Image Dehazing Based on Second-Order Variational Model

被引：0

作者：

Gao Z. ^{[1
]}

Wei W. ^{[1
]}

Pan Z. ^{[1
]}

Hou G. ^{[1
]}

Zhao H. ^{[1
]}

Song J. ^{[1
]}

机构：

[1] College of Computer Science & Technology, Qingdao University, Qingdao

来源：

Jisuanji Fuzhu Sheji Yu Tuxingxue Xuebao/Journal of Computer-Aided Design and Computer Graphics | 2019年 / 31卷 / 11期

关键词：

Alternating direction multiplier method; Dark primaries prior; Image denoising; Second-order dehazing model; Second-order variational model;

D O I：

10.3724/SP.J.1089.2019.17721

中图分类号：

学科分类号：

摘要：

The algorithm based on dark channel prior theory can effectively dehaze under different scenes, but the image usually contains noise and some details which are not kept effectively after dehazing. The second-order variational model takes the second-order derivative as regular term, and can be used for image denoising. It has a good edge retention effect. In this paper, first of all, the dark channel prior method is used to estimate the transmission rate of hazy images, and then it is combined with second-order variational models including Laplacian variation model, Hessian matrix variation model, total generalized variation model and total curvature variation model, respectively. Four new second-order dehazing models, namely, H-LV model, H-HMV model, H-TGV model and H-TCV model, are proposed. In order to improve the computational efficiency of proposed models, corresponding ADMM (alter direction method of multipliers) algorithms are designed. By introducing auxiliary variables, the lagrangian multiplier is continuously updated and iterated until the energy equation converges. The experimental results using LIVE Image Defogging database show that the edge of images obtained by proposed models are good and image noise can be suppressed. © 2019, Beijing China Science Journal Publishing Co. Ltd. All right reserved.

引用

页码：1981 / 1994

页数：13

共 31 条

[1] Cao X., Liu C., Zhang J., Et al., Fast image defogging algorithm based on luminance contrast enhancement and saturation compensation, Journal of Computer-Aided Design & Computer Graphics, 30, 10, pp. 1925-1934, (2018)
[2] Hautiere N., Tarel J.P., Halmaoui H., Et al., Enhanced fog detection and free-space segmentation for car navigation, Machine Vision and Applications, 25, 3, pp. 667-679, (2014)
[3] Kim J.Y., Kim L.S., Hwang S.H., An advanced contrast enhancement using partially overlapped sub-block histogram equalization, IEEE Transactions on Circuits and Systems for Video Technology, 11, 4, pp. 475-484, (2001)
[4] Singh D., Kumar V., Dehazing of remote sensing images using fourth-order partial differential equations based trilateral filter, IET Computer Vision, 12, 2, pp. 208-219, (2018)
[5] Russo F., An image enhancement technique combining sharpening and noise reduction, IEEE Transactions on Instrumentation and Measurement, 51, 4, pp. 824-828, (2001)
[6] Jobson D.J., Rahman Z., Woodell G.A., A multiscale retinex for bridging the gap between color images and the human observation of scenes, IEEE Transactions on Image Processing, 6, 7, pp. 965-976, (1997)
[7] Narasimhan S.G., Nayar S.K., Contrast restoration of weather degraded images, IEEE Transactions on Pattern Analysis and Machine Intelligence, 25, 6, pp. 713-724, (2003)
[8] Hautiere N., Tarel J.P., Lavenant J., Et al., Automatic fog detection and estimation of visibility distance through use of an onboard camera, Machine Vision and Applications, 17, 1, pp. 8-20, (2006)
[9] Tan R.T., Visibility in bad weather from a single image, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, 1, pp. 1-8, (2008)
[10] Fattal R., Single image dehazing, ACM Transactions on Graphics, 27, 3, (2008)

← 1 2 3 4 →