Abstract
Accurate photovoltaic (PV) prediction has a very positive effect on many problems that power grids can face when there is a high penetration of variable energy sources. This problem can be addressed with computational intelligence algorithms such as neural networks and Evolutionary Optimization. The purpose of this article is to analyze three different hybridizations between physical models and artificial neural networks: the first hybridization combines neural networks with the output of the five-parameter physical model of a photovoltaic module in which the parameters are obtained from a datasheet. In the second hybridization, the parameters are obtained from a matching procedure with historical data exploiting Social Network Optimization. Finally, the third hybridization is PHANN, in which clear sky irradiation is used as an input. These three hybrid methods are compared with two physical approaches and simple neural network-based forecasting. The results show that the hybridization is very effective for achieving good forecasting results, while the performance of the three hybrid methods is comparable.
Highlights
In the last 20 years, the penetration of renewable energy sources (RESs) in energy systems around the world has progressively increased due to the rise of environmental concerns and governmental policies
We found that those obtained from the Social Network Optimization (SNO) matching procedure differed greatly from those obtained from datasheets: in particular, they lost part of their physical meaning because the optimization procedure choses them to reduce the error introduced by the weather forecast
The performance and the specific features of three hybrid models have been analyzed on real measurement data acquired at SolarTechLAB
Summary
In the last 20 years, the penetration of renewable energy sources (RESs) in energy systems around the world has progressively increased due to the rise of environmental concerns and governmental policies. The most important and challenging problem arising from the great penetration of PV in electrical systems is the high level of variability in the power supplied. This strictly depends on local weather conditions, such as cloud cover, temperature, wind speed and atmospheric aerosol levels. Large frequency oscillations can be induced by abrupt changes in power; secondly, in the case of the high penetration of renewables, reverse active power flows may occur in the medium-voltage distribution power supply, or even in the high-voltage transmission line
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