Accelerating OTA Circuit Design: Transistor Sizing Based on a Transformer Model and Precomputed Lookup Tables

Device sizing is crucial for meeting performance specifications in operational transconductance amplifiers (OTAs), and this work proposes an automated sizing framework based on a transformer model. The approach first leverages the driving-point signal flow graph (DP-SFG) to map an OTA circuit and it...

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Bibliographic Details
Published inProceedings - Design, Automation, and Test in Europe Conference and Exhibition pp. 1 - 7
Main Authors Ghosh, Subhadip, Gebru, Endalk Y., Kashyap, Chandramouli V., Harjani, Ramesh, Sapatnekar, Sachin S.
Format Conference Proceeding
LanguageEnglish
Published EDAA 31.03.2025
Subjects
Computational efficiency
Computational modeling
Integrated circuit modeling
SPICE
Tokenization
Topology
Training
Transconductance
Transformers
Transistors
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ISSN1558-1101
DOI10.23919/DATE64628.2025.10993030

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Summary:Device sizing is crucial for meeting performance specifications in operational transconductance amplifiers (OTAs), and this work proposes an automated sizing framework based on a transformer model. The approach first leverages the driving-point signal flow graph (DP-SFG) to map an OTA circuit and its specifications into transformer-friendly sequential data. A specialized tokenization approach is applied to the sequential data to expedite the training of the transformer on a diverse range of OTA topologies, under multiple specifications. Under specific performance constraints, the trained transformer model is used to accurately predict DP-SFG parameters in the inference phase. The predicted DP-SFG parameters are then translated to transistor sizes using a precomputed look-up table-based approach inspired by the 9m / I d methodology. In contrast to previous conventional or machine-learning-based methods, the proposed framework achieves significant improvements in both speed and computational efficiency by reducing the need for expensive SPICE simulations within the optimization loop; instead, almost all SPICE simulations are confined to the one-time training phase. The method is validated on a variety of unseen specifications, and the sizing solution demonstrates over 90% success in meeting specifications with just one SPICE simulation for validation, and 100% success with 3-5 additional SPICE simulations.
ISSN:1558-1101
DOI:10.23919/DATE64628.2025.10993030