基于明度分量的Retinex-Net图像增强改进方法

张航瑛; 王雪琦; 王华英; 曹良才

doi:10.7498/aps.71.20220099

摘要

当人们在低照度光照条件下拍摄图像时, 图像通常会受到低可见度的影响. 这种低可见度的图像不仅影响视觉效果而且对后续的使用造成诸多困难. 为了解决低照度条件下图像可见度差, 色彩偏差等问题, 本文提出了一种改进的Retinex网络增强方法. 该方法首先对低照度RGB图像进行HSV色彩空间变换, 利用Retinex分解网络单独对明度分量进行分解增强, 并通过上采样操作增大明度分量的分辨率. 然后对色相分量和饱和度分量, 运用最近邻点插值增大其分辨率, 结合增强的明度分量转换回RGB色彩空间, 得到初始增强图像. 最后采用小波变换图像融合技术, 与原始低照度图像进行融合, 消除初始增强图像中的过度增强部分. 实验结果分析表明, 本文所提方法与原始Retinex网络方法相比, NIQE值平均下降了19.49%, 图像标准差平均提升了41.35%. 本文所提算法有望在安防监控、生物医学等领域得到有效应用.

关键词:

Abstract

When capturing images under low-light lighting conditions, the resulting images often suffer low visibility. Such low-visibility images not only affect the visual effect but also cause many difficulties in practical application. Therefore, image enhancement technology under low-light conditions has always been a challenging problem in image algorithms. Considering that most of the existing image enhancement methods are based on the RGB color space enhancement technology, the correlation among the RGB three primary colors is ignored, which makes the color distortion phenomenon easy to occur when the image is enhanced. To solve the problems of poor image visibility and color deviation under low-light conditions, in this paper an advanced Retinex network enhancement method is proposed. In the method, firstly the low-light RGB image is transformed into HSV color space, the Retinex decomposition network is used to decompose and enhance the value component separately, and thus increasing the resolution of the value component through up-sampling operation; then, for the hue component and saturation component, the nearest neighbor interpolation is used to increase their resolutions, and the enhanced value component is combined to convert back to RGB color space to obtain the initial enhanced image; finally, the wavelet transform image fusion technology is used to fuse with the original low-light image to eliminate the over-enhanced part in the initial enhanced image. The analysis of experimental results shows that the method proposed in this paper has obvious advantages in brightness enhancement and color restoration of low-light images. Especially, comparing with the original Retinex network method, the NIQE value decreases by an average of 19.49%, and the image standard deviation increases by an average of 41.35%. The algorithm proposed in this paper is expected to be effectively used in the fields of security monitoring and biomedicine.

Keywords:

作者及机构信息

1.
清华大学精密仪器系, 精密测试技术与仪器国家重点实验室, 北京　100084

2.
河北工程大学数理科学与工程学院, 邯郸　056038

通信作者: 曹良才, clc@tsinghua.edu.cn

基金项目: 国家自然科学基金(批准号: 61827825)资助的课题.

Authors and contacts

1.
State Key Laboratory of Precision Testing Technology and Instruments, Department of Precision Instruments, Tsinghua University, Beijing 100084, China

2.
School of Mathematical Science and Engineering, Hebei University of Engineering, Handan 056038, China

Corresponding author: Cao Liang-Cai, clc@tsinghua.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 61827825 ).

文章全文 : translate this paragraph

参考文献

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施引文献

图 1 (a) Retinex成像理论模型; (b) Retinex算术思想简介

Fig. 1. (a) Retinex imaging theoretical model; (b) arithmetic ideas of Retinex algorithm.

下载: 全尺寸图片幻灯片

图 2 改进的Retinex网络增强算法流程图

Fig. 2. Flow chart of the advanced Retinex network enhancement algorithm.

下载: 全尺寸图片幻灯片

图 3 sym4尺度函数与小波函数

Fig. 3. Scale function and wavelet function of sym4.

下载: 全尺寸图片幻灯片

图 4 不同算法对比效果图

Fig. 4. Comparison of different algorithms.

下载: 全尺寸图片幻灯片

图 5 不同算法增强效果局部放大图

Fig. 5. Local enlarged view of the enhancement effect of different algorithms.

下载: 全尺寸图片幻灯片

图 6 不同方法图像评价指标的均值变化情况

Fig. 6. Changes in mean values of image evaluation metrics for different methods.

下载: 全尺寸图片幻灯片

表 1 V分量分解网络结构

Table 1. V-component decomposition network structure.

