Abstract
In this chapter an innovative method for one and seven-day forecast of electricity load is proposed. The new approach has been tested on three different cases from south-west Western Australia’s interconnected system. They have been tested under the most realistic conditions by considering only minimum and maximum forecasts of temperature and relative humidity as available future inputs. Two different nonlinear approaches of neural networks and decision trees have been applied to fit proper models. A modified version of mean absolute percentage error (MMAPE) of each model over the test year is presented. By applying a developed criterion to recognize the dominant component of the electricity load, user of this work will be able to choose the most efficient forecasting method.
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Notes
- 1.
Also known as country goldfields.
- 2.
SWIS: South west interconnected system.
- 3.
The correlation between the load data decreases as the number of weeks increases. In this study the maximum number of two future weeks and two previous weeks has been used for missing data estimation.
- 4.
Quantile–Quantile or Q–Q plot is a graph that shows the probability of two distributions against each other. By using Q–Q plots similarities and differences of two different distributions can be investigated.
- 5.
Although sometimes these forecasts are available for every three hour of the following week, to avoid the loss of generality only minimum and maximum values of temperature and humidity are considered to be available to this framework at the time of forecasting.
- 6.
A list of Western Australian public holidays has been used to generate the holidays input variables.
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Moghaddam, M.K., Bahri, P.A. (2014). Development of a Novel Approach for Electricity Forecasting. In: Kim, H., Ao, SI., Amouzegar, M., Rieger, B. (eds) IAENG Transactions on Engineering Technologies. Lecture Notes in Electrical Engineering, vol 247. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-6818-5_45
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