Authors

  • Phuoc Pham
  • Arun Venkitaraman
  • Chia-Yu Hsieh
  • Andrea Bonetti
  • Stefan Uhlich*
  • Markus Leibl
  • Simon Hofmann
  • Eisaku Ohbuchi
  • Lorenzo Servadei
  • Ulf Schlichtmann
  • Robert Wille

* External authors

Venue

  • MLCAD-25

Date

  • 2025

Share

GENIE-ASI: Generative Instruction and Executable Code for Analog Subcircuit Identification

VIEW PUBLICATION

Phuoc Pham

Arun Venkitaraman

Chia-Yu Hsieh

Andrea Bonetti

Stefan Uhlich*

Markus Leibl

Simon Hofmann

Eisaku Ohbuchi

Lorenzo Servadei

Ulf Schlichtmann

Robert Wille

* External authors

MLCAD-25

2025

Abstract

Analog subcircuit identification is a core task in analog design, essential for simulation, sizing, and layout. Traditional methods often require extensive human expertise, rule-based encoding, or large labeled datasets. To address these challenges, we propose GENIE-ASI, the first training-free, large language model (LLM)-based methodology for analog subcircuit identification. GENIE-ASI operates in two phases: it first uses in-context learning to derive natural language instructions from a few demonstration examples, then translates these into executable Python code to identify subcircuits in unseen SPICE netlists. In addition, to evaluate LLM-based approaches systematically, we introduce a new benchmark composed of operational amplifier netlists (op-amps) that cover a wide range of subcircuit variants. Experimental results on the proposed benchmark show that GENIE-ASI matches rule-based performance on simple structures (F1-score = 1.0), remains competitive on moderate abstractions (F1-score = 0.81), and shows potential even on complex subcircuits (F1-score = 0.31). These findings demonstrate that LLMs can serve as adaptable, general-purpose tools in analog design automation, opening new research directions for foundation model applications in analog design automation.

Related Publications

Reverse Engineering of Music Mixing Graphs With Differentiable Processors and Iterative Pruning

JAES, 2025
Sungho Lee*, Marco A. Martínez-Ramírez, Wei-Hsiang Liao, Stefan Uhlich*, Giorgio Fabbro*, Kyogu Lee*, Yuki Mitsufuji

Reverse engineering of music mixes aims to uncover how dry source signals are processed and combined to produce a final mix. In this paper, prior works are extended to reflect the compositional nature of mixing and search for a graph of audio processors. First, a mixing cons…

Schemato -- An LLM for Netlist-to-Schematic Conversion

MLCAD, 2025
Ryoga Matsuo, Stefan Uhlich*, Arun Venkitaraman, Andrea Bonetti, Chia-Yu Hsieh, Ali Momeni, Lukas Mauch*, Augusto Capone, Eisaku Ohbuchi, Lorenzo Servadei

Machine learning models are advancing circuit design, particularly in analog circuits. They typically generate netlists that lack human interpretability. This is a problem as human designers heavily rely on the interpretability of circuit diagrams or schematics to intuitivel…

Music Foundation Model as Generic Booster for Music Downstream Tasks

TMLR, 2025
WeiHsiang Liao, Yuhta Takida, Yukara Ikemiya, Zhi Zhong*, Chieh-Hsin Lai, Giorgio Fabbro*, Kazuki Shimada, Keisuke Toyama*, Kinwai Cheuk, Marco A. Martínez-Ramírez, Shusuke Takahashi*, Stefan Uhlich*, Taketo Akama*, Woosung Choi, Yuichiro Koyama*, Yuki Mitsufuji

We demonstrate the efficacy of using intermediate representations from a single foundation model to enhance various music downstream tasks. We introduce SoniDo, a music foundation model (MFM) designed to extract hierarchical features from target music samples. By leveraging …
SEE ALL
  • HOME
  • Publications
  • GENIE-ASI: Generative Instruction and Executable Code for Analog Subcircuit Identification

JOIN US

Shape the Future of AI with Sony AI

We want to hear from those of you who have a strong desire
to shape the future of AI.

LEARN MORE
TO TOP TO TOP
CONTACT US