干涉合成孔径雷达监测湿地水位研究综述

doi:10.13287/j.1001-9332.202008.035

应用生态学报 ›› 2020, Vol. 31 ›› Issue (8): 2841-2848.doi: 10.13287/j.1001-9332.202008.035

• • 上一篇

干涉合成孔径雷达监测湿地水位研究综述

陈月庆¹, 武黎黎¹, 章光新^2*, 乔斯佳¹

¹信阳师范学院地理科学学院/河南省水土环境污染协同防治重点实验室, 河南信阳 464000;
²中国科学院东北地理与农业生态研究所, 长春 130102

收稿日期:2020-01-29 修回日期:2020-05-11 出版日期:2020-08-15 发布日期:2021-02-15
通讯作者: * E-mail: zhgx@iga.ac.cn
作者简介:陈月庆, 男, 1983年生, 博士, 讲师。主要从事湿地遥感与湿地水文连通性等研究。E-mail: chenyueqing@iga.ac.cn
基金资助:
国家自然科学基金项目(41701395,41877160,41671476)、国家重点研发计划项目(2017YFC0406003)、中国科学院特色所项目(IGA-135-05)和信阳师范学院“南湖学者奖励计划”青年项目资助

Review on wetland water level monitoring using interferometric synthetic aperture radar

CHEN Yue-qing¹, WU Li-li¹, ZHANG Guang-xin^2*, QIAO Si-jia¹

¹School of Geographic Sciences/Henan Key Laboratory of Coordinated Prevention and Control of Soil and Water Environmental Pollution, Xinyang Normal University, Xinyang 464000, Henan, China;
²Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun 130102, China

Received:2020-01-29 Revised:2020-05-11 Online:2020-08-15 Published:2021-02-15
Supported by:
This work was supported by the National Natural Science Foundation of China (41701395, 41877160, 41671476), the National Key R&D Program of China (2017YFC0406003), the Featured Institute Project, the Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences (IGA-135-05) and the Nanhu Scholars Program for Young Scholars of Xinyang Normal University

摘要/Abstract

摘要： 湿地水位是表征湿地水文情势的重要指标,干涉合成孔径雷达(InSAR)监测湿地水位具有空间分辨率高、精度高、成本低和效益好等突出优势。本文简要介绍了InSAR监测湿地水位的先决条件,系统阐述了InSAR监测湿地水位技术的类型及其优缺点,重点探讨了InSAR监测湿地水位的影响因素。InSAR监测湿地水位须满足三大前提条件:1)存在非淹没水生植被;2)主要后向散射机制为双回波散射;3)干涉相干性超过一定的阈值。目前,该水位监测技术已从传统的InSAR技术发展到STBAS、MM和DSI等改进的InSAR技术,已由监测相对水位变化发展到监测绝对水位和水深时间序列。InSAR监测湿地水位的影响因素包括合成孔径雷达(SAR)的工作参数和湿地本身的特性。最后,指出该领域未来亟待加强的研究方向为:探讨该水位监测技术应用于更多具有不同后向散射特性及干涉相干性特征的其他生态区的潜力;开发多传感器、多轨道、多波段、多极化和多时相的InSAR新算法;引入新的SAR数据源;加强InSAR监测湿地水位的“副产品”,如湿地水文连通性、流向和流态等研究。

