APA
Click to copy
Guglani, S., Jakhar, A. K., Dimple, K., Sukhija, A., Dasgupta, A., Sharma, R., … Roy, S. (2024). Artificial Neural Networks With Fast Transfer Learning for Statistical Signal Integrity Analysis of MWCNT and MLGNR Interconnect Networks. IEEE Transactions on Electromagnetic Compatibility (Print).
Chicago/Turabian
Click to copy
Guglani, Surila, Asha Kumari Jakhar, K. Dimple, Ankit Sukhija, A. Dasgupta, Rohit Sharma, Brajesh Kumar Kaushik, and Sourajeet Roy. “Artificial Neural Networks With Fast Transfer Learning for Statistical Signal Integrity Analysis of MWCNT and MLGNR Interconnect Networks.” IEEE transactions on electromagnetic compatibility (Print) (2024).
MLA
Click to copy
Guglani, Surila, et al. “Artificial Neural Networks With Fast Transfer Learning for Statistical Signal Integrity Analysis of MWCNT and MLGNR Interconnect Networks.” IEEE Transactions on Electromagnetic Compatibility (Print), 2024.
BibTeX Click to copy
@article{surila2024a,
title = {Artificial Neural Networks With Fast Transfer Learning for Statistical Signal Integrity Analysis of MWCNT and MLGNR Interconnect Networks},
year = {2024},
journal = {IEEE transactions on electromagnetic compatibility (Print)},
author = {Guglani, Surila and Jakhar, Asha Kumari and Dimple, K. and Sukhija, Ankit and Dasgupta, A. and Sharma, Rohit and Kaushik, Brajesh Kumar and Roy, Sourajeet}
}
In this article, artificial neural network (ANN) metamodels have been developed for the fast statistical signal integrity analysis of multiwalled carbon nanotube and multilayer graphene nanoribbon interconnect networks. These ANN metamodels, referred to as primary ANNs, are trained using transfer learning strategies where the initial guess of the weights and bias terms are learned from a pretrained secondary ANN. The secondary ANN is trained using data extracted from a cheap and approximate equivalent single conductor model of the interconnects. Starting with this informed initial guess, the weights and bias terms of the primary ANN can be optimized using a very small dataset generated from the rigorous but massive multiconductor circuit model of the interconnects. This makes the primary ANN significantly more efficient to train than existing metamodels. Two distinct transfer learning strategies based on the full and partial transfer of knowledge between the primary and secondary ANNs have been developed in this work.