联合LiCSBAS和机器学习的昆明市地面监测和预测

doi:10.13474/j.cnki.11-2246.2023.0211

测绘通报 ›› 2023, Vol. 0 ›› Issue (7): 119-124.doi: 10.13474/j.cnki.11-2246.2023.0211

联合LiCSBAS和机器学习的昆明市地面监测和预测

李洋洋¹, 左小清¹, 肖波^1,2, 李勇发¹, 杨栩¹, 董玉娟¹

1. 昆明理工大学国土资源工程学院, 云南昆明 650093;
2. 云南交通职业技术学院公路与建筑工程学院, 云南昆明 650500

收稿日期:2023-02-21 出版日期:2023-07-25 发布日期:2023-08-08
通讯作者: 左小清。E-mail:zxq@kust.edu.cn
作者简介:李洋洋(1998-),男,硕士生,研究方向为InSAR技术监测应用与精度分析。E-mail:1208825765@qq.com
基金资助:
国家自然科学基金(42161067)

Combined LiCSBAS and machine learning ground monitoring and prediction method for Kunming city

LI Yangyang¹, ZUO Xiaoqing¹, XIAO Bo^1,2, LI Yongfa¹, YANG Xu¹, DONG Yujuan¹

1. Institute of Land and Resources Engineering, Kunming University of Science and Technology, Kunming 650093, China;
2. Yunnan Communications Vocational and Technical College, School of Highway and Construction Engineering, Kunming 650500, China

Received:2023-02-21 Online:2023-07-25 Published:2023-08-08

摘要/Abstract

摘要： 针对InSAR在数据处理过程中存在对流层延迟误差、解缠误差及处理大范围区域数据需要消耗大量时间和磁盘空间的问题,本文首先利用LiCSBAS和GACOS产品对2016年9月16日至2021年5月5日昆明市134景Sentinel-1升降轨影像进行数据处理,获取昆明市主城区沉降信息,在此基础上得到5个典型地表沉降区并分析其时空分布特征;然后利用深度森林和长短期记忆网络模型进行时序值的预测,引入绝对误差(ε)、均方根误差(RMSE)、纳什系数(NSE)对模型进行评价,深度森林和长短期记忆模型得到的ε均在4 mm以内,RMSE值分别为0.70和3.01,NSE值分别为0.92和0.81。结果表明,深度森林预测模型效果较好,联合LiCSBAS和机器学习模型的城市地表监测和预测的方法可以为今后开展地面沉降监测和灾害预警提供参考。

关键词: 对流层延迟误差, LiCSBAS, 解缠误差, 深度森林, 时序预测

Abstract: To address the problems of tropospheric delay errors, deconvolution errors and the large amount of time and disk space required to process data over a large area in InSAR during data processing,in this paper, the atmospheric correction data of 134 Sentinel-1 lifting rail images of Kunming city from September 16, 2016 to May 5, 2021 are processed by LiCSBAS and synthetic aperture radar general atmospheric correction online service product, and the subsidence information of the main urban area of Kunming city is obtained.On this basis, five typical land surface subsidence areas are obtained and their temporal and spatial distribution characteristics are analyzed. Then, deep forest and long term memory network models are used to predict the time series values, and absolute error (ε), root mean square error (RMSE) and nash coefficient (NSE) are introduced to evaluate the models. Both the deep forest and LSTM prediction models are within 4 mm, RMSE values are 0.70 and 3.01, and NSE values are 0.92 and 0.81, respectively.The results show that the deep forest prediction model has a good effect. The urban surface monitoring and prediction method combined with LiCSBAS and machine learning model can provide a reference for future land subsidence monitoring and disaster warning.

Key words: tropospheric delay error, LiCSBAS, deconvolution error, deep forest, time series prediction

中图分类号:

P237

李洋洋, 左小清, 肖波, 李勇发, 杨栩, 董玉娟. 联合LiCSBAS和机器学习的昆明市地面监测和预测[J]. 测绘通报, 2023, 0(7): 119-124.