输入	操作	卷积核	输出通道	步长	输出
RGB	rgb to hsv	—	—	—	H, S, V
V	conv	3	64	1	feats0
feats0	conv & ReLU	3	64	1	feats1
feats1	conv & ReLU	3	64	1	feats2
feats2	conv & ReLU	3	64	1	feats3
feats3	conv & ReLU	3	64	1	feats4
feats4	conv & ReLU	3	64	1	feats5
feats5	conv & sigmoid	3	2	1	R, I

下载: 导出CSV

表 2 V分量增强网络结构

Table 2. V-component enhancement network structure.

输入	操作	卷积核	输出通道	步长	输出
V_low, R_low, I_low	up-sample	—	—	—	Input
Input	conv	3	64	1	out0
out0	conv & ReLU	3	64	2	out1
out1	conv & ReLU	3	64	2	out2
out2	conv & ReLU	3	64	2	out3
out3	interpolation	—	64	—	out3 up
out3 up, out2 de1	conv & ReLU interpolation	3 —	64 64	1 —	de1 de1 up
de1 up, out1 de2	conv & ReLU interpolation	3 —	64 64	1 —	de2 de2 up
de2 up, out0de1 de2	conv & ReLUinterpolation interpolation	3— —	6464 64	1— —	de3de1 r de2 r
de1 r, de2 r, de3	conv & ReLU	3	64	1	feats0
feats0	conv	1	64	1	feats1
feats1	conv	3	1	1	V_new

下载: 导出CSV

表 3 不同图像的客观评价指标

Table 3. Objective evaluation metrics for different images.

Image	Evaluate	MSRCR	Auto GC	Retinex-Net	ARN
Image1	NIQE	5.6692	5.1384	5.9782	4.0729
	Entropy	7.1095	6.6392	7.1375	7.8179
	SD	33.3758	41.6959	31.1130	42.9601
Image 2	NIQE	6.2926	6.0252	5.3596	3.7336
	Entropy	7.3012	7.5171	7.5777	7.7226
	SD	41.8903	55.6071	46.3428	66.2911
Image 3	NIQE	5.6715	4.9203	4.4528	4.0319
	Entropy	6.7898	7.1224	7.7284	7.8633
	SD	31.3800	37.3028	53.5654	72.4424
Image 4	NIQE	3.7695	3.8844	3.7200	3.6582
	Entropy	5.5392	7.1881	7.2807	7.4010
	SD	40.8917	38.6741	39.9913	46.9674
Image 5	NIQE	3.9541	4.4738	4.0126	3.6424
	Entropy	7.3497	6.0549	7.2871	7.4387
	SD	42.1574	41.0863	32.5321	56.5474
Image 6	NIQE	7.3401	6.4273	5.4459	3.8790
	Entropy	7.0335	5.5701	7.3417	7.8134
	SD	34.1136	40.6108	38.4974	56.5800
Mean	NIQE	5.4495	5.1449	4.7649	3.8363
	Entropy	6.8538	6.6820	7.3922	7.6762
	SD	37.3015	42.4962	40.3003	56.9647