关键词: 干涉合成孔径雷达, 后向散射, 干涉相干性, 湿地, 水位, 水文连通性

Abstract: Water level is an important indicator of wetland hydrological regime. Detection of wetland water levels through interferometric synthetic aperture radar (InSAR) has outstanding advantage, including high spatial resolution, high accuracy, low cost, and high efficiency. We introduced prerequisites for the monitoring of wetland water levels with InSAR, discussed the types of InSAR techniques, the influencing factors for monitoring wetland water levels and their advantages and disadvantages. There are three prerequisites for effectively detecting wetland water levels with InSAR techniques: 1) the presence of emergent aquatic plants; 2) the main backscattering mechanism is double bounce scattering; and 3) the interferometric coherence exceeds a certain threshold. Current water level monitoring techniques have been developed from traditional InSAR techniques to advanced InSAR techniques, such as STBAS, MM, and DSI. These techniques evolve from detecting relative water level changes to estimate absolute water level and water depth time series. The influencing factors of InSAR techniques for monitoring wetland water levels include operating para-meters of the synthetic aperture radar (SAR) and characteristics of the wetlands themselves. Finally, we proposed the key directions for future research in this field: i) investigating the potential use of specific water level monitoring techniques in other regions with different backscattering and interferometric coherence characteristics; ii) developing new algorithms to integrate multi-sensor, multi-track, multi-band, multi-polarization, and multi-temporal InSAR repeat-pass observation; iii) considering alternative sources of SAR data; and (iv) strengthening research on “by-products” of wetland water level monitoring with InSAR, such as wetland hydrological connectivity, flow direction, and flow regime.

Key words: InSAR, backscattering, interferometric coherence, wetland, water level, hydrological connectivity

陈月庆, 武黎黎, 章光新, 乔斯佳. 干涉合成孔径雷达监测湿地水位研究综述[J]. 应用生态学报, 2020, 31(8): 2841-2848.

CHEN Yue-qing, WU Li-li, ZHANG Guang-xin, QIAO Si-jia. Review on wetland water level monitoring using interferometric synthetic aperture radar[J]. Chinese Journal of Applied Ecology, 2020, 31(8): 2841-2848.

