Reference:
J. Lago,
K. De Brabandere,
F. De Ridder, and
B. De Schutter,
"Short-term forecasting of solar irradiance without local telemetry: A
generalized model using satellite data," Solar Energy, vol.
173, pp. 566-577, Oct. 2018.
Abstract:
Due to the increasing integration of solar power into the electrical
grid, forecasting short-term solar irradiance has become key for many
applications, e.g. operational planning, power purchases, reserve
activation, etc. In this context, as solar generators are
geographically dispersed and ground measurements are not always easy
to obtain, it is very important to have general models that can
predict solar irradiance without the need of local data. In this
paper, a model that can perform short-term forecasting of solar
irradiance in any general location without the need of ground
measurements is proposed. To do so, the model considers
satellite-based measurements and weather-based forecasts, and employs
a deep neural network structure that is able to generalize across
locations; particularly, the network is trained only using a small
subset of sites where ground data is available, and the model is able
to generalize to a much larger number of locations where ground data
does not exist. As a case study, 25 locations in The Netherlands are
considered and the proposed model is compared against four local
models that are individually trained for each location using ground
measurements. Despite the general nature of the model, it is shown
show that the proposed model is equal or better than the local models:
when comparing the average performance across all the locations and
prediction horizons, the proposed model obtains a 31.31% rRMSE
(relative root mean square error) while the best local model achieves
a 32.01% rRMSE.