图学学报 ›› 2026, Vol. 47 ›› Issue (3): 576-588.DOI: 10.11996/JG.j.2095-302X.2026030576
收稿日期:2025-10-27
接受日期:2026-02-12
出版日期:2026-06-30
发布日期:2026-06-30
通讯作者:刘艳丽,E-mail:yanliliu@scu.edu.cn
ZHANG Yi1, WANG Zhen2, LIU Yanli2(
), XING Guanyu3
Received:2025-10-27
Accepted:2026-02-12
Published:2026-06-30
Online:2026-06-30
Contact:
LIU Yanli,E-mail:yanliliu@scu.edu.cn摘要:
针对现有视频去雾方法在纹理细节恢复不足及帧间一致性建模不充分的问题,提出了一种渐进式时空细节增强视频去雾算法(PSTD-net),包括空间细节增强与跨帧时序建模2个模块。首先,为缓解现有方法对高频纹理建模能力不足的问题,提出了渐进式细节增强编码器,有效提取并恢复被雾霾破坏的纹理细节;其次,为提升视频帧间的时间一致性,设计了跨帧细节增强模块,通过时空注意力机制建模帧间依赖关系,增强图像细节的同时抑制伪影生成。实验在多个合成及真实雾霾视频数据集上进行,结果表明,PSTD-net在去雾效果和视觉一致性方面均取得了改进,为视频去雾任务提供了新的解决方案。
中图分类号:
张益, 王振, 刘艳丽, 邢冠宇. 渐进式时空细节增强视频去雾算法[J]. 图学学报, 2026, 47(3): 576-588.
ZHANG Yi, WANG Zhen, LIU Yanli, XING Guanyu. A progressive spatiotemporal detail enhancement algorithm for video dehazing[J]. Journal of Graphics, 2026, 47(3): 576-588.
| 方法 | 年份 | 类型 | HazeWorld | REVIDE | ||
|---|---|---|---|---|---|---|
| PSNR/dB | SSIM | PSNR/dB | SSIM | |||
| DCP[ | 2011 | 图像去雾 | 16.49 | 0.812 6 | 11.03 | 0.728 5 |
| Griddehazenet[ | 2019 | 图像去雾 | 22.80 | 0.921 7 | 19.69 | 0.854 5 |
| FFA[ | 2020 | 图像去雾 | 22.11 | 0.900 7 | 16.65 | 0.813 3 |
| MSDBN[ | 2020 | 图像去雾 | 23.70 | 0.885 8 | 22.01 | 0.875 9 |
| Dehamer[ | 2022 | 图像去雾 | 22.92 | 0.904 4 | 19.43 | 0.700 8 |
| Dehazeformer[ | 2023 | 图像去雾 | 25.44 | 0.928 6 | 19.92 | 0.814 9 |
| DEA-Net[ | 2024 | 图像去雾 | 28.29 | 0.918 8 | 20.28 | 0.778 8 |
| VDH[ | 2018 | 视频去雾 | 17.97 | 0.778 0 | 16.64 | 0.813 3 |
| EDVR[ | 2019 | 视频去雾 | 22.91 | 0.903 6 | 21.22 | 0.870 7 |
| CG-IDN[ | 2021 | 视频去雾 | 25.25 | 0.915 5 | 23.21 | 0.883 6 |
| BasicVSR++[ | 2022 | 视频去雾 | 26.06 | 0.920 7 | 21.68 | 0.872 6 |
| MAP-Net[ | 2023 | 视频去雾 | 27.12 | 0.934 9 | 24.03 | 0.892 7 |
| DVD-Net[ | 2024 | 视频去雾 | 28.33 | 0.935 6 | 24.34 | 0.892 1 |
| PSTD-net | — | 视频去雾 | 28.66 | 0.938 7 | 23.65 | 0.896 7 |
表1 各方法在HazeWorld和REVIDE上的定量指标对比
Table 1 Quantitative results on HazeWorld and REVIDE
| 方法 | 年份 | 类型 | HazeWorld | REVIDE | ||
|---|---|---|---|---|---|---|
| PSNR/dB | SSIM | PSNR/dB | SSIM | |||
| DCP[ | 2011 | 图像去雾 | 16.49 | 0.812 6 | 11.03 | 0.728 5 |
| Griddehazenet[ | 2019 | 图像去雾 | 22.80 | 0.921 7 | 19.69 | 0.854 5 |
| FFA[ | 2020 | 图像去雾 | 22.11 | 0.900 7 | 16.65 | 0.813 3 |
| MSDBN[ | 2020 | 图像去雾 | 23.70 | 0.885 8 | 22.01 | 0.875 9 |
| Dehamer[ | 2022 | 图像去雾 | 22.92 | 0.904 4 | 19.43 | 0.700 8 |
| Dehazeformer[ | 2023 | 图像去雾 | 25.44 | 0.928 6 | 19.92 | 0.814 9 |
| DEA-Net[ | 2024 | 图像去雾 | 28.29 | 0.918 8 | 20.28 | 0.778 8 |
| VDH[ | 2018 | 视频去雾 | 17.97 | 0.778 0 | 16.64 | 0.813 3 |
| EDVR[ | 2019 | 视频去雾 | 22.91 | 0.903 6 | 21.22 | 0.870 7 |
| CG-IDN[ | 2021 | 视频去雾 | 25.25 | 0.915 5 | 23.21 | 0.883 6 |