参考文献

[1] 章光新, 张蕾, 冯夏清, 等. 湿地生态水文与水资源管理. 北京: 科学出版社, 2014 [Zhang G-X, Zhang L, Feng X-Q, et al. Wetland Ecohydrology and Water Resources Management. Beijing: Science Press, 2014]
[2] 崔保山, 杨志峰. 湿地生态系统健康的时空尺度特征. 应用生态学报, 2003, 14(1): 121-125 [Cui B-S, Yang Z-F. Temporal-spatial scale characteristic of wetland ecosystem health. Chinese Journal of Applied Ecology, 2003, 14(1): 121-125]
[3] 陈月庆, 武黎黎, 章光新, 等. 湿地水文连通研究综述. 南水北调与水利科技, 2019, 17(1): 26-38 [Chen Y-Q, Wu L-L, Zhang G-X, et al. Review of wetland hydrological connectivity. South-to-North Water Transfers and Water Science & Technology, 2019, 17(1): 26-38]
[4] Edwards AL, Lee DW, Richards JH. Responses to a fluctuating environment: Effects of water depth on growth and biomass allocation in Eleocharis cellulosa Torr. (Cyperaceae). Canadian Journal of Botany, 2003, 81: 964-975
[5] 卜祥祺, 刘琳, 穆亚楠, 等. 水位波动对南美蟛蜞菊和蟛蜞菊种内及种间关系的影响. 应用生态学报, 2017, 28(3): 797-804 [Bu X-Q, Liu L, Mu Y-N, et al. Effects of water level fluctuation on the inter- and intra-specific relationships between Wedelia trilobata and W. chinensis. Chinese Journal of Applied Ecology, 2017, 28(3): 797-804]
[6] Liu Q, Liu JL, Liu H, et al. Vegetation dynamics under water-level fluctuations: Implications for wetland restoration. Journal of Hydrology, 2020, 581: 124418
[7] Lorenzn RE, Ronchi-Virgolini AL, Blake JG. Wetland dependency drives temporal turnover of bird species between high- and low-water years in floodplain wetlands of the Paran River. Ecohydrology, 2020, 13: e2179
[8] Wdowinski S, Hong SH. Wetland InSAR: A review of the technique and applications// Tiner RW, Lang MW, Klemas VV, eds. Remote Sensing of Wetlands: Applications and Advances. Boca Raton, FL, USA: Chemical Rubber Company Press, 2015: 137-154
[9] Zhang M. Satellite Radar Altimetry for Inland Hydrologic Studies. PhD Thesis. Columbus, OH, USA: The Ohio State University, 2009
[10] Kim JW, Lu Z, Jones JW, et al. Monitoring Everglades freshwater marsh water level using L-band synthetic aperture radar backscatter. Remote Sensing of Environment, 2014, 150: 66-81
[11] Hong SH, Wdowinski S, Kim SW, et al. Multi-temporal monitoring of wetland water levels in the Florida Everglades using interferometric synthetic aperture radar (InSAR). Remote Sensing of Environment, 2010, 114: 2436-2447
[12] Hanssen RF. Radar Interferometry: Data Interpretation and Error Analysis. Berlin: Springer Science & Business Media, 2001
[13] Lu Z. InSAR imaging of volcanic deformation over cloud-prone areas: Aleutian Islands. Photogrammetric Engineering & Remote Sensing, 2007, 73: 245-257
[14] Tong X, Sandwell DT, Fialko Y. Coseismic slip model of the 2008 Wenchuan earthquake derived from joint inversion of interferometric synthetic aperture radar, GPS, and field data. Journal of Geophysical Research: Solid Earth, 2010, 115: B04314
[15] Ye X, Kaufmann H, Guo X. Landslide monitoring in the Three Gorges area using D-InSAR and corner reflectors. Photogrammetric Engineering & Remote Sensing, 2004, 70: 1167-1172
[16] Gray L. Using multiple RADARSAT InSAR pairs to estimate a full three-dimensional solution for glacial ice movement. Geophysical Research Letters, 2011, 38: L05502
[17] Alsdorf DE, Melack JM, Dunne T, et al. Interferometric radar measurements of water level changes on the Amazon flood plain. Nature, 2000, 404: 174
[18] Alsdorf DE, Smith LC, Melack JM. Amazon floodplain water level changes measured with interferometric SIR-C radar. IEEE Transactions on Geoscience and Remote Sensing, 2001, 39: 423-431
[19] Wdowinski S, Kim SW, Amelung F, et al. Space-based detection of wetlands' surface water level changes from L-band SAR interferometry. Remote Sensing of Environment, 2008, 112: 681-696
[20] Wdowinski S, Amelung F, Miralles-Wilhelm F, et al. Space-based measurements of sheet-flow characteristics in the Everglades wetland, Florida. Geophysical Research Letters, 2004, 31: L15503
[21] Hong S, Wdowinski S, Kim S. Evaluation of TerraSAR-X observations for wetland InSAR application. IEEE Transactions on Geoscience and Remote Sensing, 2010, 48: 864-873
[22] Kim S, Wdowinski S, Amelung F, et al. Interferometric coherence analysis of the Everglades Wetlands, South Florida. IEEE Transactions on Geoscience and Remote Sensing, 2013, 51: 5210-5224
