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遥感技术与应用  2023, Vol. 38 Issue (5): 1126-1135    DOI: 10.11873/j.issn.1004-0323.2023.5.1126
遥感应用     
基于孤立森林的水体异常快速发现与识别
朱秀芳1,2(),李原3,4,郭锐1,2
1.北京师范大学遥感科学国家重点实验室,北京 100875
2.北京师范大学 地理科学学部遥感科学与工程研究院,北京 100875
3.内蒙古大学 生态与环境学院,内蒙古 呼和浩特 010021
4.内蒙古自治区河流与湖泊生态重点实验室,内蒙古 呼和浩特 010021
Rapid Detection and Identification of Water Anomalies based on Isolated Forest
Xiufang ZHU1,2(),Yuan LI3,4,Rui GUO1,2
1.State Key Laboratory of Remote Sensing Science,Beijing Normal University,Beijing 100875,China
2.Institute of Remote Sensing Science and Engineering,School of Geographic Sciences,Beijing Normal University,Beijing 100875,China
3.College of Ecology and Environment,Inner Mongolia University,Hohhot 010021,China
4.Key Laboratory of River and Lake Ecology,Inner Mongolia Autonomous Region,Hohhot 010021,China
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摘要:

现有异常水体的检测研究通常针对特定区域、特定数据源和特定时相开展,且往往是事后的检测而非实时的监测,不能很好地服务于水体异常快速发现与识别的业务需求。为此,提出了一种基于无监督的孤立森林加决策规则(U-IForest-SD)的水体异常信息提取方法,并以Landsat与Sentinel的数据作为测试数据,以青岛浒苔、松雅湖黑臭水、墨西哥湾溢油为案例,对比了支持向量机、监督孤立森林以及U-IForest-SD 3种方法识别浒苔、黑臭水和溢油的精度。研究结果显示:该方法对于3种异常类型的总体识别精度都在90%以上、Kppa系数都在0.8以上,整体精度高于监督孤立森林但略低于SVM。该算法只需要输入单期影像,无需训练样本,具有可移植性好、普适性强、自动化程度高的优点。此外,该方法可以有效地避免“假警”和“虚警”的发生,在异常水体的快速发现和识别业务中有很好的应用前景。
关键词: 异常检测溢油黑臭水浒苔    
Abstract:

The existing detection research of abnormal water bodies is usually carried out for specific regions, specific data sources and specific time phases. Anomaly recognition algorithm testing is often a backtracking of the water body anomaly events that have occurred, rather than real-time monitoring of the anomaly events, which cannot serve the requirements of rapid detection and identification of water body anomalies. In this paper, a method of extracting water body abnormal information based on unsupervised isolated forest plus decision rule (U-IForest-SD) is proposed. We selected Landsat and Sentinel as the test data, and tested the accuracy of U-IForest-SD with the black and smelly water body of Qingdao Enteromorpha, Songya lake and the oil spill in the Gulf of Mexico as research cases. We also compared U-IForest-SD with SVM and supervised isolated forests. The results show that the overall accuracy of the proposed method for the three types of anomalies is above 90%, and the kappa coefficient is above 0.8. The overall accuracy is higher than that of supervised isolated forest but slightly lower than that of SVM. This algorithm only needs to input single phase images, and does not need training samples. It has the advantages of good portability, strong universality and high automation. In addition, it can effectively avoid the occurrence of "wrong alarm" and "false alarm". Therefore, the newly proposed method has a good application prospect in the rapid detection and identification of abnormal water bodies.
Key words: Anomaly detection    Oil spill    Black smelly water    Enteromorpha
收稿日期: 2022-09-12 出版日期: 2023-11-07
ZTFLH:  X87  
基金资助: 国家自然科学基金重大项目(41292583)
作者简介: 朱秀芳(1982-),女,浙江天台人,教授,主要从事遥感应用研究。E?mail:zhuxiufang@bnu.edu.cn
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朱秀芳,李原,郭锐. 基于孤立森林的水体异常快速发现与识别[J]. 遥感技术与应用, 2023, 38(5): 1126-1135.

Xiufang ZHU,Yuan LI,Rui GUO. Rapid Detection and Identification of Water Anomalies based on Isolated Forest. Remote Sensing Technology and Application, 2023, 38(5): 1126-1135.

链接本文:

http://www.rsta.ac.cn/CN/10.11873/j.issn.1004-0323.2023.5.1126        http://www.rsta.ac.cn/CN/Y2023/V38/I5/1126

图1  研究区概况(a) 青岛浒苔 (b) 松雅湖黑臭水 (c) 墨西哥湾溢油
数据类型获取时间数据描述用途
Landsat 82021-07-09青岛浒苔发生时的数据测试算法提取浒苔的适用性
Landsat 82021-09-11青岛浒苔结束后的数据测试算法在正常水体中是否会错误识别异常
Landsat 82016-11-28松雅湖黑臭水体发生时的数据测试算法提取黑臭水体的适用性
Sentinel-22020-05-02墨西哥湾溢油发生时的数据测试算法提取溢油的适用性
表 1  数据详情
图2  正常水体与异常水体的对比(a) 反射率对比 (b) NDVI区间
类型NDVI
最小值Min最大值Max均值Mean标准差σ

范围

(Mean±2σ)

浒苔0.160.610.4080.13(0.15,0.67)
黑臭水体-0.303-0.13-0.2040.049(-0.302,-0.106)
溢油-0.980-0.880.23(-1,-0.42)
表 2  异常水体NDVI统计
图3  水体异常发现和识别的流程
图4  基于SVM、S-IForest和U-IForest 3类方法的异常水体识别结果
案例方法PAUAOAKappa
青岛浒苔SVM0.940.990.970.95
S-IForest0.840.900.900.79
U-IForest- IQR0.760.950.880.75
U-IForest- 1.5IQR0.760.960.890.77
U-IForest- SD0.780.990.900.80
U-IForest- 2SD0.720.960.870.72
UPCA-U-IForest-SD0.800.960.900.80

松雅湖

黑臭水

SVM0.990.990.990.99
S-IForest0.990.850.940.87
U-IForest- IQR0.430.860.800.46
U-IForest- 1.5IQR0.040.450.670.02
U-IForest- SD0.970.970.960.90
U-IForest- 2SD0.080.550.680.07
UPCA-U-IForest-SD0.990.930.970.95
墨西哥湾溢油SVM0.910.990.980.94
S-IForest0.470.970.860.56
U-IForest- IQR0.340.860.770.38
U-IForest- 1.5IQR0.110.970.800.17
U-IForest- SD0.840.950.940.85
U-IForest- 2SD0.330.860.770.37
UPCA-U-IForest-SD0.800.760.880.70
表3  精度验证
图5  仅依赖决策规则的异常水体识别结果
图6  仅使用U-IForest的异常水体识别结果
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