| BasicVSR++[ | 2022 | 视频去雾 | 26.06 | 0.920 7 | 21.68 | 0.872 6 |
| MAP-Net[ | 2023 | 视频去雾 | 27.12 | 0.934 9 | 24.03 | 0.892 7 |
| DVD-Net[ | 2024 | 视频去雾 | 28.33 | 0.935 6 | 24.34 | 0.892 1 |
| PSTD-net | — | 视频去雾 | 28.66 | 0.938 7 | 23.65 | 0.896 7 |
图4 各方法在自然场景下对天空区域的修复效果对比
Fig. 4 Qualitative comparison of restoration performance on sky regions under natural scenarios ((a) Input image; (b) EDVR; (c) Dehamer; (d) Dehazeformer; (e) DEA-net; (f) MAP-Net; (g) PSTD-net; (h) Ground truth)
图5 各方法在自然场景下对天空区域的修复效果对比
Fig. 5 Qualitative comparison of sky region restoration in natural scenarios ((a) Input image; (b) EDVR; (c) Dehamer; (d) Dehazeformer; (e) DEA-net; (f) MAP-Net; (g) PSTD-net; (h) Ground truth)
图6 各方法在REVIDE数据集上的去雾效果对比
Fig. 6 Qualitative comparison of dehazing performance on the REVIDE dataset ((a) Input image; (b) EDVR; (c) Dehamer; (d) Dehazeformer; (e) DEA-net; (f) MAP-Net; (g) PSTD-net; (h) Ground truth)
| 模型 | PSNR/dB | SSIM | FLOPS/G | 参数量/M |
|---|---|---|---|---|
| Base | 26.69 | 0.882 4 | 63.43 | 6.81 |
| Base-SDE | 27.32 | 0.911 0 | 63.12 | 6.80 |
| PSTD-net | 27.61 | 0.917 2 | 63.42 | 6.81 |
表2 空间细节增强模块消融实验结果
Table 2 Results of ablation experiments for the spatial detail enhancement module
| 模型 | PSNR/dB | SSIM | FLOPS/G | 参数量/M |
|---|---|---|---|---|
| Base | 26.69 | 0.882 4 | 63.43 | 6.81 |
| Base-SDE | 27.32 | 0.911 0 | 63.12 | 6.80 |
| PSTD-net | 27.61 | 0.917 2 | 63.42 | 6.81 |
图7 空间细节增强模块对去雾结果的影响
Fig. 7 Influence of the spatial detail enhancement module on dehazing performance ((a) Base; (b) Base-SDE; (c) PSTD-net; (d) Ground truth)
| 模型 | PSNR/dB | SSIM | FLOPS/G | 参数量/ M |
|---|---|---|---|---|
| Base-Stack | 26.53 | 0.8768 | 57.96 | 6.45 |
| Base-SDE | 27.43 | 0.9135 | 58.49 | 6.44 |
| PSTD-net | 27.61 | 0.9172 | 63.42 | 6.81 |
表3 跨帧细节增强模块消融实验结果
Table 3 Results of ablation experiments for the cross-frame detail enhancement module
| 模型 | PSNR/dB | SSIM | FLOPS/G | 参数量/ M |
|---|---|---|---|---|
| Base-Stack | 26.53 | 0.8768 | 57.96 | 6.45 |
| Base-SDE | 27.43 | 0.9135 | 58.49 | 6.44 |
| PSTD-net | 27.61 | 0.9172 | 63.42 | 6.81 |
图8 空间细节增强模块对去雾结果的影响
Fig. 8 Influence of the spatial detail enhancement module on dehazing performance ((a) Base-satck; (b) Base-nodetail; (c) PSTD-net; (d) Ground truth)
| 损失 | PSNR | SSIM | 迭代次数/ K |
|---|---|---|---|
| L1 | 26.57 | 0.893 9 | 40 |
| L2 | 26.02 | 0.879 3 | 40 |
| L1+L2 | 26.86 | 0.903 2 | 40 |
| L1+LCR | 27.61 | 0.917 2 | 40 |
表4 损失函数消融实验结果
Table 4 Results of ablation experiments for different loss terms
| 损失 | PSNR | SSIM | 迭代次数/ K |
|---|---|---|---|
| L1 | 26.57 | 0.893 9 | 40 |
| L2 | 26.02 | 0.879 3 | 40 |
| L1+L2 | 26.86 | 0.903 2 | 40 |
| L1+LCR | 27.61 | 0.917 2 | 40 |
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