[23] Hong SH, Wdowinski S. Multitemporal multitrack monitoring of wetland water levels in the Florida Everglades using ALOS PALSAR data with interferometric proces-sing. IEEE Geoscience and Remote Sensing Letters, 2014, 11: 1355-1359
[24] Lu Z, Crane M, Kwoun OI, et al. C-band radar observes water level change in swamp forests. EOS, Transactions American Geophysical Union, 2005, 86: 141-144
[25] Kim JW, Lu Z, Lee H, et al. Integrated analysis of PALSAR/Radarsat-1 InSAR and ENVISAT altimeter data for mapping of absolute water level changes in Louisiana wetlands. Remote Sensing of Environment, 2009, 113: 2356-2365
[26] Lu Z, Kwoun OI. Radarsat-1 and ERS InSAR analysis over southeastern coastal Louisiana: Implications for mapping water-level changes beneath swamp forests. IEEE Transactions on Geoscience and Remote Sensing, 2008, 46: 2167-2184
[27] Pitcher LH, Pavelsky TM, Smith LC, et al. AirSWOT InSAR mapping of surface water elevations and hydraulic gradients across the Yukon Flats Basin, Alaska. Water Resources Research, 2019, 55: 937-953
[28] Xie C, Shao Y, Xu J, et al. Analysis of ALOS PALSAR InSAR data for mapping water level changes in Yellow River Delta wetlands. International Journal of Remote Sensing, 2013, 34: 2047-2056
[29] Xie C, Xu J, Shao Y, et al. Long term detection of water depth changes of coastal wetlands in the Yellow River Delta based on distributed scatterer interferometry. Remote Sensing of Environment, 2015, 164: 238-253
[30] Yuan M, Xie C, Shao Y, et al. Retrieval of water depth of coastal wetlands in the Yellow River Delta from ALOS PALSAR backscattering coefficients and interferometry. IEEE Geoscience and Remote Sensing Letters, 2016, 13: 1517-1521
[31] Zhang M, Li Z, Tian B, et al. The backscattering cha-racteristics of wetland vegetation and water-level changes detection using multi-mode SAR: A case study. International Journal of Applied Earth Observation and Geoinformation, 2016, 45: 1-13
[32] Zhang M, Li Z, Tian B, et al. A method for monitoring hydrological conditions beneath herbaceous wetlands using multi-temporal ALOS PALSAR coherence data. Remote Sensing Letters, 2015, 6: 618-627
[33] 付波霖. 基于多源遥感的沼泽湿地水文边界界定方法研究. 博士论文. 长春: 中国科学院东北地理与农业生态研究所, 2017 [Fu B-L. Study on a Method for Delineation of Wetland Hydrology Boundary using Multi-Sources Remote Sensing Data. PhD Thesis. Changchun: Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, 2017]
[34] Jung HC, Hamski J, Durand M, et al. Characterization of complex fluvial systems using remote sensing of spatial and temporal water level variations in the Amazon, Congo, and Brahmaputra Rivers. Earth Surface Processes and Landforms, 2010, 35: 294-304
[35] Lu Z, Kim JW, Lee H, et al. Helmand river hydrologic studies using ALOS PALSAR InSAR and ENVISAT altimetry. Marine Geodesy, 2009, 32: 320-333
[36] Poncos V, Teleaga D, Bondar C, et al. A new insight on the water level dynamics of the Danube Delta using a high spatial density of SAR measurements. Journal of Hydrology, 2013, 482: 79-91
[37] Gondwe BR, Hong SH, Wdowinski S, et al. Hydrologic dynamics of the ground-water-dependent Sian Ka'an wetlands, Mexico, derived from InSAR and SAR data. Wetlands, 2010, 30: 1-13
[38] Poncos V, Molson S, Welch A, et al. SAR for surface water monitoring and public health. 2014 IEEE Geo-science and Remote Sensing Symposium. Piscataway, NJ,USA: Institute of Electrical and Electronics Engineers, 2014
[39] Siles G, Trudel M, Peters DL, et al. Hydrological monitoring of high-latitude shallow water bodies from high-resolution space-borne D-InSAR. Remote Sensing of Environment, 2020, 236: 111444
[40] Jaramillo F, Brown I, Castellazzi P, et al. Assessment of hydrologic connectivity in an ungauged wetland with InSAR observations. Environmental Research Letters, 2018, 13: 10
[41] Mohammadimanesh F, Salehi B, Mahdianpari M, et al. Wetland water level monitoring using interferometric synthetic aperture radar (InSAR): A review. Canadian Journal of Remote Sensing, 2018, 44: 247-262
[42] Richards J, Woodgate P, Skidmore A. An explanation of enhanced radar backscattering from flooded forests. International Journal of Remote Sensing, 1987, 8: 1093-1100
