Wind power prediction using a three stage genetic ensemble and auxiliary predictor
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- @Article{SHAHID:2020:ASC,
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author = "Farah Shahid and Asifullah Khan and Aneela Zameer and
Junaid Arshad and Kamran Safdar",
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title = "Wind power prediction using a three stage genetic
ensemble and auxiliary predictor",
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journal = "Applied Soft Computing",
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year = "2020",
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volume = "90",
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pages = "106151",
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month = may,
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keywords = "genetic algorithms, genetic programming, Wind power
prediction, Computational intelligence, Artificial
neural networks (ANN), Genetic programming (GP), Radial
basis function (RBF), Relevance vector machine (RVM)",
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ISSN = "1568-4946",
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DOI = "doi:10.1016/j.asoc.2020.106151",
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URL = "http://www.sciencedirect.com/science/article/pii/S1568494620300910",
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size = "15 pages",
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abstract = "This paper presents a novel method for accurate wind
power prediction by applying computational intelligence
approaches while exploiting Auxiliary Predictor (AxP)
and Genetic Programming (GP) based ensemble of Neural
Networks (AxP-GPNN). The inherent fluctuations in the
power generated by wind mills may affect their optimal
integration in the electric grid and therefore,
accurate prediction is highly desired. To cater these
fluctuations and highly nonlinear mapping, we present
an ensemble approach, where the auxiliary predictor is
constructed with Radial Basis Function (RBF) network
and Relevance Vector Machine (RVM) and various neural
networks are then employed as base regressors. Use of
RVM is based on its established advantages for robust
prediction on unseen data to address the overfitting
issue in training phase. AxP is used for suitable
weight initialization to base predictors and provides
initial decision space to base learners. Further, an
ensemble of neural networks based on GP is developed
which uses the base predictions of neural networks as
well as the auxiliary information generated by AxP. The
GP ensemble based forecasting engine is thus robust to
minor variations in the data as compared to the
individual base regressors. We also employ
information-theoretic feature selection on physical
measurements of the wind mills. Results have been
extracted in the form of statistical performance
indices including mean absolute error, standard
deviation error and mean square error. These error
measures are compared with the other existing wind
power prediction techniques. These results present
better wind power estimates and reduced prediction
error. Paired t-test for the proposed model with other
machine learning based models is carried out for
further evaluation. Overall, these comparisons validate
the importance of auxiliary predictor in ensemble model
of GP and ANNs",
- }
Genetic Programming entries for
Farah Shahid
Asifullah Khan
Aneela Zameer
Junaid Arshad
Kamran Safdar
Citations