Abstract
Problem statement: Repeated observation of a given area over time yiel ds potential for many forms of change detection analysis. These repe ated observations are confounded in terms of radiometric consistency due to changes in sensor ca libration over time, differences in illumination, observation angles and variation in atmospheric eff ects. Also major problem with satellite images is that regions below clouds are not covered by sensor . Cloud detection, removal and data prediction in cloudy region is essential for image interpretation . Approach: This study demonstrated applicability of empirical relative radiometric normalization met hods to a set of multitemporal cloudy images acquired by Resourcesat-1 LISS III sensor. Objectiv e of this study was to detect and remove cloud cover and normalize an image radiometrically. Cloud detection was achieved by using Average Brightness Threshold (ABT) algorithm. The detected cloud removed and replaced with data from another images of the same area. We proposed a new method in which cloudy pixels are replaced with predicted pixel values obtained by regression. Afte r cloud removal, the proposed normalization method was applied to reduce the radiometric influe nce caused by non surface factors. This process identified landscape elements whose reflectance val ues are nearly constant over time, i.e., the subset of non-changing pixels are identified using frequency based correlation technique. Further, we proposed another method of radiometric correction in frequen cy domain, Pseudo-Invariant Feature regression and this process removed landscape elements such as vegetation whose reflectance values are not constant over time. It takes advantage of vegetatio n being typically high frequency area, can be removed by low pass filter. Results: The quality of radiometric normalization is statis tically assessed by R 2 value and Root Mean Square Error (RMSE) between each pair of analogous band. Further we verified that difference in mean and sta ndard deviation is reduced after normalization of subject image with respect to reference image. Resu lts are compared with commonly used No Change regression method in spatial domain. Conclusion: Cloud removal depends on spatial registration between the two images (reference imag e and cloudy subject image). Visual inspection shows proposed cloudy pixel prediction method performs better than replacing cloudy pixels with another image of the same area. Statistical analysi s also shows that average RMSE of all bands is more in No Change method. Correlation in Fourier domain does not require water body in the scene, while No Change method does require.
Highlights
Satellite images are useful for monitoring changes in land use and land cover
We suggested new method in which cloudy pixels amplitude thresholding is highly effective are replaced with predicted pixel values obtained by
Much difference is not seen in the results of proposed two radiometric normalization using Fourier transform methods
Summary
Satellite images are useful for monitoring changes in land use and land cover. Major problem with these images is that regions below clouds are not covered by sensor. The image distortion due to cloud cover is a classical problem of visible band of remote sensing imagery. For non-stationary satellite, it is commonly found in the earth resource observation application. Removing cloud cover from satellite imagery is very useful for assisting image interpretation. Cloud detection and removal is very vital in processing of satellite imagery. Further it is more difficult to quantify and interpret changes on multitemporal images under different illumination, atmospheric or sensor conditions without radiometric calibration. The relative approach to radiometric correction, known as relative radiometric
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