Abstract
A global I-V and C-V BSIM-CMG parameter extraction methodology based on deep learning is proposed. 100 k training datasets were generated through Monte Carlo simulation varying 28 IV and CV model parameters in the industry-standard BSIM-CMG FinFET model. For each of the 100 k Monte Carlo-selected BSIM-CMG parameter dataset, the ID-VG and CGG-VG characteristics of seven Monte Carlo-selected gate lengths ranging from 14 nm to 110 nm were generated as the input to train the parameter extraction neural network. The neural network outputs for training are the 28 model parameters’ values. The neural network's capability to extract BSIM-CMG model parameters that accurately fit TCAD-generated ID-VG and CGG-VG data over a range of gate lengths was demonstrated. This marks the first time a deep learning compact model parameter extraction flow, employing a single neural network for both I-V and C-V parameters and for a range of gate length, is presented.
Original language | English |
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Article number | 108898 |
Journal | Solid-State Electronics |
Volume | 216 |
DOIs | |
State | Published - Jun 2024 |
Keywords
- Berkeley Short-channel IGFET Model – Common Multi-Gate (BSIM-CMG)
- Compact model
- Deep learning
- Fin field effect transistor (FinFET)
- Parameter extraction