Reconfiguration of Automated Manufacturing Systems Using Gated Graph Neural Networks
Downloads
Published
DOI:
https://doi.org/10.58414/SCIENTIFICTEMPER.2022.13.246Keywords:
Machine Learning, Reconfiguration, Computer numerical control (CNC), Gated Graph Neural Network (GGNN), Automat Manufacturing Systems, Dedicated Manufacturing lines.Dimensions Badge
Issue
Section
License
Copyright (c) 2022 The Scientific Temper
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
To deal with the unpredictability of dynamic markets, automated manufacturing systems rely on their capacity to adapt and change. With the need for more personalized and high-quality goods, the complexity of these systems evolves, prompting more agile and adaptable techniques. To enable dynamic as well as on systems reconfiguration aimed at responding swiftly to product changes by providing more efficient services. To increase production in response to market demand and meet the referred requirements, this proposed study employs Machine Learning Techniques for the Reconfiguration of Automated Manufacturing Systems. Gated Graph Neural Network (GGNN) based prediction model is generated using graph instances as input, and the prediction model provides a result for each graph instance, as well as activity level relevance and ratings for the relevant needs such as model accuracy and validation. For better use of the model effectiveness by the proposed methodology for the final model is validated for cost, time, and productivity.Abstract
How to Cite
Downloads
Similar Articles
- Pritee Rajaram Ray, Bijal Zaveri, The role of technology in implementing effective education for children with learning difficulties , The Scientific Temper: Vol. 15 No. 04 (2024): The Scientific Temper
- Jayalakshmi K., M. Prabakaran, The role of big data in transforming human resource analytics: A literature review , The Scientific Temper: Vol. 15 No. spl-1 (2024): The Scientific Temper
- S. TAMIL FATHIMA, K. FATHIMA BIBI, Early diagnosis of cardiac disease using Xgboost ensemble voting-based feature selection, based lightweight recurrent neural network approach , The Scientific Temper: Vol. 16 No. 06 (2025): The Scientific Temper
- V Anitha, Seema Sharma, R. Jayavadivel, Akundi Sai Hanuman, B Gayathri, R. Rajagopal, A network for collaborative detection of intrusions in smart cities using blockchain technology , The Scientific Temper: Vol. 14 No. 03 (2023): The Scientific Temper
- S. Dhivya, S. Prakash, Power quality assessment in solar-connected smart grids via hybrid attention-residual network for power quality (HARN-PQ) , The Scientific Temper: Vol. 15 No. 04 (2024): The Scientific Temper
- Deepa S, Sripriya T, Radhika M, Jeneetha J. J, Experimental evaluation of artificial intelligence assisted heart disease prediction using deep learning principle , The Scientific Temper: Vol. 14 No. 04 (2023): The Scientific Temper
- D. Padma Prabha, C. Victoria Priscilla, A combined framework based on LSTM autoencoder and XGBoost with adaptive threshold classification for credit card fraud detection , The Scientific Temper: Vol. 15 No. 02 (2024): The Scientific Temper
- C. Agilan, Lakshna Arun, Optimization-based clustering feature extraction approach for human emotion recognition , The Scientific Temper: Vol. 15 No. spl-1 (2024): The Scientific Temper
- Engida Admassu, Classifying enset based on their disease tolerance using deep learning , The Scientific Temper: Vol. 14 No. 03 (2023): The Scientific Temper
- Ritu Nagila, Abhishek Kumar Mishra, Ashish Nagila, Role of big data in enhancing lung cancer prediction and treatment , The Scientific Temper: Vol. 16 No. 04 (2025): The Scientific Temper
<< < 4 5 6 7 8 9 10 11 12 13 > >>
You may also start an advanced similarity search for this article.
Most read articles by the same author(s)
- Abhishek Dwivedi, Shekhar Verma, SCNN Based Classification Technique for the Face Spoof Detection Using Deep Learning Concept , The Scientific Temper: Vol. 13 No. 02 (2022): The Scientific Temper
