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
- Arvind K Shukla, Balaji V, Dharani R, M Ananthi, R Padmavathy, Romala V. Srinivas, Precision agriculture predictive modeling and sensor analysis for enhanced crop monitoring , The Scientific Temper: Vol. 14 No. 04 (2023): The Scientific Temper
- Sathya R., Balamurugan P, Classification of glaucoma in retinal fundus images using integrated YOLO-V8 and deep CNN , The Scientific Temper: Vol. 15 No. 03 (2024): The Scientific Temper
- U. Perachiselvi, R. Balasubramani, Funding agencies in Tamil Nadu State Universities: A scientometric perspective , The Scientific Temper: Vol. 15 No. spl-1 (2024): The Scientific Temper
- R. Sakthiraman, L. Arockiam, RFSVMDD: Ensemble of multi-dimension random forest and custom-made support vector machine for detecting RPL DDoS attacks in an IoT-based WSN environment , The Scientific Temper: Vol. 16 No. 03 (2025): The Scientific Temper
- S. Prabagar, Vinay K. Nassa, Senthil V. M, Shilpa Abhang, Pravin P. Adivarekar, Sridevi R, Python-based social science applications’ profiling and optimization on HPC systems using task and data parallelism , The Scientific Temper: Vol. 14 No. 03 (2023): The Scientific Temper
- Shalini Tiwari, To Explore the Salt Stress Responsive Long Non-coding RNA(s) Mechanism in Contrasting Rice (Oryza stiva L.) Genotypes , The Scientific Temper: Vol. 13 No. 02 (2022): The Scientific Temper
- Gomathi P, Deena Rose D, Sampath Kumar R, Sathya Priya M, Dinesh S, Ramarao M, Computer vision for unmanned aerial vehicles in agriculture: applications, challenges, and opportunities , The Scientific Temper: Vol. 14 No. 03 (2023): The Scientific Temper
- Rianka Sarkar, P. Sreeramulu, Oceanic Epistemologies and Trans-corporeality: Reimagining Amitav Ghosh through Anthropocene Narratives , The Scientific Temper: Vol. 16 No. 12 (2025): The Scientific Temper
- Nabab Ali, Equabal Jawaid, Spatial Insect Biodiversity and Community Analysis in Selected Rice Fields of North Bihar , The Scientific Temper: Vol. 13 No. 01 (2022): The Scientific Temper
- Dhulasi Priya S, Saranya K G, Significance of artificial intelligence in the development of sustainable transportation , The Scientific Temper: Vol. 14 No. 02 (2023): The Scientific Temper
<< < 19 20 21 22 23 24 25 26 27 28 > >>
You may also start an advanced similarity search for this article.
