Abstract

Wind Energy generation depends on the existence of wind, a meteorological phenomena intermittent by nature, with the consequence of generating uncertainty on the availability of wind energy in the future. The grid stability processes require continuous forecasting of wind energy generated. Forecasting wind energy can be performed either by using weather forecast data or by projecting (or regressing) the past time-series data observations into the future. This last method is the statistical or time series approach. Wind Time Series show non-linearity and non-stationarity properties, and these two properties increase the complexity of the forecasting task using statistical methodologies. In this paper we explore the use of deep learning techniques, which can represent non-linearity, to the wind speed prediction using the largest public wind dataset available, the Wind Toolkit from the National Renewable Laboratory of the US. Several deep network architectures like Multi Layer Perceptrons, Convolutional Networks or Recurrent Networks have been tested on the 126,692 wind-sites and with the results obtained valuable comparisons and conclusions have been obtained. The distribution of the wind sites across the North American Geography has allowed to include in the analysis relationships between terrain, wind forecast complexity and deep methods. With the developed testing workbench and with the availability of the Barcelona Supercomputing Center new architectures are being developed. This work concludes with the feasibility of deep learning architectures for the wind and energy forecasting.

Highlights

  • The energy industry is changing its dependence on fossil fuels by investing heavily in the generation using renewable sources

  • In this paper we explore the use of deep learning techniques, which can represent non-linearity, to the wind speed prediction using the largest public wind dataset available, the Wind Toolkit from the National Renewable Laboratory of the US

  • Deep Learning ensemble methods applied to the National Renewable Laboratory (NREL) dataset is another area of further work

Read more

Summary

Introduction

The energy industry is changing its dependence on fossil fuels by investing heavily in the generation using renewable sources. This work has developed experiments with Several deep learning architectures and applied them to all the wind sites, which has allowed to obtain conclusions from a very large resource of data. In this work the optimizer used has been Adamax and elements like early-stopping have been included in the architectures [12] This model is applied to real data and generates a prediction result that needs to be rated based on the accuracy observed, and in our case we have chosen the R2 or coefficient of determination which is a very informative measure for linear and non-linear regression problems [13]. The resulting model will apply the learned structures to new data in order to perform a forecast or a regression of the curve (wind speed in this application).

Comparisons and results analysis
Conclusions and future Work

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.