Abstract
Algorithm for determining crop harvesting dates based on time series of coherence and backscattering coefficient ( σ 0 ) derived from Sentinel-1 single look complex (SLC) synthetic-aperture radar (SAR) images is proposed. The algorithm allows the ability to monitor harvesting over large areas without having to install additional sensors on agricultural machinery. Coherence between SAR images allows the ability to track changes in field-scatterers configuration resulting from agricultural work. The proposed algorithm finds a step-like increase in coherence that occurs after the harvesting and is related to the conversion of a field into a bare soil area. An additional check of potential harvest dates is carried out by threshold values of σ 0 depending on vegetation height. The algorithm is adapted for the monitoring of non-homogeneous fields with traces of erosion and insertions of fallow land. The algorithm was tested on agricultural fields located in the north of Kazakhstan. The obtained accuracy (mean absolute error = 6.5 days) of determining the dates of harvesting can be deemed satisfactory. This accuracy can be increased by shortening the interval between observations from 12 to 6 days when using data from both Sentinel-1 satellites.
Highlights
Ground, unmanned aerial vehicle (UAV) and global positioning system (GPS) satellite observations over the agricultural machinery are widely used for monitoring of harvesting [1,2]
The algorithm registers a step-like growth of coherence which appears after harvesting and is related to the field transformation into the area of bare land
Harvesting potential dates are verified by σ0 value
Summary
Ground, unmanned aerial vehicle (UAV) and global positioning system (GPS) satellite observations over the agricultural machinery are widely used for monitoring of harvesting [1,2]. Installation of various sensors allows to monitor position, velocity and other meaningful parameters of harvesters in real time. A necessary component of such monitoring systems is geoinformation system (GIS) enabling tracking of harvesters’ operation within the boundaries of fields. A limitation of this approach is the high cost of sensors installation, reception and processing of their readings as well as development and maintenance of a special GIS. An irreplaceable instrument in monitoring large areas of crops is satellite remote sensing data. For implementation of the monitoring, it is necessary to cover the investigated area with the satellite data enabling reliable detection of the fact of harvesting
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