TY - GEN
T1 - Spatiotemporal soil moisture estimation for agricultural drought risk management
AU - Kulaglic, Ajla
AU - Üstündaǧ, B. Berk
AU - Baǧiş, Serdar
PY - 2013
Y1 - 2013
N2 - In this study we proposed a new spatiotem poral soil moisture estimation model for nowcasting and forecasting of the agricultural drought. Temporal rain, irrigation coverage, normalized difference vegetation index (NDVI) and parcel based evapotranspiration data are used as inputs of a multiple-input time-delay neural network for spatiotemporal multi-depth soil moisture estimation. For this purpose, we combined the outcome of another study that provides conversion of multi-temporal satellite image originated NDVT data to spatiotemporal NDVT data. Agricultural drought and water stress risk management are complex processes since they are not only dependent on soil structure and climatic parameters but also they have relevance to plant cover status. Our soil moisture estimation model provides nowcasting ability for water-stress management. It also provides drought forecast information in order to utilize water resources in an optimal way for yield loss reduction. The main capability of this method depends on the applicability of both past time-window data and weather forecast information as the future data to the trained neural network. Agro-meteorological data from randomly placed 6 stations, chosen to be within different agricultural fields, are used in this study. Soil moisture estimation model was performed through a 4-layer time-delay neural network. Past and predicted meteorological parameters are used as a part of inputs to the neural network. We have shown that estimated soil moisture has approximately 3% root mean square error at 15cm and 45cm depths of reference verification points.
AB - In this study we proposed a new spatiotem poral soil moisture estimation model for nowcasting and forecasting of the agricultural drought. Temporal rain, irrigation coverage, normalized difference vegetation index (NDVI) and parcel based evapotranspiration data are used as inputs of a multiple-input time-delay neural network for spatiotemporal multi-depth soil moisture estimation. For this purpose, we combined the outcome of another study that provides conversion of multi-temporal satellite image originated NDVT data to spatiotemporal NDVT data. Agricultural drought and water stress risk management are complex processes since they are not only dependent on soil structure and climatic parameters but also they have relevance to plant cover status. Our soil moisture estimation model provides nowcasting ability for water-stress management. It also provides drought forecast information in order to utilize water resources in an optimal way for yield loss reduction. The main capability of this method depends on the applicability of both past time-window data and weather forecast information as the future data to the trained neural network. Agro-meteorological data from randomly placed 6 stations, chosen to be within different agricultural fields, are used in this study. Soil moisture estimation model was performed through a 4-layer time-delay neural network. Past and predicted meteorological parameters are used as a part of inputs to the neural network. We have shown that estimated soil moisture has approximately 3% root mean square error at 15cm and 45cm depths of reference verification points.
KW - Agricultural droughty soil moisture estimation
KW - Irrigation
KW - Nowcasting
KW - TARBIL
KW - Time-delay neural network
UR - http://www.scopus.com/inward/record.url?scp=84888863159&partnerID=8YFLogxK
U2 - 10.1109/Argo-Geoinformatics.2013.6621883
DO - 10.1109/Argo-Geoinformatics.2013.6621883
M3 - Conference contribution
AN - SCOPUS:84888863159
SN - 9781479908684
T3 - 2013 2nd International Conference on Agro-Geoinformatics: Information for Sustainable Agriculture, Agro-Geoinformatics 2013
SP - 76
EP - 81
BT - 2013 2nd International Conference on Agro-Geoinformatics
T2 - 2013 2nd International Conference on Agro-Geoinformatics: Information for Sustainable Agriculture, Agro-Geoinformatics 2013
Y2 - 12 August 2013 through 16 August 2013
ER -