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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.
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Keywords:
- image enhancement/
- Retinex/
- deep learning/
- image fusion
[1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] -
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 
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输入 操作 卷积核 输出通道 步长 输出 Vlow,Rlow,Ilow 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
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de1 upde1 up, out1
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de2 rde1 r, de2 r, de3 conv & ReLU 3 64 1 feats0 feats0 conv 1 64 1 feats1 feats1 conv 3 1 1 Vnew DownLoad:
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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 DownLoad:
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[1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34]
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