A Method for Dehazing Images Obtained from Low Altitudes during High-Pressure Fronts

Unmanned aerial vehicles (UAVs) equipped with compact digital cameras and multi-spectral sensors are used in remote sensing applications and environmental studies. Recently, due to the reduction of costs of these types of system, the increase in their reliability, and the possibility of image acquisition with very high spatial resolution, low altitudes imaging is used in many qualitative and quantitative analyses in remote sensing. Also, there has been an enormous development in the processing of images obtained with UAV platforms. Until now, research on UAV imaging has focused mainly on aspects of geometric and partially radiometric correction. And consideration of the effects of low atmosphere and haze on images has so far been neglected due to the low operating altitudes of UAVs. However, it proved to be the case that the path of sunlight passing through various layers of the low atmosphere causes refraction and causes incorrect registration of reflection by the imaging sensor. Images obtained from low altitudes may be degraded due to the scattering process caused by fog and weather conditions. These negative atmospheric factors cause a reduction in contrast and colour reproduction in the image, thereby reducing its radiometric quality. This paper presents a method of dehazing images acquired with UAV platforms. As part of the research, a methodology for imagery acquisition from a low altitude was introduced, and methods of atmospheric calibration based on the atmosphere scattering model were presented. Moreover, a modified dehazing model using Wiener’s adaptive filter was presented. The accuracy assessment of the proposed dehazing method was made using qualitative indices such as structural similarity (SSIM), peak signal to noise ratio (PSNR), root mean square error (RMSE), Correlation Coefficient, Universal Image Quality Index (Q index) and Entropy. The experimental results showed that using the proposed dehazing method allowed the removal of the negative impact of haze and improved image quality, based on the PSNR index, even by an average of 34% compared to other similar methods. The obtained results show that our approach allows processing of the images to remove the negative impact of the low atmosphere. Thanks to this technique, it is possible to obtain a dehazing effect on images acquired at high humidity and radiation fog. The results from this study can provide better quality images for remote sensing analysis.

[1]  Andrew Fleming,et al.  On the Atmospheric Correction of Antarctic Airborne Hyperspectral Data , 2014, Remote. Sens..

[2]  J. Cihlar,et al.  An image transform to characterize and compensate for spatial variations in thin cloud contamination of Landsat images , 2002 .

[3]  Zeshu Zhang,et al.  Single Remote Sensing Multispectral Image Dehazing Based on a Learning Framework , 2019 .

[4]  A. Bovik,et al.  A universal image quality index , 2002, IEEE Signal Processing Letters.

[5]  Miao Qi,et al.  Multiscale Single Image Dehazing Based on Adaptive Wavelet Fusion , 2015 .

[6]  R. Richter A spatially adaptive fast atmospheric correction algorithm , 1996 .

[7]  Hongguang Li,et al.  Haze removal for UAV reconnaissance images using layered scattering model , 2016 .

[8]  Zheng Qu,et al.  The High Accuracy Atmospheric Correction for Hyperspectral Data (HATCH) model , 2003, IEEE Trans. Geosci. Remote. Sens..

[9]  Damian Wierzbicki,et al.  Influence of Lower Atmosphere on the Radiometric Quality of Unmanned Aerial Vehicle Imagery , 2019, Remote. Sens..

[10]  Ling Shao,et al.  A Fast Single Image Haze Removal Algorithm Using Color Attenuation Prior , 2015, IEEE Transactions on Image Processing.

[11]  A. Mazur,et al.  The influence of atmospheric light scattering on reflectance measurements during photogrammetric survey flights at low altitudes over forest areas , 2018 .

[12]  P. Zarco-Tejada,et al.  Spatio-temporal patterns of chlorophyll fluorescence and physiological and structural indices acquired from hyperspectral imagery as compared with carbon fluxes measured with eddy covariance , 2013 .

[13]  E. LeDrew,et al.  Remote sensing of aquatic coastal ecosystem processes , 2006 .

[14]  A. Goetz,et al.  Software for the derivation of scaled surface reflectances from AVIRIS data , 1992 .

[15]  James A. Gardner,et al.  MODTRAN5: a reformulated atmospheric band model with auxiliary species and practical multiple scattering options , 2004, SPIE Asia-Pacific Remote Sensing.

[16]  John P. Oakley,et al.  Improving image quality in poor visibility conditions using a physical model for contrast degradation , 1998, IEEE Trans. Image Process..

[17]  Ming-Sui Lee,et al.  Haze effect removal from image via haze density estimation in optical model. , 2013, Optics express.

[18]  Eero P. Simoncelli,et al.  Image quality assessment: from error visibility to structural similarity , 2004, IEEE Transactions on Image Processing.

[19]  Rudolf Richter Atmospheric correction of DAIS hyperspectral image data , 1996 .

[20]  Vijayan K. Asari,et al.  Ratio rule and homomorphic filter for enhancement of digital colour image , 2006, Neurocomputing.

[21]  Zixing Cai,et al.  Universal strategy for surveillance video defogging , 2012 .

[22]  Peter Reinartz,et al.  Haze Detection and Removal in Remotely Sensed Multispectral Imagery , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[23]  Damian Wierzbicki,et al.  Methodology of improvement of radiometric quality of images acquired from low altitudes , 2016 .

[24]  Jon Atli Benediktsson,et al.  Morphological Attribute Profiles for the Analysis of Very High Resolution Images , 2010, IEEE Transactions on Geoscience and Remote Sensing.

[25]  Shan Gao,et al.  A Sensor Image Dehazing Algorithm Based on Feature Learning , 2018, Sensors.

[26]  Eija Honkavaara,et al.  Assessment of Radiometric Correction Methods for ADS40 Imagery , 2012 .

[27]  P. Chavez An improved dark-object subtraction technique for atmospheric scattering correction of multispectral data , 1988 .