Empowering Prosumer Communities in Smart Grid with Wireless
Communications and Federated Edge Learning
- URL: http://arxiv.org/abs/2104.03169v1
- Date: Wed, 7 Apr 2021 14:57:57 GMT
- Title: Empowering Prosumer Communities in Smart Grid with Wireless
Communications and Federated Edge Learning
- Authors: Afaf Taik and Boubakr Nour and Soumaya Cherkaoui
- Abstract summary: The exponential growth of distributed energy resources is enabling the transformation of traditional consumers in the smart grid into prosumers.
We propose a multi-level pro-decision framework for prosumer communities to achieve collective goals.
In addition to preserving prosumers' privacy, we show through evaluations that training prediction models using Federated Learning yields high accuracy for different energy resources.
- Score: 5.289693272967054
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The exponential growth of distributed energy resources is enabling the
transformation of traditional consumers in the smart grid into prosumers. Such
transition presents a promising opportunity for sustainable energy trading.
Yet, the integration of prosumers in the energy market imposes new
considerations in designing unified and sustainable frameworks for efficient
use of the power and communication infrastructure. Furthermore, several issues
need to be tackled to adequately promote the adoption of decentralized
renewable-oriented systems, such as communication overhead, data privacy,
scalability, and sustainability. In this article, we present the different
aspects and challenges to be addressed for building efficient energy trading
markets in relation to communication and smart decision-making. Accordingly, we
propose a multi-level pro-decision framework for prosumer communities to
achieve collective goals. Since the individual decisions of prosumers are
mainly driven by individual self-sufficiency goals, the framework prioritizes
the individual prosumers' decisions and relies on 5G wireless network for fast
coordination among community members. In fact, each prosumer predicts energy
production and consumption to make proactive trading decisions as a response to
collective-level requests. Moreover, the collaboration of the community is
further extended by including the collaborative training of prediction models
using Federated Learning, assisted by edge servers and prosumer home-area
equipment. In addition to preserving prosumers' privacy, we show through
evaluations that training prediction models using Federated Learning yields
high accuracy for different energy resources while reducing the communication
overhead.
Related papers
- Communication Learning in Multi-Agent Systems from Graph Modeling Perspective [62.13508281188895]
We introduce a novel approach wherein we conceptualize the communication architecture among agents as a learnable graph.
We introduce a temporal gating mechanism for each agent, enabling dynamic decisions on whether to receive shared information at a given time.
arXiv Detail & Related papers (2024-11-01T05:56:51Z) - Decentralized Coordination of Distributed Energy Resources through Local Energy Markets and Deep Reinforcement Learning [1.8434042562191815]
Transactive energy, implemented through local energy markets, has recently garnered attention as a promising solution to the grid challenges.
This study addresses the gap by training a set of deep reinforcement learning agents to automate end-user participation in ALEX.
The study unveils a clear correlation between bill reduction and reduced net load variability in this setup.
arXiv Detail & Related papers (2024-04-19T19:03:33Z) - Privacy-Preserving Joint Edge Association and Power Optimization for the
Internet of Vehicles via Federated Multi-Agent Reinforcement Learning [74.53077322713548]
We investigate the privacy-preserving joint edge association and power allocation problem.
The proposed solution strikes a compelling trade-off, while preserving a higher privacy level than the state-of-the-art solutions.
arXiv Detail & Related papers (2023-01-26T10:09:23Z) - Design and Planning of Flexible Mobile Micro-Grids Using Deep
Reinforcement Learning [0.0]
The design and planning strategy of a mobile multi-energy supply system for a nomadic community is investigated.
Deep Reinforcement Learning is implemented for the design and planning problem tackled.
The results on a case study for ger communities in Mongolia suggest that mobile nomadic energy systems can be both technically and economically feasible.
arXiv Detail & Related papers (2022-12-08T08:30:50Z) - Distributed Energy Management and Demand Response in Smart Grids: A
Multi-Agent Deep Reinforcement Learning Framework [53.97223237572147]
This paper presents a multi-agent Deep Reinforcement Learning (DRL) framework for autonomous control and integration of renewable energy resources into smart power grid systems.
In particular, the proposed framework jointly considers demand response (DR) and distributed energy management (DEM) for residential end-users.
arXiv Detail & Related papers (2022-11-29T01:18:58Z) - FedREP: Towards Horizontal Federated Load Forecasting for Retail Energy
Providers [1.1254693939127909]
We propose a novel horizontal privacy-preserving federated learning framework for energy load forecasting, namely FedREP.
We consider a federated learning system consisting of a control centre and multiple retailers by enabling multiple REPs to build a common, robust machine learning model without sharing data.
For forecasting, we use a state-of-the-art Long Short-Term Memory (LSTM) neural network due to its ability to learn long term sequences of observations.
arXiv Detail & Related papers (2022-03-01T04:16:19Z) - Optimal Power Allocation for Rate Splitting Communications with Deep
Reinforcement Learning [61.91604046990993]
This letter introduces a novel framework to optimize the power allocation for users in a Rate Splitting Multiple Access network.
In the network, messages intended for users are split into different parts that are a single common part and respective private parts.
arXiv Detail & Related papers (2021-07-01T06:32:49Z) - Virtual Microgrid Management via Software-defined Energy Network for
Electricity Sharing [10.13696311830345]
This article proposes an approach to build a virtual microgrid operated as a software-defined energy network (SDEN)
The proposed cyber-physical system presumes that electrical energy is shared among its members and that the energy sharing is enabled in the cyber domain by handshakes inspired by resource allocation methods utilized in computer networks, wireless communications, and peer-to-peer Internet applications (e.g., BitTorrent)
This article concludes that the proposed solution generally complies with the existing regulations but has highly disruptive potential to organize a dominantly electrified energy system in the mid- to long-term.
arXiv Detail & Related papers (2021-02-01T06:09:40Z) - A Hierarchical Approach to Multi-Energy Demand Response: From
Electricity to Multi-Energy Applications [1.5084441395740482]
This paper looks into an opportunity to control energy consumption of an aggregation of many residential, commercial and industrial consumers.
This ensemble control becomes a modern demand response contributor to the set of modeling tools for multi-energy infrastructure systems.
arXiv Detail & Related papers (2020-05-05T17:17:51Z) - A Deep Reinforcement Learning Framework for Continuous Intraday Market
Bidding [69.37299910149981]
A key component for the successful renewable energy sources integration is the usage of energy storage.
We propose a novel modelling framework for the strategic participation of energy storage in the European continuous intraday market.
An distributed version of the fitted Q algorithm is chosen for solving this problem due to its sample efficiency.
Results indicate that the agent converges to a policy that achieves in average higher total revenues than the benchmark strategy.
arXiv Detail & Related papers (2020-04-13T13:50:13Z) - Towards a Peer-to-Peer Energy Market: an Overview [68.8204255655161]
This work focuses on the electric power market, comparing the status quo with the recent trend towards the increase in distributed self-generation capabilities by prosumers.
We introduce a potential multi-layered architecture for a Peer-to-Peer (P2P) energy market, discussing the fundamental aspects of local production and local consumption as part of a microgrid.
To give a full picture to the reader, we also scrutinise relevant elements of energy trading, such as Smart Contract and grid stability.
arXiv Detail & Related papers (2020-03-02T20:32:10Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.