Demand Response Potential Day-Ahead Forecasting Approach Based on LSSA-BPNN Considering the Electricity-Carbon Coupling Incentive Effects

In order to address the challenges of global climate change and to achieve the goals of sustainable development, the need for a low-carbon transition of the power system is becoming more urgent. However, previous demand response (DR) potential forecasting models for load aggregators (LAs) only consi...

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Bibliographic Details
Published in:IEEE transactions on industry applications Vol. 60; no. 3; pp. 4505 - 4516
Main Authors: Zhang, Yiran, Ge, Xinxin, Li, Meiyi, Li, Nan, Wang, Fei, Wang, Liyong, Sun, Qinfei
Format: Journal Article
Language:English
Published: New York IEEE 01.05.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Artificial neural networks
Back propagation networks
Biological system modeling
Carbon
Carbon dioxide
Carbon emissions
Climate change
Customers
Data models
Day-ahead forecasting
Demand response
demand response potential
Economic impact
Electric potential
Electric power demand
Electric power systems
Electricity
electricity-carbon coupling
Electrode potentials
Emissions
Energy management
Forecasting
Home automation
load aggregator
Load modeling
low-carbon
Low-carbon economy
Neural networks
Power consumption
Power system planning
Redundancy
Residential energy
Search algorithms
Sustainable development
ISSN:0093-9994, 1939-9367
Online Access:Get full text
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Summary:In order to address the challenges of global climate change and to achieve the goals of sustainable development, the need for a low-carbon transition of the power system is becoming more urgent. However, previous demand response (DR) potential forecasting models for load aggregators (LAs) only consider the potential for customers to adjust their loads, without fully exploiting the potential to reduce their carbon emissions. To this end, a logistic sparrow search algorithm- back propagation neural network (LSSA-BPNN) based DR potential and carbon reduction potential forecasting model for LAs is proposed in this paper, which considers the dual incentive of electricity and carbon. First, a novel home energy management system (HEMS) model is developed, which considers the dual incentive of electricity and carbon. The model's objective function consists of two components: minimizing economic costs and reducing carbon emissions. Weight coefficients are introduced to characterize the power consumption preferences of different customer types. Subsequently, simulations are conducted to generate data related to DR potential and carbon reduction potential of LAs. Second, the multiple influencing features of DR potential and carbon reduction potential are sorted according to the degree of importance by the RF model respectively, which could reduce the redundancy of input features. Finally, based on the selected features, the LSSA-BPNN model is established to obtain the forecasting results of the DR potential and carbon reduction potential for LAs. The effectiveness and superiority of the proposed model have been verified using a real dataset in Austin.
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ISSN:0093-9994
1939-9367
DOI:10.1109/TIA.2024.3372942