Deep learning-based partial inductance extraction of 3-D interconnects
A physics-informed deep learning-based scheme is introduced for computing partial inductances of interconnects. This scheme takes a physics-based skin depth map and a geometry identifier of the interconnects as inputs and provides the current density distribution on the interconnects as the output....
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sg-ntu-dr.10356-1821402025-01-17T15:42:55Z Deep learning-based partial inductance extraction of 3-D interconnects Jia, Xiaofan Wang, Mingyu Dai, Qiqi Wang, Chao-Fu Yucel, Abdulkadir C. School of Electrical and Electronic Engineering Engineering Physics Convolutional neural network Deep learning Inductance extraction Machine learning Magneto-quasi-static analysis Parameter extraction U-net A physics-informed deep learning-based scheme is introduced for computing partial inductances of interconnects. This scheme takes a physics-based skin depth map and a geometry identifier of the interconnects as inputs and provides the current density distribution on the interconnects as the output. The predicted currents are then used to compute the partial self-resistances, self-inductances, and mutual-inductances of the interconnects. The proposed method leverages an Attention U-net, a U-shaped convolutional neural network with attention modules. During the training of Attention U-net, a specifically designed loss function is used to ensure the accurate modeling of the currents on the structure as well as ports. The accuracy, efficiency, and generalization ability of this physics-informed deep learning method are demonstrated via inductance extraction of the interconnects with and without a ground plane, including straight single interconnects, interconnects with sharp bends, parallel interconnects, and multiple conductor crossover buses. Numerical results show that the proposed scheme can predict the current density distribution of one interconnect scenario in 15.63 ms on GPU, 1157x faster than the physics-based solver, while providing self-inductances, mutual-inductances, and self-resistances of interconnects with around 1%, 3%, and 4% -norm error, respectively. Nanyang Technological University Submitted/Accepted version This work was supported by Nanyang Technological University under a Start-Up Grant. 2025-01-16T01:46:59Z 2025-01-16T01:46:59Z 2025 Journal Article Jia, X., Wang, M., Dai, Q., Wang, C. & Yucel, A. C. (2025). Deep learning-based partial inductance extraction of 3-D interconnects. IEEE Journal On Multiscale and Multiphysics Computational Techniques. https://dx.doi.org/10.1109/JMMCT.2025.3528484 2379-8793 https://hdl.handle.net/10356/182140 10.1109/JMMCT.2025.3528484 en NTU-SUG IEEE Journal on Multiscale and Multiphysics Computational Techniques © 2025 IEEE. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1109/JMMCT.2025.3528484. application/pdf |
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Engineering Physics Convolutional neural network Deep learning Inductance extraction Machine learning Magneto-quasi-static analysis Parameter extraction U-net |
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Engineering Physics Convolutional neural network Deep learning Inductance extraction Machine learning Magneto-quasi-static analysis Parameter extraction U-net Jia, Xiaofan Wang, Mingyu Dai, Qiqi Wang, Chao-Fu Yucel, Abdulkadir C. Deep learning-based partial inductance extraction of 3-D interconnects |
| description |
A physics-informed deep learning-based scheme is introduced for computing partial inductances of interconnects. This scheme takes a physics-based skin depth map and a geometry identifier of the interconnects as inputs and provides the current density distribution on the interconnects as the output. The predicted currents are then used to compute the partial self-resistances, self-inductances, and mutual-inductances of the interconnects. The proposed method leverages an Attention U-net, a U-shaped convolutional neural network with attention modules. During the training of Attention U-net, a specifically designed loss function is used to ensure the accurate modeling of the currents on the structure as well as ports. The accuracy, efficiency, and generalization ability of this physics-informed deep learning method are demonstrated via inductance extraction of the interconnects with and without a ground plane, including straight single interconnects, interconnects with sharp bends, parallel interconnects, and multiple conductor crossover buses. Numerical results show that the proposed scheme can predict the current density distribution of one interconnect scenario in 15.63 ms on GPU, 1157x faster than the physics-based solver, while providing self-inductances, mutual-inductances, and self-resistances of interconnects with around 1%, 3%, and 4% -norm error, respectively. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Jia, Xiaofan Wang, Mingyu Dai, Qiqi Wang, Chao-Fu Yucel, Abdulkadir C. |
| format |
Article |
| author |
Jia, Xiaofan Wang, Mingyu Dai, Qiqi Wang, Chao-Fu Yucel, Abdulkadir C. |
| author_sort |
Jia, Xiaofan |
| title |
Deep learning-based partial inductance extraction of 3-D interconnects |
| title_short |
Deep learning-based partial inductance extraction of 3-D interconnects |
| title_full |
Deep learning-based partial inductance extraction of 3-D interconnects |
| title_fullStr |
Deep learning-based partial inductance extraction of 3-D interconnects |
| title_full_unstemmed |
Deep learning-based partial inductance extraction of 3-D interconnects |
| title_sort |
deep learning-based partial inductance extraction of 3-d interconnects |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/182140 |
| _version_ |
1821833175952785408 |