下载: 导出CSV

[1]	蒋一纯, 詹伟达, 朱德鹏 2021 激光与光电子学进展 58 0410001 Google Scholar Jiang Y C, Zhan W D, Zhu D P 2021 Laser Optoelectron. Prog. 58 0410001 Google Scholar
[2]	韩平丽, 刘飞, 张广, 陶禹, 邵晓鹏 2018 物理学报 67 054202 Google Scholar Han P L, Liu F, Zhang G, Tao Y, Shao X P 2018 Acta Phys. Sin. 67 054202 Google Scholar
[3]	Liu J, Wang X, Chen M, Liu S G, Zhou X R, Shao Z F, Liu P 2014 Opt. Express 22 618 Google Scholar
[4]	Fu X Y, Zeng D L, Huang Y, Liao Y H, Ding X H, Paisley J 2016 Signal Process. 129 82 Google Scholar
[5]	Singh N, Bhandari A K 2021 IEEE Trans. Instrum. Meas. 70 1
[6]	Land E H 1964 Am. Sci. 52 247
[7]	Land E H, McCann J J 1971 J. Opt. Soc. Am. 61 1 Google Scholar
[8]	Land E H, Hubel D H, Livingstone M S, Perry S H, Burns M M 1983 Nature 303 616 Google Scholar
[9]	李红, 吴炜, 杨晓敏, 严斌宇, 刘凯, Gwanggil J 2016 物理学报 65 160701 Google Scholar Li H, Wu W, Yang X M, Yan B Y, Liu K, Gwanggil J 2016 Acta Phys. Sin. 65 160701 Google Scholar
[10]	Jobson D J, Rahman Z, Woodell G A 1997 IEEE Trans. Image Process. 6 451 Google Scholar
[11]	Rahman Z, Jobson D J, Woodell G A 1996 Proceedings of 3rd IEEE International Conference on Image Processing Lausanne, Switzerland, September 19, 1996 p1003
[12]	Jobson D J, Rahman Z, Woodell G A 1997 IEEE Trans. Image Process. 6 965 Google Scholar
[13]	毕国玲, 续志军, 赵建, 孙强 2015 物理学报 64 100701 Google Scholar Bi G L, Xu Z J, Zhao J, Sun Q 2015 Acta Phys. Sin. 64 100701 Google Scholar
[14]	Zhou Z Q, Dong M J, Xie X Z, Gao Z F 2016 Appl. Opt. 55 6480
[15]	王殿伟, 韩鹏飞, 范九伦, 刘颖, 许志杰, 王晶 2018 物理学报 67 210701 Google Scholar Wang D W, Han P F, Fan J L, Liu Y, Xu Z J, Wang J 2018 Acta Phys. Sin. 67 210701 Google Scholar
[16]	Kwon H J, Lee S H, Lee G Y, Sohng K I 2014 Digit. Signal Process. 30 74 Google Scholar
[17]	Yang Q X, Tan K H, Ahuja N 2009 IEEE Conference on Computer Vision and Pattern Recognition Miami, USA, June 20–25, 2009 p557
[18]	Wang S H, Zheng J, Hu H M, Li B 2013 IEEE Trans. Image Process. 22 3538 Google Scholar
[19]	Fu X Y, Zeng D L, Huang Y, Zhang X P, Ding X H 2016 IEEE Conference on Computer Vision and Pattern Recognition Las Vegas, USA, June 27–30, 2016 p2782
[20]	Guo X J, Li Y, Ling H B 2017 IEEE Trans. Image Process. 26 982 Google Scholar
[21]	Gijsenij A, Gevers T, Weijer J 2011 IEEE Trans. Image Process. 20 2475 Google Scholar
[22]	赵欣慰, 金韬, 池灏, 曲嵩 2015 物理学报 64 104201 Google Scholar Zhao X W, Jin T, Chi H, Qu S 2015 Acta Phys. Sin. 64 104201 Google Scholar
[23]	Jiang Z Q, Li H T, Liu L j, Men A D, Wang H Y 2021 Neurocomputing 454 361 Google Scholar
[24]	马红强, 马时平, 许悦雷, 朱明明 2019 光学学报 39 0210004 Google Scholar Ma H Q, Ma S P, Xu Y L, Zhu M M 2019 Acta Opt. Sin. 39 0210004 Google Scholar
[25]	Guo Y H, Ke X, Ma J, Zhang J 2019 IEEE Access 7 13737 Google Scholar
[26]	Lore K G, Akintayo A, Sarkar S 2017 Pattern Recognit. 61 650 Google Scholar
[27]	Wang W J, Wei C, Yang W H, Liu J Y 2018 13th IEEE International Conference on Automatic Face & Gesture Recognition Xi'an, China, May 15–19, 2018 p751
[28]	He W J, Liu Y Y, Feng J F, Zhang W W, Gu G H, Chen Q 2020 IEEE 3rd International Conference on Information Systems and Computer Aided Education Dalian, China, September 27–29, 2020 p397
[29]	Wei C, Wang W J, Yang W H, Liu J Y 2018 arXiv: 1808.04560 v1 [cs. CV]
[30]	Yakno M, Mohamad-Saleh J, Ibrahim M Z 2021 Sensors 21 6445 Google Scholar
[31]	陈刚, 刘言, 杨贺超, 孙斌, 喻春雨 2021 光学精密工程 29 1999 Google Scholar Chen G, Liu Y, Yang H C, Sun B, Yu C Y 2021 Opt. Precis. Eng. 29 1999 Google Scholar
[32]	Zhang H Y, Cao L C, Yang F 2021 Proc. SPIE First Optics Frontier Conference Hangzhou, China, June 18, 2021 1185002
[33]	Yadav A K, Roy R, Kumar A P, Kumar C S, Dhakad S K 2015 International Conference on Advances in Computing, Communications and Informatics Kochi, India, August 10–13, 2015 p1204
[34]	Mittal A, Soundararajan R, Bovik A C 2013 IEEE Signal Process. Lett. 20 209 Google Scholar

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