ILB: Graph Neural Network Enabled Emergency Demand Response Program For
Electricity
- URL: http://arxiv.org/abs/2310.00129v1
- Date: Fri, 29 Sep 2023 20:38:04 GMT
- Title: ILB: Graph Neural Network Enabled Emergency Demand Response Program For
Electricity
- Authors: Sina Shaham, Bhaskar Krishnamachari, Matthew Kahn
- Abstract summary: In times of crisis, an emergency Demand Response program is required to manage unexpected spikes in energy demand.
We propose the Incentive-Driven Load Balancer (ILB), a program designed to efficiently manage demand and response during crisis situations.
We introduce a two-step machine learning-based framework for participant selection, which employs a graph-based approach to identify households capable of easily adjusting their electricity consumption.
- Score: 6.123324869194196
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Demand Response (DR) programs have become a crucial component of smart
electricity grids as they shift the flexibility of electricity consumption from
supply to demand in response to the ever-growing demand for electricity. In
particular, in times of crisis, an emergency DR program is required to manage
unexpected spikes in energy demand. In this paper, we propose the
Incentive-Driven Load Balancer (ILB), a program designed to efficiently manage
demand and response during crisis situations. By offering incentives to
flexible households likely to reduce demand, the ILB facilitates effective
demand reduction and prepares them for unexpected events. To enable ILB, we
introduce a two-step machine learning-based framework for participant
selection, which employs a graph-based approach to identify households capable
of easily adjusting their electricity consumption. This framework utilizes two
Graph Neural Networks (GNNs): one for pattern recognition and another for
household selection. Through extensive experiments on household-level
electricity consumption in California, Michigan, and Texas, we demonstrate the
ILB program's significant effectiveness in supporting communities during
emergencies.
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