Abstract
Groundwater-fed lakes in northeastern Germany are characterized by significant lake level changes, but for only a few lakes are in situ water level measurements available. In this study, we test the potential of RapidEye satellite images for indirectly reconstructing lake level changes. The lake levels are derived by intersecting water-land borders with a high-resolution digital elevation model (DEM). Based on Lake Fürstenseer (LF), we define requirements and limitations of the method. Water-land borders were extracted automatically from the 37 RapidEye images available for the period between 2009 and 2014. Otsu’s threshold was used for the NIR band and for the normalized difference water index (NDWI). The results were validated with in situ gauging, contour lines from the DEM, and in situ Differential Global Positioning System (DGPS) measurements of the shoreline. Using an ideal shoreline subset, the lake levels could be reconstructed with decimeter accuracy using the NIR water-land border, but the levels were systematically underestimated by 0–20 cm. The accuracy of the reconstructed lake level retrieval strongly depends on the precision of the water-land border retrieval, on the accuracy of the DEM, and on the lake level itself. A clear shift of the water-land border with increasing lake level is also essential for the unambiguous reconstruction of different levels. This shift needs to be several times larger than the pixel size. The biggest challenges for lake level reconstruction are the presence of vegetation at the shorelines, the quality of the topographic data in the underwater area, the slope of the shoreline, and shadows in combination with low solar angles.
Highlights
The glacial landscape of the northeastern Central European lowlands in Germany and Poland is characterized by a high number of natural lakes
Monitoring lake level changes remains a hot topic as only ca. 500 of the ca. 5000 lakes in northeastern Germany have regular gauging stations [59,60] and because the RapidEye time series analysis in this study clearly showed the significance of lake level and shoreline changes for ecologic and economic reasons: Within one season, between April 2009 and September 2009, the size of the sandbank decreased by 90% and within one year the sandbank and shallow sandy beaches were completely flooded
We measured lake levels indirectly by combining information on the water-land borders derived from high-resolution multi-spectral satellite images (RapidEye) and high-resolution topographic data
Summary
The glacial landscape of the northeastern Central European lowlands in Germany and Poland is characterized by a high number of natural lakes. Most are groundwater lakes whose water levels are linked to the local uncovered aquifer. Groundwater and precipitation determine the inflow, evapotranspiration the outflow [1,2]. These processes affect the natural dynamic of the lakes and lake level changes. In addition to natural level fluctuations, human interference such as land use and hydromelioration, as well as climate change, influence lake levels [3,4]. Lakes in the northeastern Central European lowlands play an important role in ecosystem functions [1]. The most important services of lakes are the protection of biodiversity, water and carbon storage as well as their recreational value (tourism) [4]
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