imaging and remote sensing, just to mention a few
This work presents a new approach to image reconstruction based on the coupling of an image segmentation variational model and the radiometric analysis of multi-temporal satellite imagery
Variational image segmentation has proven instrumental in image restoration: the smoothing action, by reducing the noise level of input data, and the discontinuity-preserving feature eases the identification of homogeneous regions and the forming of coherent region sets to be used in the radiometric analysis on which the reconstruction is based
Summary
Digital imaging is becoming increasingly common and is being used in a growing variety of fields spanning from computer vision to medical imaging and remote sensing, just to mention a few. Be they technological or natural, images may often contain radiometric distortions or partial lack of information. This work presents a new approach to image reconstruction based on the coupling of an image segmentation variational model and the radiometric analysis of multi-temporal satellite imagery. The reconstruction of satellite imagery is crucial to improve the performance of further image processing tasks such as classification, spectral unmixing, and object detection. Among the many past and active satellite missions for Earth Observation (EO) purposes, the Landsat 7 mission presents a specific data-loss issue that attracted and still attracts a lot of interest in the image reconstruction field. The ETM+ sensors cover visible red, green, and blue (RGB), Near-InfraRed (NIR), Short-Wave InfraRed (SWIR), Mid-InfraRed (MIR), and Thermal InfraRed (TIR) spectral bands with a 8-bit radiometric resolution (transmitted) and spatial resolutions of 30, 60, and 15 m for RGB/NIR/SWIR/MIR, TIR, and panchromatic bands, respectively.
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