English

DiffCkt: A Diffusion Model-Based Hybrid Neural Network Framework for Automatic Transistor-Level Generation of Analog Circuits

Emerging Technologies 2025-07-22 v2

Abstract

Analog circuit design consists of the pre-layout and layout phases. Among them, the pre-layout phase directly decides the final circuit performance, but heavily depends on experienced engineers to do manual design according to specific application scenarios. To overcome these challenges and automate the analog circuit pre-layout design phase, we introduce DiffCkt: a diffusion model-based hybrid neural network framework for the automatic transistor-level generation of analog circuits, which can directly generate corresponding circuit structures and device parameters tailored to specific performance requirements. To more accurately quantify the efficiency of circuits generated by DiffCkt, we introduce the Circuit Generation Efficiency Index (CGEI), which is determined by both the figure of merit (FOM) of a single generated circuit and the time consumed. Compared with relative research, DiffCkt has improved CGEI by a factor of 2.218365×2.21 \sim 8365\times, reaching a state-of-the-art (SOTA) level. In conclusion, this work shows that the diffusion model has the remarkable ability to learn and generate analog circuit structures and device parameters, providing a revolutionary method for automating the pre-layout design of analog circuits. The circuit dataset will be open source, its preview version is available at https://github.com/CjLiu-NJU/DiffCkt.

Keywords

Cite

@article{arxiv.2507.00444,
  title  = {DiffCkt: A Diffusion Model-Based Hybrid Neural Network Framework for Automatic Transistor-Level Generation of Analog Circuits},
  author = {Chengjie Liu and Jiajia Li and Yabing Feng and Wenhao Huang and Weiyu Chen and Yuan Du and Jun Yang and Li Du},
  journal= {arXiv preprint arXiv:2507.00444},
  year   = {2025}
}

Comments

V1: Accepted by ICCAD2025; V2: 2025.7.19 **** Corrected the formula errors in Algorithm 5 and supplemented the relevant materials. Added references related to diffusion for analog circuits. Fixed the citation error of Table III. Corrected the error regarding the authors' affiliations. Optimized the layout. ****

R2 v1 2026-07-01T03:40:55.277Z