Related papers: Just In Time Transformers

Just In Time Transformers

URL: http://arxiv.org/abs/2410.16881v1
Date: Tue, 22 Oct 2024 10:33:00 GMT
Title: Just In Time Transformers
Authors: Ahmed Ala Eddine Benali, Massimo Cafaro, Italo Epicoco, Marco Pulimeno, Enrico Junior Schioppa,
Abstract summary: JITtrans is a novel transformer deep learning model that significantly improves energy consumption forecasting accuracy. Our findings highlight the potential of advanced predictive technologies to revolutionize energy management and advance sustainable power systems.
Score: 2.7350304370706797
License:
Abstract: Precise energy load forecasting in residential households is crucial for mitigating carbon emissions and enhancing energy efficiency; indeed, accurate forecasting enables utility companies and policymakers, who advocate sustainable energy practices, to optimize resource utilization. Moreover, smart meters provide valuable information by allowing for granular insights into consumption patterns. Building upon available smart meter data, our study aims to cluster consumers into distinct groups according to their energy usage behaviours, effectively capturing a diverse spectrum of consumption patterns. Next, we design JITtrans (Just In Time transformer), a novel transformer deep learning model that significantly improves energy consumption forecasting accuracy, with respect to traditional forecasting methods. Extensive experimental results validate our claims using proprietary smart meter data. Our findings highlight the potential of advanced predictive technologies to revolutionize energy management and advance sustainable power systems: the development of efficient and eco-friendly energy solutions critically depends on such technologies.

Related papers

TRIZ Method for Urban Building Energy Optimization: GWO-SARIMA-LSTM Forecasting model [0.34028430825850625]
This study proposes a hybrid deep learning model that combines TRIZ innovation theory with GWO, SARIMA and LSTM to improve the accuracy of building energy consumption prediction. Our experiments demonstrate a significant 15% reduction in prediction error compared to existing models.
arXiv Detail & Related papers (2024-10-20T04:46:42Z)
Empowering Distributed Solutions in Renewable Energy Systems and Grid Optimization [3.8979646385036175]
Machine learning (ML) advancements play a crucial role in empowering renewable energy sources and improving grid management. The incorporation of big data and ML into smart grids offers several advantages, including heightened energy efficiency. However, challenges like handling large data volumes, ensuring cybersecurity, and obtaining specialized expertise must be addressed.
arXiv Detail & Related papers (2023-10-24T02:45:16Z)
Non-Intrusive Electric Load Monitoring Approach Based on Current Feature Visualization for Smart Energy Management [51.89904044860731]
We employ computer vision techniques of AI to design a non-invasive load monitoring method for smart electric energy management. We propose to recognize all electric loads from color feature images using a U-shape deep neural network with multi-scale feature extraction and attention mechanism.
arXiv Detail & Related papers (2023-08-08T04:52:19Z)
Benchmarks and Custom Package for Energy Forecasting [55.460452605056894]
Energy forecasting aims to minimize the cost of subsequent tasks such as power grid dispatch. In this paper, we collected large-scale load datasets and released a new renewable energy dataset. We conducted extensive experiments with 21 forecasting methods in these energy datasets at different levels under 11 evaluation metrics.
arXiv Detail & Related papers (2023-07-14T06:50:02Z)
Building Energy Efficiency through Advanced Regression Models and Metaheuristic Techniques for Sustainable Management [3.6811136816751513]
This research leverages extensive raw data from building infrastructures to uncover energy consumption patterns. We investigate the factors influencing energy efficiency and cost reduction in buildings, utilizing Lasso Regression, Decision Tree, and Random Forest models. We apply metaheuristic techniques to enhance the Decision Tree algorithm, resulting in improved predictive precision.
arXiv Detail & Related papers (2023-05-15T01:21:42Z)
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)
Privacy Preserving Demand Forecasting to Encourage Consumer Acceptance of Smart Energy Meters [4.769747792846004]
We highlight the need for privacy preserving energy demand forecasting to allay a major concern consumers have about smart meter installations. High resolution smart meter data can expose many private aspects of a consumer's household such as occupancy, habits and individual appliance usage. We propose the application of a distributed machine learning setting known as federated learning for energy demand forecasting at various scales to make load prediction possible.
arXiv Detail & Related papers (2020-12-14T12:04:34Z)
Energy Disaggregation with Semi-supervised Sparse Coding [0.0]
Energy disaggregation research aims to decompose the aggregated energy consumption data into its component appliances. In this paper, a discriminative disaggregation model based on sparse coding has been evaluated on large-scale household power usage dataset for energy conservation.
arXiv Detail & Related papers (2020-04-20T21:05:25Z)
Risk-Aware Energy Scheduling for Edge Computing with Microgrid: A Multi-Agent Deep Reinforcement Learning Approach [82.6692222294594]
We study a risk-aware energy scheduling problem for a microgrid-powered MEC network. We derive the solution by applying a multi-agent deep reinforcement learning (MADRL)-based advantage actor-critic (A3C) algorithm with shared neural networks.
arXiv Detail & Related papers (2020-02-21T02:14:38Z)
Multi-Agent Meta-Reinforcement Learning for Self-Powered and Sustainable Edge Computing Systems [87.4519172058185]
An effective energy dispatch mechanism for self-powered wireless networks with edge computing capabilities is studied. A novel multi-agent meta-reinforcement learning (MAMRL) framework is proposed to solve the formulated problem. Experimental results show that the proposed MAMRL model can reduce up to 11% non-renewable energy usage and by 22.4% the energy cost.
arXiv Detail & Related papers (2020-02-20T04:58:07Z)
Towards the Systematic Reporting of the Energy and Carbon Footprints of Machine Learning [68.37641996188133]
We introduce a framework for tracking realtime energy consumption and carbon emissions. We create a leaderboard for energy efficient reinforcement learning algorithms. We propose strategies for mitigation of carbon emissions and reduction of energy consumption.
arXiv Detail & Related papers (2020-01-31T05:12:59Z)

This list is automatically generated from the titles and abstracts of the papers in this site.