Large circuit models: opportunities and challenges

Lei Chen; Yiqi Chen; Zhufei Chu; Wenji Fang; Tsung Yi Ho; Ru Huang; Yu Huang; Sadaf Khan; Min Li; Xingquan Li; Yu Li; Yun Liang; Jinwei Liu; Yi Liu; Yibo Lin; Guojie Luo; Hongyang Pan; Zhengyuan Shi; Guangyu Sun; Dimitrios Tsaras; Runsheng Wang; Ziyi Wang; Xinming Wei; Zhiyao Xie; Qiang Xu; Chenhao Xue; Junchi Yan; Jun Yang; Bei Yu; Mingxuan Yuan; Evangeline F.Y. Young; Xuan Zeng; Haoyi Zhang; Zuodong Zhang; Yuxiang Zhao; Hui Ling Zhen; Ziyang Zheng; Binwu Zhu; Keren Zhu; Sunan Zou

doi:10.1007/s11432-024-4155-7

Large circuit models: opportunities and challenges

Lei Chen, Yiqi Chen, Zhufei Chu, Wenji Fang, Tsung Yi Ho, Ru Huang, Yu Huang, Sadaf Khan, Min Li, Xingquan Li, Yu Li, Yun Liang, Jinwei Liu, Yi Liu, Yibo Lin, Guojie Luo^*, Hongyang Pan, Zhengyuan Shi, Guangyu Sun, Dimitrios TsarasRunsheng Wang, Ziyi Wang, Xinming Wei, Zhiyao Xie, Qiang Xu^*, Chenhao Xue, Junchi Yan, Jun Yang, Bei Yu, Mingxuan Yuan^*, Evangeline F.Y. Young, Xuan Zeng, Haoyi Zhang, Zuodong Zhang, Yuxiang Zhao, Hui Ling Zhen, Ziyang Zheng, Binwu Zhu, Keren Zhu, Sunan Zou

^*Corresponding author for this work

Department of Computer Science

Research output: Contribution to journal › Journal article › peer-review

13 Citations (Scopus)

Abstract

Within the electronic design automation (EDA) domain, artificial intelligence (AI)-driven solutions have emerged as formidable tools, yet they typically augment rather than redefine existing methodologies. These solutions often repurpose deep learning models from other domains, such as vision, text, and graph analytics, applying them to circuit design without tailoring to the unique complexities of electronic circuits. Such an “AI4EDA” approach falls short of achieving a holistic design synthesis and understanding, overlooking the intricate interplay of electrical, logical, and physical facets of circuit data. This study argues for a paradigm shift from AI4EDA towards AI-rooted EDA from the ground up, integrating AI at the core of the design process. Pivotal to this vision is the development of a multimodal circuit representation learning technique, poised to provide a comprehensive understanding by harmonizing and extracting insights from varied data sources, such as functional specifications, register-transfer level (RTL) designs, circuit netlists, and physical layouts. We champion the creation of large circuit models (LCMs) that are inherently multimodal, crafted to decode and express the rich semantics and structures of circuit data, thus fostering more resilient, efficient, and inventive design methodologies. Embracing this AI-rooted philosophy, we foresee a trajectory that transcends the current innovation plateau in EDA, igniting a profound “shift-left” in electronic design methodology. The envisioned advancements herald not just an evolution of existing EDA tools but a revolution, giving rise to novel instruments of design-tools that promise to radically enhance design productivity and inaugurate a new epoch where the optimization of circuit performance, power, and area (PPA) is achieved not incrementally, but through leaps that redefine the benchmarks of electronic systems’ capabilities.

Original language	English
Article number	200402
Number of pages	42
Journal	Science China Information Sciences
Volume	67
Issue number	10
Early online date	25 Sept 2024
DOIs	https://doi.org/10.1007/s11432-024-4155-7
Publication status	Published - Oct 2024

User-Defined Keywords

AI-rooted EDA
circuit optimization
large circuit models (LCMs)
multimodal circuit representation learning