[43] Guarnieri AM, Prati C. SAR interferometry: A “Quick and dirty” coherence estimator for data browsing. IEEE Transactions on Geoscience and Remote Sensing, 1997, 35: 660-669
[44] Mohammadimanesh F, Salehi B, Mahdianpari M, et al. Multi-temporal, multi-frequency, and multi-polarization coherence and SAR backscatter analysis of wetlands. ISPRS Journal of Photogrammetry and Remote Sensing, 2018, 142: 78-93
[45] Brisco B, Ahern F, Murnaghan K, et al. Seasonal change in wetland coherence as an aid to wetland monitoring. Remote Sensing, 2017, 9: 158
[46] Hirosawa H, Matsuzaka Y, Kobayashi O. Measurement of microwave backscatter from a cypress with and without leaves. IEEE Transactions on Geoscience and Remote Sensing, 1989, 27: 698-701
[47] Mougin E, Lopes A, Karam MA, et al. Effect of tree structure on X-band microwave signature of conifers. IEEE Transactions on Geoscience and Remote Sensing, 1993, 31: 655-667
[48] Brisco B, Murnaghan K, Wdowinski S, et al. Evaluation of RADARSAT-2 acquisition modes for wetland monitoring applications. Canadian Journal of Remote Sensing, 2015, 41: 431-439
[49] Gray AL, Mattar KE, Sofko G. Influence of ionospheric electron density fluctuations on satellite radar interfero-metry. Geophysical Research Letters, 2000, 27: 1451-1454
[50] Hong SH, Wdowinski S. Evaluation of the quad-polarimetric Radarsat-2 observations for the wetland InSAR application. Canadian Journal of Remote Sensing, 2012, 37: 484-492
[51] Chen Z, White L, Banks S, et al. InSAR monitoring of marsh wetlands flow dynamics in Great Lakes. IGARSS 2019-2019 IEEE International Geoscience and Remote Sensing Symposium. Piscataway, NJ,USA: Institute of Electrical and Electronics Engineers, 2019
[52] Mohammadimanesh F, Salehi B, Mahdianpari M, et al. X-band interferometric sar observations for wetland water level monitoring in newfoundland and labrador. 2017 IEEE International Geoscience and Remote Sensing Symposium (IGARSS). Piscataway, NJ,USA: Institute of Electrical and Electronics Engineers, 2017
[53] Chen YQ, Qiao SJ, Zhang GX, et al. Investigating the potential use of Sentinel-1 data for monitoring wetland water level changes in China's Momoge National Nature Reserve. PeerJ, 2020, 8: e8616
[54] Lu Z, Kwoun OI. Interferometric synthetic aperture radar (InSAR) study of coastal wetlands over southeastern Louisiana// Wang Y, ed. Remote Sensing of Coastal Environments. Boca Raton, FL, USA: Chemical Rubber Company Press, 2009: 25-60
[55] Freeman A, Durden SL. A three-component scattering model for polarimetric SAR data. IEEE Transactions on Geoscience and Remote Sensing, 1998, 36: 963-973
[56] Yamaguchi Y, Moriyama T, Ishido M, et al. Four-component scattering model for polarimetric SAR image decomposition. IEEE Transactions on Geoscience and Remote Sensing, 2005, 43: 1699-1706
[57] Grings FM, Ferrazzoli P, Jacobo-Berlles JC, et al. Monitoring flood condition in marshes using EM models and Envisat ASAR observations. IEEE Transactions on Geoscience and Remote Sensing, 2006, 44: 936-942
[58] Li J, Chen W, Touzi R. Optimum RADARSAT-1 configurations for wetlands discrimination: A case study of the Mer Bleue peat bog. Canadian Journal of Remote Sensing, 2007, 33: S46-S55
[59] Evans TL, Costa M. Landcover classification of the Lo-wer Nhecolndia subregion of the Brazilian Pantanal Wetlands using ALOS/PALSAR, RADARSAT-2 and ENVISAT/ASAR imagery. Remote Sensing of Environment, 2013, 128: 118-137
[60] Lee H, Yuan T, Jung HC, et al. Mapping wetland water depths over the central Congo Basin using PALSAR ScanSAR, Envisat altimetry, and MODIS VCF data. Remote Sensing of Environment, 2015, 159: 70-79
[61] Yuan T, Lee H, Jung H. Toward estimating wetland water level changes based on hydrological sensitivity analysis of PALSAR backscattering coefficients over different vegetation fields. Remote Sensing, 2015, 7: 3153-3183
[62] Kasischke ES, Smith KB, Bourgeau-Chavez LL, et al. Effects of seasonal hydrologic patterns in south Florida wetlands on radar backscatter measured from ERS-2 SAR imagery. Remote Sensing of Environment, 2003, 88: 423-441

