Statistics of building-specific load forecasting models

Forecasting of daily loads is crucial for the Distribution System Operators (DSO). Contemporary short-term load forecasting models (STLF) are very well recognized and described in numerous articles. One of such models is the Adaptive Neuro-Fuzzy Inference System (ANFIS), which requires a large set of historical data. A well-recognized issue both for the ANFIS and other daily load forecasting models is the selection of exogenous variables. This article attempts to verify the statement that an appropriate selection of exogenous variables of the ANFIS model affects the accuracy of the forecasts obtained ex post. This proposal seems to be a return to the roots of the Polish econometrics school and the use of the Hellwig method to select exogenous variables of the ANFIS model. In this context, it is also worth asking whether the use of the Hellwig method in conjunction with the ANFIS model makes it possible to investigate the significance of weather variables on the profile of the daily load in an energy company. The functioning of the ANFIS model was tested for some consumers exhibiting high load randomness located within the area under supervision of the examined power company. The load curves featuring seasonal variability and weekly similarity are suitable for forecasting with the ANFIS model. The Hellwig method has been used to select exogenous variables in the ANFIS model. The optimal set of variables has been determined on the basis of integral indicators of information capacity H. Including an additional variable, i.e., air temperature, has also been taken into consideration. Some results of ex post daily load forecast are presented.

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Short-term Load Forecasting by Using Improved GEP and Abnormal Load Recognition

ACM Transactions on Internet Technology ◽

10.1145/3447513 ◽

2021 ◽

Vol 21 (4) ◽

pp. 1-28

Author(s):

Song Deng ◽

Fulin Chen ◽

Xia Dong ◽

Guangwei Gao ◽

Xindong Wu

Keyword(s):

Gene Expression ◽

Probability Distribution ◽

Detection Rate ◽

Cross Validation ◽

Normal Load ◽

Gene Expression Programming ◽

Load Forecasting ◽

Short Term ◽

Forecasting Models ◽

Short Term Load Forecasting

Load forecasting in short term is very important to economic dispatch and safety assessment of power system. Although existing load forecasting in short-term algorithms have reached required forecast accuracy, most of the forecasting models are black boxes and cannot be constructed to display mathematical models. At the same time, because of the abnormal load caused by the failure of the load data collection device, time synchronization, and malicious tampering, the accuracy of the existing load forecasting models is greatly reduced. To address these problems, this article proposes a Short-Term Load Forecasting algorithm by using Improved Gene Expression Programming and Abnormal Load Recognition (STLF-IGEP_ALR). First, the Recognition algorithm of Abnormal Load based on Probability Distribution and Cross Validation is proposed. By analyzing the probability distribution of rows and columns in load data, and using the probability distribution of rows and columns for cross-validation, misjudgment of normal load in abnormal load data can be better solved. Second, by designing strategies for adaptive generation of population parameters, individual evolution of populations and dynamic adjustment of genetic operation probability, an Improved Gene Expression Programming based on Evolutionary Parameter Optimization is proposed. Finally, the experimental results on two real load datasets and one open load dataset show that compared with the existing abnormal data detection algorithms, the algorithm proposed in this article have higher advantages in missing detection rate, false detection rate and precision rate, and STLF-IGEP_ALR is superior to other short-term load forecasting algorithms in terms of the convergence speed, MAE, MAPE, RSME, and R 2 .

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New Short Term Load Forecasting models based on growth rate scaling and simple averaging

2016 IEEE 6th International Conference on Power Systems (ICPS) ◽

10.1109/icpes.2016.7584177 ◽

2016 ◽

Cited By ~ 1

Author(s):

Sreenu Sreekumar ◽

Jatin Verma ◽

Sujil A ◽

Rajesh Kumar

Keyword(s):

Growth Rate ◽

Load Forecasting ◽

Short Term ◽

Forecasting Models ◽

Short Term Load Forecasting

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A Power Load Forecasting Model Based on FA-CSSA-ELM

