基于卫星雷达测高技术的湖库动态监测理论、方法和研究进展

姜丽光; 刘俊; 张星星

doi:10.11834/jrs.20221221

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基于卫星雷达测高技术的湖库动态监测理论、方法和研究进展
Monitoring lakes and reservoirs using satellite radar altimetry： Theory， methods， and progresses
2022年26卷第1期页码：104-114
收稿：2021-04-19，

纸质出版：2022-01-07
DOI： 10.11834/jrs.20221221
稿件说明：

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姜丽光，刘俊，张星星.2022.基于卫星雷达测高技术的湖库动态监测理论、方法和研究进展.遥感学报，26（1）： 104-114 DOI： 10.11834/jrs.20221221.

Jiang L G，Liu J and Zhang X X. 2022. Monitoring lakes and reservoirs using satellite radar altimetry： Theory， methods， and progresses. National Remote Sensing Bulletin， 26（1）：104-114 DOI： 10.11834/jrs.20221221.

摘要

水位是反映水体变化的重要变量，利用卫星测高技术获取湖库的水位信息，很大程度上改变了传统地面观测数据匮乏的现状。本文综述了卫星雷达测高技术在湖泊和水库动态监测方面的理论、主要的数据处理方法和数据产品，以及当前的主要研究进展。从文献检索可以看出，当前的应用研究对象主要聚焦在个别湖泊或小范围内的湖泊群；在数据处理方面，数据以单一测高任务数据为主，并依赖于主流数据库的三级产品，针对一级、二级产品的数据处理方法研究较少；在研究主题方面，主要以湖库水位变化趋势及影响因素分析为主，也有少量研究聚焦在水量估算、流域水文模拟等方向。未来发展新的数据处理方法，如全聚焦SAR技术和干涉宽刈幅数据处理技术等，研发新的测高任务（如测高小卫星星簇计划SMASH、地表水和海洋地形SWOT、以及欧盟的下一代测高任务Sentinel-3 NGT等），来提高中小型湖库的测高数据精度、覆盖范围以及频率，将为测高研究带来新的机遇。

Abstract

Water level is an important variable that indicates the variations in the vertical dimension of inland water bodies. However

in-situ monitoring of water level of lakes and reservoirs is expensive. Thus

the coverage of gauging network is relatively low. The satellite altimetry technology

originally used for ocean research

has been widely applied for inland water research on a local to regional and global scale. As the success of several altimetry missions

the situation of data scarcity has been mitigated

especially in the recent decade.

The literature review shows that the mainstream of altimetry research for lakes and reservoirs focuses on one specific or few lakes/reservoirs aiming at a detailed investigation. Regarding the altimetry data sets

most studies use high-level products (i.e. water level data instead of raw signals) from one certain database

such as Hydroweb

DAHITI

etc.

but very few exploit the low-level products. The major research foci include temporal variations of water level

and the attribution of water level changes in the context of climate changes. Besides

some publications research the water storage changes and thus assess the water resources and management issues

while some others focus on catchment hydrologic modeling with water levels of lakes/reservoirs as constraints.

In this short review article

we first briefly introduced the theory of inland altimetry

followed by the descriptions of major freely open-access products of different levels. Then

we summarized the common data processing procedures including data screening

waveform retracking

outlier removal

time series construction

etc. We intend to guide the newcomers to prepare data for their own studies of interest when dealing with low-level products if necessary. Moreover

we reviewed the latest progresses of inland water altimetry

especially for lakes and reservoirs research. The progresses are reported in three main directions

i.e.

water level monitoring and analysis

dynamics of water storage

and catchment hydrologic modeling. The latter two directions involve more data sets other than altimetry-derived water levels and still need more research for further advancement.

We concluded this study with recommendations on future research topics

such as new data processing techniques (e.g. Fully-Focused SAR and Wide swath InSAR processing

Machine Learning

etc.) to extract water levels that are more accurate. We also provide introductions of several proposed or planed future altimetry missions (e.g. SWOT

Sentinel-3 Next Generation Topography

Sentinel-6-Next Generation

etc.) that will provide many opportunities for lake and reservoir research beyond just lake/reservoir monitoring. Moreover

we highlight the value of multi-mission (or constellations) data sets for high spatio-temporal resolution mapping of inland water bodies. Meanwhile

it is also very important to develop freely open-access high-level databases for end users

such as hydrological modelers.

关键词

Keywords

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