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1007/s11432-024-4155-7

Cite this

@article{cec84eac93904e88865ca0d9e515eb64,

title = "Large circuit models: opportunities and challenges",

abstract = "Within the electronic design automation (EDA) domain, artificial intelligence (AI)-driven solutions have emerged as formidable tools, yet they typically augment rather than redefine existing methodologies. These solutions often repurpose deep learning models from other domains, such as vision, text, and graph analytics, applying them to circuit design without tailoring to the unique complexities of electronic circuits. Such an “AI4EDA” approach falls short of achieving a holistic design synthesis and understanding, overlooking the intricate interplay of electrical, logical, and physical facets of circuit data. This study argues for a paradigm shift from AI4EDA towards AI-rooted EDA from the ground up, integrating AI at the core of the design process. Pivotal to this vision is the development of a multimodal circuit representation learning technique, poised to provide a comprehensive understanding by harmonizing and extracting insights from varied data sources, such as functional specifications, register-transfer level (RTL) designs, circuit netlists, and physical layouts. We champion the creation of large circuit models (LCMs) that are inherently multimodal, crafted to decode and express the rich semantics and structures of circuit data, thus fostering more resilient, efficient, and inventive design methodologies. Embracing this AI-rooted philosophy, we foresee a trajectory that transcends the current innovation plateau in EDA, igniting a profound “shift-left” in electronic design methodology. The envisioned advancements herald not just an evolution of existing EDA tools but a revolution, giving rise to novel instruments of design-tools that promise to radically enhance design productivity and inaugurate a new epoch where the optimization of circuit performance, power, and area (PPA) is achieved not incrementally, but through leaps that redefine the benchmarks of electronic systems{\textquoteright} capabilities.",

keywords = "AI-rooted EDA, circuit optimization, large circuit models (LCMs), multimodal circuit representation learning",

author = "Lei Chen and Yiqi Chen and Zhufei Chu and Wenji Fang and Ho, {Tsung Yi} and Ru Huang and Yu Huang and Sadaf Khan and Min Li and Xingquan Li and Yu Li and Yun Liang and Jinwei Liu and Yi Liu and Yibo Lin and Guojie Luo and Hongyang Pan and Zhengyuan Shi and Guangyu Sun and Dimitrios Tsaras and Runsheng Wang and Ziyi Wang and Xinming Wei and Zhiyao Xie and Qiang Xu and Chenhao Xue and Junchi Yan and Jun Yang and Bei Yu and Mingxuan Yuan and Young, {Evangeline F.Y.} and Xuan Zeng and Haoyi Zhang and Zuodong Zhang and Yuxiang Zhao and Zhen, {Hui Ling} and Ziyang Zheng and Binwu Zhu and Keren Zhu and Sunan Zou",

note = "This work was supported in part by Hong Kong S.A.R. General Research Fund (Grant No. 14212422) and Research Matching (Grant No. CSE-7-2022). Publisher Copyright: {\textcopyright} The Author(s) 2024, ",

year = "2024",

month = oct,

doi = "10.1007/s11432-024-4155-7",

language = "English",

volume = "67",

journal = "Science China Information Sciences",

issn = "1674-733X",

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Chen, L, Chen, Y, Chu, Z, Fang, W, Ho, TY, Huang, R, Huang, Y, Khan, S, Li, M, Li, X, Li, Y, Liang, Y, Liu, J, Liu, Y, Lin, Y, Luo, G, Pan, H, Shi, Z, Sun, G, Tsaras, D, Wang, R, Wang, Z, Wei, X, Xie, Z, Xu, Q, Xue, C, Yan, J, Yang, J, Yu, B, Yuan, M, Young, EFY, Zeng, X, Zhang, H, Zhang, Z, Zhao, Y, Zhen, HL, Zheng, Z, Zhu, B, Zhu, K & Zou, S 2024, 'Large circuit models: opportunities and challenges', Science China Information Sciences, vol. 67, no. 10, 200402. https://doi.org/10.1007/s11432-024-4155-7

TY - JOUR

T1 - Large circuit models

T2 - opportunities and challenges

AU - Chen, Lei

AU - Chen, Yiqi

AU - Chu, Zhufei

AU - Fang, Wenji

AU - Ho, Tsung Yi

AU - Huang, Ru

AU - Huang, Yu

AU - Khan, Sadaf

AU - Li, Min

AU - Li, Xingquan

AU - Li, Yu

AU - Liang, Yun

AU - Liu, Jinwei

AU - Liu, Yi

AU - Lin, Yibo

AU - Luo, Guojie

AU - Pan, Hongyang

AU - Shi, Zhengyuan

AU - Sun, Guangyu

AU - Tsaras, Dimitrios

AU - Wang, Runsheng

AU - Wang, Ziyi

AU - Wei, Xinming

AU - Xie, Zhiyao

AU - Xu, Qiang

AU - Xue, Chenhao

AU - Yan, Junchi

AU - Yang, Jun

AU - Yu, Bei

AU - Yuan, Mingxuan

AU - Young, Evangeline F.Y.

