dc.description.abstract |
The inception of remote sensing on the global technological horizon has eased out the
conventional field and laboratory-based time-taking soil health assessment techniques. The
utilisation of Machine Learning (ML) in remote sensing research has truly revolutionised
the modelling and estimation of crop yield and soil health parameters. Over the past many
decades, most of the remote sensing research directed at soil health was done alongside
crop monitoring or precision agriculture-related studies. Therefore, there is still a paucity
of dedicated research using multi-sensor remotely sensed data for soil health studies.
Optical-multispectral remotely sensed data had been widely used for the different soil type
mapping and generation of various soil health-related indices worldwide. Still, this data is
highly weather dependent and not readily available for days of having a cloud over the area
under study. Remotely sensed SAR data, on the other hand being an active sensor, has
penetration ability and all-weather, all-time data acquisition capability, but its soil healthrelated indices are highly data and target-dependent and are still under research. The field
gathered soil health-related parameters like moisture, salinity and Soil Organic Carbon
have been much relied upon for ages for soil-related research. However, this is a highly
labour-intensive exercise and requires costly apparatus and skilled manpower to be
deployed. This study aims to utilise both remotely sensed Microwave satellite data from
Sentinel-1 and Optical data from Sentinel-2, and field data to estimate three important soil
health parameters- Soil Moisture, Soil Salinity, and Soil Organic Carbon (SOC). After that,
the soil health parameters, SAR backscatter and field data were used to estimate wheat crop
yield. The study uses SAR backscatter of VV and VH polarisations from Sentinel-1,
Normalised Differential Moisture Index (NDMI) and Normalised Differential Salinity
Index (NDSI) from Sentinel-2, Volumetric Moisture Content (VMC), Electrical
Conductivity (EC), and Temperature from the field, with SOC and pH from a laboratory
test of soil samples. The data were used for the estimation of soil health parameters using
various machine learning techniques. The neural network model performed best in crop
yield estimation and gave R2
values of 0.712 and 0.635 in training and testing phases,
respectively and Mean Absolute Error (MAE) of 0.32 and Root Mean Square Error
(RMSE) value of 0.54. The novel feature of this study is that since Sentinel-1 SAR data
operates in C-band with less penetration in vegetation, the study estimates soil health
parameters for early stages of wheat crop growth when soil lies mostly exposed and utilises the estimates for crop yield prediction. This study has importance for early mitigation and
monitoring of soil health when there is no availability of longer wavelength SAR data. |
en_US |