Modelling of Energy Consumption in Wheat Production Using Neural Networks “Case Study in Canterbury Province, New Zealand“
An artificial neural network (ANN) approach was used to model the energy consumption of wheat production. This study was conducted over 35,300 hectares of irrigated and dry land wheat fields in Canterbury in the 2007-2008 harvest year.1 In this study several direct and indirect factors have been used to create an artificial neural networks model to predict energy use in wheat production. The final model can predict energy consumption by using farm condition (size of wheat area and number paddocks), farmers- social properties (education), and energy inputs (N and P use, fungicide consumption, seed consumption, and irrigation frequency), it can also predict energy use in Canterbury wheat farms with error margin of ±7% (± 1600 MJ/ha).
[1] Pellizzi G. Use of energy and labour in Italian agriculture. Journal of
Agricultural Engineering Research. 1992;52:111-9.
[2] Al-Ghandoor A, Jaber JO, Al-Hinti I, Mansour IM. Residential past and
future energy consumption: Potential savings and environmental impact.
Renewable and Sustainable Energy Reviews. 2009;13(6-7):1262-74.
[3] Tester JW. Sustainable energy : choosing among options. Cambridge,
Mass.: MIT Press, 2005.
[4] Sözen A. Future projection of the energy dependency of Turkey using
artificial neural network. Energy Policy. 2009;37(11):4827-33.
[5] Jebaraj S, Iniyan S. A review of energy models. Renewable and
Sustainable Energy Reviews. 2006;10(4):281-311.
[6] Fang Q, Hanna MA, Haque E, Spillman CK. Neural Network Modeling
Of Energy Requirments, For Size Reduction Of Wheat. ASAE.
2000;43(4): 947-952.
[7] Hornik K, Stinchocombe M, White H. Multilayer feedforward networks
are universal approximators. Elsevier Science Ltd Oxford, UK, UK
1989;2(5).
[8] Heinzow T, Tol RSJ. Prediction of crop yields across four climate zones
in Germany: an artificial neural network approach. Centre for Marine
and Climate Research, Hamburg University, Hamburg. 2003.
[9] Kalogirou SA. Artificial neural networks in renewable energy systems
applications: a review. Renewable and Sustainable Energy Reviews.
2001;5(4):373-401.
[10] Javeed Nizami S, Al-Garni AZ. Forecasting electric energy consumption
using neural networks. Energy Policy. 1995;23(12):1097-104.
[11] Mohandes MA, Rehman S, Halawani TO. A neural networks approach
for wind speed prediction. Renewable Energy. 1998;13(3):345-54.
[12] Kalogirou SA, Bojic M. Artificial neural networks for the prediction of
the energy consumption of a passive solar building. energy.
2000;25(5):479-91.
[13] Kalogirou SA. Applications of artificial neural-networks for energy
systems. Applied Energy. 2000;67(1-2):17-35.
[14] Aydinalp M, Ismet Ugursal V, Fung AS. Modeling of the appliance,
lighting, and space-cooling energy consumptions in the residential sector
using neural networks. Applied Energy. 2002;71(2):87-110.
[15] Hsu C-C, Chen C-Y. Regional load forecasting in Taiwan--applications
of artificial neural networks. Energy Conversion and Management.
2003;44(12):1941-9.
[16] Hagan M, Demuth H, Beale M. Neural network design: Boston, USA:
PWS Publishing Company, 2002.
[17] Samarasinghe S. Neural networks for applied sciences and engineering :
from fundamentals to complex pattern recognition. Boca Raton, FL:
Auerbach, 2007.
[1] Pellizzi G. Use of energy and labour in Italian agriculture. Journal of
Agricultural Engineering Research. 1992;52:111-9.
[2] Al-Ghandoor A, Jaber JO, Al-Hinti I, Mansour IM. Residential past and
future energy consumption: Potential savings and environmental impact.
Renewable and Sustainable Energy Reviews. 2009;13(6-7):1262-74.
[3] Tester JW. Sustainable energy : choosing among options. Cambridge,
Mass.: MIT Press, 2005.
[4] Sözen A. Future projection of the energy dependency of Turkey using
artificial neural network. Energy Policy. 2009;37(11):4827-33.
[5] Jebaraj S, Iniyan S. A review of energy models. Renewable and
Sustainable Energy Reviews. 2006;10(4):281-311.
[6] Fang Q, Hanna MA, Haque E, Spillman CK. Neural Network Modeling
Of Energy Requirments, For Size Reduction Of Wheat. ASAE.
2000;43(4): 947-952.
[7] Hornik K, Stinchocombe M, White H. Multilayer feedforward networks
are universal approximators. Elsevier Science Ltd Oxford, UK, UK
1989;2(5).
[8] Heinzow T, Tol RSJ. Prediction of crop yields across four climate zones
in Germany: an artificial neural network approach. Centre for Marine
and Climate Research, Hamburg University, Hamburg. 2003.
[9] Kalogirou SA. Artificial neural networks in renewable energy systems
applications: a review. Renewable and Sustainable Energy Reviews.
2001;5(4):373-401.
[10] Javeed Nizami S, Al-Garni AZ. Forecasting electric energy consumption
using neural networks. Energy Policy. 1995;23(12):1097-104.
[11] Mohandes MA, Rehman S, Halawani TO. A neural networks approach
for wind speed prediction. Renewable Energy. 1998;13(3):345-54.
[12] Kalogirou SA, Bojic M. Artificial neural networks for the prediction of
the energy consumption of a passive solar building. energy.
2000;25(5):479-91.
[13] Kalogirou SA. Applications of artificial neural-networks for energy
systems. Applied Energy. 2000;67(1-2):17-35.
[14] Aydinalp M, Ismet Ugursal V, Fung AS. Modeling of the appliance,
lighting, and space-cooling energy consumptions in the residential sector
using neural networks. Applied Energy. 2002;71(2):87-110.
[15] Hsu C-C, Chen C-Y. Regional load forecasting in Taiwan--applications
of artificial neural networks. Energy Conversion and Management.
2003;44(12):1941-9.
[16] Hagan M, Demuth H, Beale M. Neural network design: Boston, USA:
PWS Publishing Company, 2002.
[17] Samarasinghe S. Neural networks for applied sciences and engineering :
from fundamentals to complex pattern recognition. Boca Raton, FL:
Auerbach, 2007.
@article{"International Journal of Biological, Life and Agricultural Sciences:64113", author = "M. Safa and S. Samarasinghe", title = "Modelling of Energy Consumption in Wheat Production Using Neural Networks “Case Study in Canterbury Province, New Zealand“", abstract = "An artificial neural network (ANN) approach was used to model the energy consumption of wheat production. This study was conducted over 35,300 hectares of irrigated and dry land wheat fields in Canterbury in the 2007-2008 harvest year.1 In this study several direct and indirect factors have been used to create an artificial neural networks model to predict energy use in wheat production. The final model can predict energy consumption by using farm condition (size of wheat area and number paddocks), farmers- social properties (education), and energy inputs (N and P use, fungicide consumption, seed consumption, and irrigation frequency), it can also predict energy use in Canterbury wheat farms with error margin of ±7% (± 1600 MJ/ha).
", keywords = "Artificial neural network, Canterbury, energy consumption, modelling, New Zealand, wheat.", volume = "4", number = "12", pages = "931-5", }