AU - Zeng, Xuan

AU - Zhang, Haoyi

AU - Zhang, Zuodong

AU - Zhao, Yuxiang

AU - Zhen, Hui Ling

AU - Zheng, Ziyang

AU - Zhu, Binwu

AU - Zhu, Keren

AU - Zou, Sunan

PY - 2024/10

Y1 - 2024/10

N2 - Within the electronic design automation (EDA) domain, artificial intelligence (AI)-driven solutions have emerged as formidable tools, yet they typically augment rather than redefine existing methodologies. These solutions often repurpose deep learning models from other domains, such as vision, text, and graph analytics, applying them to circuit design without tailoring to the unique complexities of electronic circuits. Such an “AI4EDA” approach falls short of achieving a holistic design synthesis and understanding, overlooking the intricate interplay of electrical, logical, and physical facets of circuit data. This study argues for a paradigm shift from AI4EDA towards AI-rooted EDA from the ground up, integrating AI at the core of the design process. Pivotal to this vision is the development of a multimodal circuit representation learning technique, poised to provide a comprehensive understanding by harmonizing and extracting insights from varied data sources, such as functional specifications, register-transfer level (RTL) designs, circuit netlists, and physical layouts. We champion the creation of large circuit models (LCMs) that are inherently multimodal, crafted to decode and express the rich semantics and structures of circuit data, thus fostering more resilient, efficient, and inventive design methodologies. Embracing this AI-rooted philosophy, we foresee a trajectory that transcends the current innovation plateau in EDA, igniting a profound “shift-left” in electronic design methodology. The envisioned advancements herald not just an evolution of existing EDA tools but a revolution, giving rise to novel instruments of design-tools that promise to radically enhance design productivity and inaugurate a new epoch where the optimization of circuit performance, power, and area (PPA) is achieved not incrementally, but through leaps that redefine the benchmarks of electronic systems’ capabilities.

AB - Within the electronic design automation (EDA) domain, artificial intelligence (AI)-driven solutions have emerged as formidable tools, yet they typically augment rather than redefine existing methodologies. These solutions often repurpose deep learning models from other domains, such as vision, text, and graph analytics, applying them to circuit design without tailoring to the unique complexities of electronic circuits. Such an “AI4EDA” approach falls short of achieving a holistic design synthesis and understanding, overlooking the intricate interplay of electrical, logical, and physical facets of circuit data. This study argues for a paradigm shift from AI4EDA towards AI-rooted EDA from the ground up, integrating AI at the core of the design process. Pivotal to this vision is the development of a multimodal circuit representation learning technique, poised to provide a comprehensive understanding by harmonizing and extracting insights from varied data sources, such as functional specifications, register-transfer level (RTL) designs, circuit netlists, and physical layouts. We champion the creation of large circuit models (LCMs) that are inherently multimodal, crafted to decode and express the rich semantics and structures of circuit data, thus fostering more resilient, efficient, and inventive design methodologies. Embracing this AI-rooted philosophy, we foresee a trajectory that transcends the current innovation plateau in EDA, igniting a profound “shift-left” in electronic design methodology. The envisioned advancements herald not just an evolution of existing EDA tools but a revolution, giving rise to novel instruments of design-tools that promise to radically enhance design productivity and inaugurate a new epoch where the optimization of circuit performance, power, and area (PPA) is achieved not incrementally, but through leaps that redefine the benchmarks of electronic systems’ capabilities.

KW - AI-rooted EDA

KW - circuit optimization

KW - large circuit models (LCMs)

KW - multimodal circuit representation learning

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DO - 10.1007/s11432-024-4155-7

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SN - 1674-733X

VL - 67

JO - Science China Information Sciences

JF - Science China Information Sciences

IS - 10

M1 - 200402

ER -

Large circuit models: opportunities and challenges

Abstract

User-Defined Keywords

UN SDGs

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