Mathematical Problems in Engineering ◽

10.1155/2021/9965932 ◽

2021 ◽

Vol 2021 ◽

pp. 1-14

Author(s):

Zuoxun Wang ◽

Xinheng Wang ◽

Chunrui Ma ◽

Zengxu Song

Keyword(s):

Search Algorithm ◽

Load Forecasting ◽

Local Optimum ◽

Chaotic Mapping ◽

Forecasting Models ◽

Power Resources ◽

Power Load ◽

Power Load Forecasting ◽

Learning Machine ◽

Grid Operation

Accurate and stable power load forecasting methods are essential for the rational allocation of power resources and grid operation. Due to the nonlinear nature of power loads, it is difficult for a single forecasting method to complete the forecasting task accurately and quickly. In this study, a new combined model for power loads forecasting is proposed. The initial weights and thresholds of the extreme learning machine (ELM) optimized by the chaotic sparrow search algorithm (CSSA) and improved by the firefly algorithm (FA) are used to improve the forecasting performance and achieve accurate forecasting. The early local optimum that exists in the sparrow algorithm is overcome by Tent chaotic mapping. A firefly perturbation strategy is used to improve the global optimization capability of the model. Real values from a power grid in Shandong are used to validate the prediction performance of the proposed FA-CSSA-ELM model. Experiments show that the proposed model produces more accurate forecasting results than other single forecasting models or combined forecasting models.

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Application Data for Electricity Load Forecasting Models

2019 5th International Conference on Engineering, Applied Sciences and Technology (ICEAST) ◽

10.1109/iceast.2019.8802527 ◽

2019 ◽

Author(s):

Sooppasek Katruksa ◽

Somchat Jiriwibhakorn

Keyword(s):

Load Forecasting ◽

Forecasting Models ◽

Application Data ◽

Electricity Load ◽

Electricity Load Forecasting

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Short-Term Load Forecasting in Smart Grids: An Intelligent Modular Approach

Energies ◽

10.3390/en12010164 ◽

2019 ◽

Vol 12 (1) ◽

pp. 164 ◽

Cited By ~ 32

Author(s):

Ashfaq Ahmad ◽

Nadeem Javaid ◽

Abdul Mateen ◽

Muhammad Awais ◽

Zahoor Ali Khan

Keyword(s):

Neural Network ◽

Artificial Neural Network ◽

Execution Time ◽

Smart Grids ◽

Load Forecasting ◽

Forecast Accuracy ◽

Forecasting Model ◽

Exogenous Variables ◽

Forecasting Models ◽

The Third

Daily operations and planning in a smart grid require a day-ahead load forecasting of its customers. The accuracy of day-ahead load-forecasting models has a significant impact on many decisions such as scheduling of fuel purchases, system security assessment, economic scheduling of generating capacity, and planning for energy transactions. However, day-ahead load forecasting is a challenging task due to its dependence on external factors such as meteorological and exogenous variables. Furthermore, the existing day-ahead load-forecasting models enhance forecast accuracy by paying the cost of increased execution time. Aiming at improving the forecast accuracy while not paying the increased executions time cost, a hybrid artificial neural network-based day-ahead load-forecasting model for smart grids is proposed in this paper. The proposed forecasting model comprises three modules: (i) a pre-processing module; (ii) a forecast module; and (iii) an optimization module. In the first module, correlated lagged load data along with influential meteorological and exogenous variables are fed as inputs to a feature selection technique which removes irrelevant and/or redundant samples from the inputs. In the second module, a sigmoid function (activation) and a multivariate auto regressive algorithm (training) in the artificial neural network are used. The third module uses a heuristics-based optimization technique to minimize the forecast error. In the third module, our modified version of an enhanced differential evolution algorithm is used. The proposed method is validated via simulations where it is tested on the datasets of DAYTOWN (Ohio, USA) and EKPC (Kentucky, USA). In comparison to two existing day-ahead load-forecasting models, results show improved performance of the proposed model in terms of accuracy, execution time, and scalability.

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