无人机高光谱影像水面耀光去除及信息重构方法研究

doi:10.3969/j.issn.1000-5641.2024.01.005

摘要/Abstract

摘要：

抑制遥感影像水面耀光污染并重构影像信息, 是改善无人机遥感信息质量、扩大水环境监测区域的有效途径. 针对传统经典的耀光信息重构算法难以适用于无人机高光谱影像这一问题, 提出了一种耀光自动检测去除与信息重构算法, 即采用归一化水体指数提取水体, 以全波段总和灰度图像的最低值为阈值对耀光进行分割, 利用拉普拉斯算子提取水面耀光纹理, 通过多轮形态学膨胀与阈值更新迭代计算出两者面积差值, 以投票机制获得最小差值的出现频率, 并逆向获取最佳阈值自动去除耀光. 而后, 基于主成分分析确定匹配波段, 通过改进Criminisi算法对去除区域进行重构. 去除算法应用于四个真实耀光场景, 去除率均在99%以上. 重构算法结果在主观和客观上均优于其他算法, 耀光重构水体与正常水体各波段变异系数差值在1%以内, 具有良好的光谱应用能力.

关键词: 无人机高光谱, 耀光去除, 信息重构, 主成分分析, 改进Criminisi算法

Abstract:

Suppressing water glint pollution from remote sensing images and reconstructing image information are effective ways to improve the quality of UAV (unmanned aerial vehicle) remote sensing information and increase water environment monitoring areas. It is difficult to apply traditional glint information reconstruction algorithms to UAV hyperspectral images. This study proposes an algorithm for automatic glint detection, removal, and information reconstruction. First, NDWI (normalized difference water index) was used to extract the water body, and the lowest value of the sum of grayscale images in the entire band was used as a threshold to segment the glint, and the Laplace operator was used to extract the glint texture. The difference between the two areas was calculated through multiple rounds of morphological expansion and threshold updates. The lowest difference occurrence frequency was obtained by voting, and the best threshold was obtained in reverse to remove the glint automatically. Then, we determined the matching bands based on principal component analysis and compared the minimum similarity of matching blocks of different sizes to obtain the best size of the image blocks. Finally, we used an improved Criminisi algorithm to reconstruct the flare removal region. The removal algorithm was applied to four real glint scenarios with a removal rate > 99%; the reconstruction algorithm results are superior to those of other algorithms both subjectively and objectively, and the difference between the variation coefficient of each band of the glint reconstruction for water and normal water was within 1%, indicating good spectral application capability.

Key words: UAV hyperspectral, glint removal, information reconstruction, principal component analysis, improvement of the Criminisi algorithm

中图分类号:

王世瑞, 沈芳, 李仁虎, 李鹏. 无人机高光谱影像水面耀光去除及信息重构方法研究[J]. 华东师范大学学报（自然科学版）, 2024, 2024(1): 36-49.

Shirui WANG, Fang SHEN, Renhu LI, Peng LI. Research on water surface glint removal and information reconstruction methods for unmanned aerial vehicle hyperspectral images[J]. Journal of East China Normal University(Natural Science), 2024, 2024(1): 36-49.

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多旋翼无人机	高光谱传感器
型号: KWT-X6L	型号: Micro Hyperspec VNIR A-Series
最大抗风能力: 14 m/s	波长范围: 400 ~ 1000 nm
最大飞行速度: 15 m/s	光谱分辨率: < 4 nm
最大负载重量: 6 kg	成像方式: 推扫式成像
负载荷飞行时间: ≥ 35 min	空间通道数: 1004; 焦距: 8 mm

评价方法	方法	场景1	场景2	场景3	场景4	评价方法	重构算法	场景1	场景2	场景3	场景4
RMSE	TV	0.035	0.047	0.021	0.007	SAM	TV	2.068	2.305	1.176	0.263
	PDE	0.035	0.036	0.032	0.006		PDE	2.068	2.435	1.177	0.268
	LRMR	0.022	0.027	0.03	0.007		LRMR	1.017	6.142	1.002	0.217
	Original CRI	0.012	0.013	0.017	0.006		Original CRI	0.917	0.685	0.631	0.134
	CRI-PCA	0.012	0.011	0.011	0.006		CRI-PCA	1.428	1.011	0.708	0.232
	CRI-inversePCA	0.008	0.006	0.011	0.006		CRI-inversePCA	0.378	0.202	0.584	0.132
SSIM	TV	0.967	0.92	0.987	0.992	PSNR	TV	29.318	26.833	33.411	42.956
	PDE	0.967	0.974	0.986	0.992		PDE	29.317	29.785	29.956	44.808
	LRMR	0.958	0.945	0.976	0.991		LRMR	33.349	31.65	30.436	42.86
	Original CRI	0.981	0.982	0.986	0.992		Original CRI	39.292	38.075	35.686	44.711
	CRI-PCA	0.986	0.988	0.991	0.992		CRI-PCA	39.228	39.004	39.171	44.979
	CRI-inversePCA	0.989	0.993	0.991	0.992		CRI-inversePCA	42.449	45.388	39.176	44.877

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