CYGNSS信号对降水的时空响应及其驱动因子分析

Spatiotemporal Response of CYGNSS Signals to Precipitation and Analysis of Driving Factors

  • 摘要: 近年来,星载全球导航卫星系统反射测量(global navigation satellite system-reflectometry,GNSS-R)技术被广泛应用于地表水文监测,但针对降水,特别是其与飓风全球导航卫星系统(cyclone global navigation satellite system,CYGNSS)信号的响应机制研究仍有限。以中国广东省为研究区域,基于距平指数和相关分析方法,探究不同尺度下研究区2019—2020年逐月的CYGNSS反射率和降水的时空响应关系,综合考虑驱动因子如数字高程模型(digital elevation model,DEM)、坡度、土壤类型、土地覆盖类型和归一化植被指数(normalized difference vegetation index,NDVI),并基于地理探测器分析各驱动因子对CYGNSS信号与降水响应关系的影响力。研究发现:(1)在2019—2020年内,月平均CYGNSS反射率值和降水量均呈现明显的季节性差异,并且二者变化趋势近乎保持同步,这验证了 CYGNSS 信号在监测降水方面的潜力。(2)随着空间尺度的增大,CYGNSS 信号和降水呈现的正相关性逐渐增强。(3)在不同空间尺度下,DEM 和坡度较小(地势较平坦)的地区、土地覆盖类型为耕地的区域,以及较低到中等植被覆盖地区的CYGNSS信号和降水之间的正相关性更强。而不同尺度下土壤类型对CYGNSS信号和降水响应关系的影响存在差异。(4)各驱动因子对CYGNSS信号与降水响应关系的影响力按大小依次排序为DEM>NDVI>坡度>土地覆盖类型>土壤类型,并且随着尺度越大,各驱动因子的影响力越强。该研究有助于对地表水文变化进行准确评估,为降水监测和水资源管理提供决策支持。

     

    Abstract:
    Objectives The spaceborne global navigation satellite system-reflectometry (GNSS-R) technology has been extensively employed in monitoring surface hydrology in recent years. However, research on the key factor of precipitation in the surface hydrological cycle, especially its spatiotemporal relationship with cyclone global navigation satellite system (CYGNSS) signals, remains limited. Therefore, this paper conducts a detailed and comprehensive analysis of the direct relationship between CYGNSS reflectivity and precipitation, taking into account multiple influencing factors and scale effects.
    Methods This study utilizes monthly CYGNSS data and precipitation data from 2019 to 2020, taking Guangdong Province, China as the study area. It analyzes the spatiotemporal response relationship between CYGNSS signals and precipitation, while comprehensively considering the influence of different driving factors such as digital elevation model (DEM), slope, land cover type, soil type, and normalized difference vegetation index (NDVI) on the CYGNSS signal-precipitation response. The study also explores scale effects, and uses a factor detector model in the geographical detector to investigate the degree of influence of each driving factor.
    Results From 2019 to 2020, the monthly average CYGNSS reflectivity and precipitation show significant seasonal differences and nearly synchronous variations, validating the potential of CYGNSS signals for precipitation monitoring. The positive correlation between CYGNSS signals and precipitation strengthens with increasing spatial scale. For example, at small scale (1 km), the positive correlation between CYGNSS signals and precipitation is 21.00% (significant at the 0.05 level), while at medium scale (3 km) and large scale (9 km), it reaches 26.84% and 40.36% respectively, highlighting the advantage of CYGNSS in monitoring precipitation at larger scales. Additionally, the study found that at different spatial scales, regions with lower DEM and slope (indicating relatively flat terrain), areas with land cover type of cropland, and regions with lower to moderate vegetation coverage exhibited a stronger positive correlation between CYGNSS signals and precipitation. However, the influence of soil type on the relationship between CYGNSS signals and precipitation response varied across different scales. The driving factors' influence on the relationship between CYGNSS signals and precipitation is ranked as follows: DEM>NDVI>slope>land cover type>soil type, and their influence becomes stronger with increasing scale.
    Conclusions This study elaborates on the response relationship between CYGNSS signals and regional precipitation, providing useful references for further utilizing GNSS-R technology to monitor precipitation and facilitating accurate assessment of surface hydrological changes. The results demonstrate that certain spatiotemporal response relationships exist between CYGNSS signals and precipitation across different scales, and various driving factors have certain influences on their response relationships.

     

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