LI Yangyang, ZUO Xiaoqing, XIAO Bo, LI Yongfa, YANG Xu, DONG Yujuan. Combined LiCSBAS and machine learning ground monitoring and prediction method for Kunming city[J]. Bulletin of Surveying and Mapping, 2023, 0(7): 119-124.

参考文献

[1] 蓝秦隆,邹进贵. SBAS技术在地面沉降监测中的应用:以武汉市为例[J]. 测绘通报,2018(S1):278-282.
[2] 许强,李为乐,董秀军,等. 四川茂县叠溪镇新磨村滑坡特征与成因机制初步研究[J]. 岩石力学与工程学报,2017,36(11):2612-2628.
[3] 刘沛源,常鸣,武彬彬,等. 基于SBAS-InSAR技术的成汶高速汶川段滑坡易发区选线研究[J]. 地球科学,2022,47(6):2048-2057.
[4] 秦晓琼,杨梦诗,王寒梅,等. 高分辨率PS-InSAR在轨道交通形变特征探测中的应用[J]. 测绘学报,2016,45(6):713-721.
[5] 麻源源,陈云波,左小清,等. Sentinel-1A数据及短基线集的昆明地面沉降分析[J]. 测绘科学,2019,44(11):59-66.
[6] MA Yuanyuan,CHEN Yunbo,ZUO Xiaoqing,et al. Land subsidence analysis of Kunming based on Sentinel-1A data and short baseline sets[J]. Science of Surveying and Mapping,2019,44(11):59-66.
[7] 姜德才,张永红,张继贤,等. 天津市地铁线不均匀地表沉降InSAR监测[J]. 遥感信息,2017,32(6):27-32.
[8] 高壮,何秀凤,肖儒雅,等. 联合估计形变和大气误差的LiCSBAS方法在地表监测中的应用分析[J/OL].武汉大学学报(信息科学版):2022:1-13.
[9] 周定义,左小清,喜文飞,等. 顾及大气误差和相位解缠误差的LiCSBAS方法对高山峡谷地区地质灾害的探测[J]. 测绘通报,2022(6):114-120.
[10] MORISHITA Y,LAZECKY M,WRIGHT T,et al. LiCSBAS:an open-source InSAR time series analysis package integrated with the LiCSAR automated sentinel-1 InSAR processor[J]. Remote Sensing,2020,12(3):424.
[11] JOLIVET R,GRANDIN R,LASSERRE C,et al. Systematic InSAR tropospheric phase delay corrections from global meteorological reanalysis data[J]. Geophysical Research Letters,2011,38(17):2011GL048757.
[12] ZHOU Zhihua,FENG Ji. Deep forest[J]. National Science Review,2019,6(1):74-86.
[13] GERS F A,SCHMIDHUBER J,CUMMINS F. Learning to forget:continual prediction with LSTM[J]. Neural Computation,2000,12(10):2451-2471.
[14] QING Xiaoyun,NIU Yugang. Hourly day-ahead solar irradiance prediction using weather forecasts by LSTM[J]. Energy,2018,148:461-468.
[15] LI Yifei. Prediction for tourism flow based on LSTM neural network[J]. Procedia Computer Science,2018,129:277-283.
[16] HOCHREITER S,SCHMIDHUBER J. Long short-term memory[J]. Neural Computation,1997,9(8):1735-1780.
[17] EFRON B,TIBSHIRANI R. Bootstrap methods for standard errors,confidence intervals,and other measures of statistical accuracy[J]. Statistical Science,1986,1(1):54-77.
[18] 刘琦,岳国森,丁孝兵,等. 佛山地铁沿线时序InSAR形变时空特征分析[J]. 武汉大学学报(信息科学版),2019,44(7):1099-1106.
[19] 刘凯斯,宫辉力,陈蓓蓓. 基于InSAR数据的北京地铁6号线地面沉降监测分析[J]. 地球信息科学学报,2018,20(1):128-137.

联合LiCSBAS和机器学习的昆明市地面监测和预测

Combined LiCSBAS and machine learning ground monitoring and prediction method for Kunming city

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 1

编辑推荐

Metrics

本文评价