干涉合成孔径雷达监测湿地水位研究综述

Review on wetland water level monitoring using interferometric synthetic aperture radar

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	于淼, 郭雪莲, 栗云召, 张昆, 杜朝红. 黄河口咸淡水交互作用对芦苇湿地土壤有机碳空间分异的影响 [J]. 应用生态学报, 2024, 35(2): 415-423.
[2]	贾娟, 李星奇, 冯晓娟. 排水对我国两种典型湿地土壤有机碳微生物转化过程的影响 [J]. 应用生态学报, 2024, 35(1): 133-140.
[3]	王婷, 牟长城, 孙梓淇, 李美霖, 王文婧, 许文, 赵海明. 长白山园池沼泽湿地碳源/汇沿湖岸至高地环境梯度变化 [J]. 应用生态学报, 2023, 34(9): 2363-2373.
[4]	李成龙, 周广胜, 周梦子, 周莉, 刘杰. 1971—2020年盘锦芦苇湿地净生态系统生产力及其影响因子 [J]. 应用生态学报, 2023, 34(5): 1331-1340.
[5]	李佳琛, 侯磊, 王艳霞, 梁启斌. 氮输入对罗时江湿地沉积物N₂O生成过程及酶活性的影响 [J]. 应用生态学报, 2023, 34(2): 405-414.
[6]	陈国远, 王成, 陈浩, 苏越, 於冉, 徐晓华. 盐城滨海湿地獐栖息地选择的季节变化 [J]. 应用生态学报, 2023, 34(2): 510-518.
[7]	王文婧, 牟长城, 李美霖, 孙梓淇, 王婷, 许文, 赵海明. 长白山河滨森林湿地碳源/汇空间分异规律及机制 [J]. 应用生态学报, 2023, 34(12): 3245-3255.
[8]	展鹏飞, 仝川. 甲烷排放部分抵消湿地生态系统碳汇功能:全球数据分析 [J]. 应用生态学报, 2023, 34(11): 2958-2968.
[9]	龚政, 文天翼, 靳闯, 赵堃, 苏敏. 江苏中部潮滩湿地土壤有机碳分布特征及影响因子 [J]. 应用生态学报, 2023, 34(11): 2978-2984.
[10]	张佳彭, 杨继松, 刘玥, 宁凯, 于君宝, 王志康, 王雪宏. 电子受体添加对黄河口湿地土壤厌氧碳矿化温度敏感性的影响 [J]. 应用生态学报, 2023, 34(11): 2985-2992.
[11]	李浙, 张琦, 吴庆明, 高晓冬, Ngo Thi Kieu Trang, 徐卓. 不同天气条件下青头潜鸭越冬期行为的响应模式 [J]. 应用生态学报, 2022, 33(9): 2557-2562.
[12]	周怡, 焦亮, 秦慧君, 吴晶晶, 车曦晨. 克隆植物芦苇叶片功能性状对异质环境的响应 [J]. 应用生态学报, 2022, 33(8): 2171-2177.
[13]	史宇骁, 李阳, 孟翊, 赵志远, 张婷玉, 王栋, 袁琳. 1989—2020年长江口九段沙湿地格局演变及影响因素 [J]. 应用生态学报, 2022, 33(8): 2229-2236.
[14]	侯雅琳, 韩广轩, 朱连奇, 李新鸽, 周英锋, 许景伟. 模拟降雨量变化对黄河三角洲湿地植物群落特征的影响 [J]. 应用生态学报, 2022, 33(5): 1260-1266.
[15]	陈祖明, 王彬. 基于SIMWE模型的典型水土保持措施侵蚀阻控路径分析——以通双小流域为例 [J]. 应用生态学报, 2022, 33(3): 703-710.