Smart grid precision: Evaluating machine learning models for forecasting of energy consumption from a smart grid
Downloads
Published
DOI:
https://doi.org/10.58414/SCIENTIFICTEMPER.2024.15.spl.27Keywords:
Smart grid, Recurrent neural network, Long short-term memory, Temporal fusion transformer, Prophet.Dimensions Badge
Issue
Section
License
Copyright (c) 2024 The Scientific Temper
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
The widespread adoption of smart home technologies has led to a significant increase in the generation of high-frequency energy consumption data from smart grids. Accurate forecasting of energy consumption in smart homes is crucial for optimizing resource utilization and promoting energy efficiency. This research work investigates the precision of energy consumption forecasting within a smart grid environment, employing machine learning algorithms such as convolutional neural network (CNN), recurrent neural network (RNN), long short-term memory (LSTM), temporal fusion transformer (TFT) and Prophet. The CNN model extracts spatial features, while RNN and LSTM capture temporal dependencies in time series data. Prophet, recognized for handling seasonality and holidays, is included for comparative analysis. Utilizing a dataset from Pecan Street, Texas, performance metrics like mean absolute error (MAE), root mean squared error (RMSE), and mean absolute percentage error (MAPE) assess each model’s accuracy. This work aids in improving energy management systems, contributing to sustainable and efficient energy use in residential environments.Abstract
How to Cite
Downloads
Similar Articles
- Rajarajeswari M, Reena Ravi, Effectiveness of multicomponent intervention on smartphone addiction and leisure wellbeing among adolescents of selected PU college in Bangalore , The Scientific Temper: Vol. 16 No. 06 (2025): The Scientific Temper
- Seema Bhakuni, Application of artificial intelligence on human resource management in information technolgy industry in India , The Scientific Temper: Vol. 14 No. 04 (2023): The Scientific Temper
- Manan Pathak, Dishang Trivedi Trivedi, Field-effect limits and design parameters for hybrid HVDC – HVAC transmission line corridors , The Scientific Temper: Vol. 16 No. Spl-1 (2025): The Scientific Temper
- S. C. Prabha, P. Sivaraaj, S. Kantha Lakshmi, Data analysis and machine learning-based modeling for real-time production , The Scientific Temper: Vol. 14 No. 03 (2023): The Scientific Temper
- Bhavikgiri Vishnugiri Goswami, Vaseemahmed G. Qureshi, Reclaiming identity: transgender perspectives on inclusion in contemporary India , The Scientific Temper: Vol. 16 No. 06 (2025): The Scientific Temper
- NITHYA R, shruthi D, Sindhuja S, Sneha S, Challenges encountered by health care professionals in monitoring adverse events due to medical devices: A review , The Scientific Temper: Vol. 14 No. 02 (2023): The Scientific Temper
- Ashwani Pandey, Sanjay Madan, Kumari Sandhiya, Ruchi Sharma, Akansha Raturi, Ashmita Bhatt, Naveen Gaurav, Comparison of Antioxidant, Phytochemical Profiling of Bacopa monnieri (Brahmi) , The Scientific Temper: Vol. 13 No. 02 (2022): The Scientific Temper
- P. Rathinabhagya, J. Merline Vinotha, Fuzzy vehicle routing problem for a municipal solid waste management system with greenhouse gas emission at various disposal stages , The Scientific Temper: Vol. 16 No. 04 (2025): The Scientific Temper
- Suprabha Amit Kshatriya, Jaymin K Bhalani, Fire and smoke detection with high accuracy using YOLOv5 , The Scientific Temper: Vol. 16 No. 06 (2025): The Scientific Temper
- Swati Sing, Rimjhim Sharma, Supriya Joshi, Ganji Purnachandra Nagaraju, Sharad Vats, Afroz Alam, Phytochemical Profiling of a Common Moss Hyophila involuta Jaeger. for its Bioactive and Antioxidant Potential Against Viral Infections , The Scientific Temper: Vol. 13 No. 01 (2022): The Scientific Temper
<< < 12 13 14 15 16 17 18 19 20 21 > >>
You may also start an advanced similarity search for this article.
