Machine Learning Prediction for Design and System Technology Co-Optimization Sensitivity Analysis

被引:0
|
作者
Cheng, Chung-Kuan [1 ]
Ho, Chia-Tung [2 ]
Holtz, Chester [1 ]
Lee, Daeyeal [2 ]
Lin, Bill [2 ]
机构
[1] Univ Calif San Diego, Dept Comp Sci, La Jolla, CA 92093 USA
[2] Univ Calif San Diego, Dept Elect & Comp Engn, La Jolla, CA 92093 USA
来源
IEEE TRANSACTIONS ON VERY LARGE SCALE INTEGRATION (VLSI) SYSTEMS | 2022年 / 30卷 / 08期
关键词
Computer architecture; Sensitivity; Predictive models; Feature extraction; Microprocessors; Libraries; Layout; Cell synthesis; complementary-FET (CFET); design technology co-optimization (DTCO); DTCO and STCO sensitivity prediction; machine learning (ML); standard cell (SDC); system technology co-optimization (STCO); STANDARD CELL SYNTHESIS; SYNTHESIS FRAMEWORK; CROSS-VALIDATION;
D O I
10.1109/TVLSI.2022.3172938
中图分类号
TP3 [计算技术、计算机技术];
学科分类号
0812 ;
摘要
As technology nodes continue to advance relentlessly, geometric pitch scaling starts to slow down. In order to retain the trend of Moore's law, design technology co-optimization (DTCO) and system technology co-optimization (STCO) are introduced together to continue scaling beyond 5 nm using pitch scaling, patterning, and novel 3-D cell structures [i.e., complementary-FET (CFET)]. However, numerous DTCO and STCO iterations are needed to continue block-level area scaling with considerations of physical layout factors: 1) various standard cell (SDC) library sets (i.e., different cell heights and conventional FET); 2) design rules (DRs); 3) back end of line (BEOL) settings; and 4) power delivery network (PDN) configurations. The growing turnaround time (TAT) among SDC design, DR optimization, and block-level area evaluation becomes one of the major bottlenecks in DTCO and STCO explorations. In this work, we develop a machine learning model that combines bootstrap aggregation and gradient boosting techniques to predict the sensitivity of minimum valid block-level area of various physical layout factors. We first demonstrate that the proposed model achieves 16.3% less mean absolute error (MAE) than the previous work for testing sets. Then, we show that the proposed model successfully captures the block-level area sensitivity of new SDC library sets, new BEOL settings, and new PDN settings with 0.013, 0.004, and 0.027 MAE, respectively. Finally, compared to the previous work, the proposed approach improves the robustness of predicting new circuit designs by up to 6.76%. The proposed framework provides more than 100x speedup compared to conventional DTCO and STCO exploration flows.
引用
收藏
页码:1059 / 1072
页数:14
相关论文
共 50 条
  • [21] Design technology co-optimization in technology definition for 22nm and beyond
    Semiconductor Research and Development Center, IBM, 2070 Rt. 52, East Fishkill, NY 10570, United States
    [J]. Dig Tech Pap Symp VLSI Technol, 2011, (112-113):
  • [22] Density Aware Cell Library Design for Design-Technology Co-Optimization
    Nishizawa, Shinichi
    Nakura, Toru
    [J]. PROCEEDINGS OF THE TWENTY THIRD INTERNATIONAL SYMPOSIUM ON QUALITY ELECTRONIC DESIGN (ISQED 2022), 2022, : 261 - 261
  • [23] Unified Technology Optimization Platform using Integrated Analysis ( UTOPIA) for holistic technology, design and system co-optimization at <=7nm nodes
    Song, S. C.
    Xu, J.
    Yang, D.
    Rim, K.
    Feng, P.
    Bao, J.
    Zhu, J.
    Wang, J.
    Nallapati, G.
    Badaroglu, M.
    Narayanasetti, P.
    Bucki, B.
    Fischer, J.
    Yeap, Geoffrey
    [J]. 2016 IEEE SYMPOSIUM ON VLSI CIRCUITS (VLSI-CIRCUITS), 2016,
  • [24] Technology-Design-Manufacturing Co-optimization for Advanced Mobile SoCs
    Yeap, Geoffrey
    [J]. 2014 IEEE PROCEEDINGS OF THE CUSTOM INTEGRATED CIRCUITS CONFERENCE (CICC), 2014,
  • [25] Design Technology Co-optimization for N14 Metall Layer
    Duan, Yingli
    Su, Xiaojing
    Chen, Ying
    Su, Yajuan
    Wei, Yayi
    Shao, Feng
    Zhang, Recco
    Lei, Junjiang
    [J]. 2016 CHINA SEMICONDUCTOR TECHNOLOGY INTERNATIONAL CONFERENCE (CSTIC), 2016,
  • [26] ADVANCED 3D DESIGN TECHNOLOGY CO-OPTIMIZATION FOR MANUFACTURABILITY
    Chen, Yu De
    Huang, Jacky
    Zhao, Dalong
    Yim, Daebin
    Ervin, Joseph
    [J]. 2019 CHINA SEMICONDUCTOR TECHNOLOGY INTERNATIONAL CONFERENCE (CSTIC), 2019,
  • [27] Technology-Design-Manufacturing Co-optimization for Advanced Mobile SoCs
    Yang, Da
    Gan, Chock
    Chidambaram, P. R.
    Nallapadi, Giri
    Zhu, John
    Song, S. C.
    Xu, Jeff
    Yeap, Geoffrey
    [J]. DESIGN-PROCESS-TECHNOLOGY CO-OPTIMIZATION FOR MANUFACTURABILITY VIII, 2014, 9053
  • [28] Design Technology Co-Optimization for Cold CMOS Benefits in Advanced Technologies
    Chiang, Hung-Li
    Wu, Jui-Jen
    Chou, Chen-Han
    Hsiao, Yen-Fu
    Chen, Yi-Chun
    Liu, Leo
    Wang, Jer-Fu
    Chen, Tzu-Chiang
    Liao, Pei-Jun
    Cai, Jin
    Bao, Xinyu
    Cheng, Alan
    Chang, Meng-Fan
    [J]. 2021 IEEE INTERNATIONAL ELECTRON DEVICES MEETING (IEDM), 2021,
  • [29] Design-technology co-optimization for 2D electronics
    Zhu, Jiadi
    Palacios, Tomas
    [J]. NATURE ELECTRONICS, 2023, 6 (11) : 803 - 804
  • [30] Design-Technology Co-optimization for Cryogenic Tensor Processing Unit
    Kang, Dong Suk
    Yu, Shimeng
    [J]. 2022 IEEE ASIA PACIFIC CONFERENCE ON CIRCUITS AND SYSTEMS, APCCAS, 2022, : 1 - 4
12345