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面向纳米电路的改进型卷积核可制造性模型建模研究

杨祎巍 张宏博 李斌

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面向纳米电路的改进型卷积核可制造性模型建模研究

杨祎巍, 张宏博, 李斌

Improved convolution kernel based DFM model for nano-scale circuits

Yang Yi-Wei, Zhang Hong-Bo, Li Bin
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  • 囿于材料和工艺稳定性等原因, 纳米级集成电路制造依然基于193 nm激发光的工艺, 光刻波长远大于版图尺寸, 使得制造中光的干涉和衍射现象极大降低了分辨率, 影响了芯片质量, 因此版图在制造前需要使用可制造性模型进行查错. 传统模型对制造过程进行物理建模, 通过对模型中的矩阵进行分解得到卷积核, 所使用的物理模型不仅复杂, 而且应用难度高, 加之还有物理模型缺失的情况, 因此难以描述具有上千参数的生产线. 本文使用卷积的形式作为可制造性模型的框架, 通过优化算法提取版图到硅片轮廓这一过程的信息并以卷积核的形式体现出来, 卷积核中的每一个元素均为根据已知的生产线输入输出数据优化得出, 是描述制造过程的一个维度. 该模型克服了传统模型需要工艺参数等机密信息的缺陷, 同时具有更强的描述制造过程的能力; 模型甚至可以包含版图校正信息, 描述从版图到硅片轮廓这一全流程. 该模型在65 nm工艺下的实验结果表明该模型具有8 nm的精度.
    Limited by materials and process stability, the nano-scale IC manufacturing process is still based on the 193 nm light technology and the wavelength is larger than the feature size of layout, thus the induced interference and diffraction greatly reduce the resolution, which affect the quality of the chip. So the layout needs to be checked by the design-for-manufacturability (DfM) model before manufacturing. Traditional DfM models describe the process steps using physical models, and deduce the convolution kernels by decomposing the matrix in corresponding physical models, which are not only complicated but also hard to use; thus combined with the insufficiency of physical models, it is difficult to describe the process with thousands of parameters. This paper uses convolution form as the framework of DfM model, and deduces the relationship, represented as convolution kernels, between layout and contour by an optimization method. Every element in the convolution kernels is optimized based on the input and output data of the process and is also a dimension to describe the process. This model overcomes the disadvantages of the traditional model which needs confidential information such as process parameters, and it has more powerful capability to describe the process. Moreover, the model can contain the layout correction information, and describe the process from layout to contour. Experiment results for 65 nm process show that the model has an accuracy of 8 nm.
    • 基金项目: 中央高校基本科研业务费(批准号: 2013ZM0015)资助的课题.
    • Funds: Project supported by the Fundamental Research Fund for the Central Universities of China (Grant No. 2013ZM0015).
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    Zavyalova L V, Lan Luan, Hua Song, Thomas Schmoeller, Shiely J P 2014 Optical Microlithography XXVII San Jose, California, USA, February 23, 2014 p905222

    [26]

    Chen D L, Cao Y P, Huang Z F, Lu X, Zhai A P 2012 Chin. Phys. B 21 084201

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    Wang H, Li C H, Pan F, Wang H B, Yan D H 2009 Chin. Phys. Lett. 26 118501

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    Katakamsetty U, Colin H, Yeo S, Valerio P, Yang Qing, Quek Shyue Fong, Aravind, N S Matthias, R Roberto S 2014 Design-Process-Technology Co-optimization for Manufacturability VIII 2014 San Jose, CA, USA, 23 Feb. 2014 p905312

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    Yan W X, Wang L Y, Zhang Z F, Liu W L, Song Z T 2014 Chin. Phys. B 23 048301

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  • [1]

    www.itrs.net

    [2]

    Tian X B, Xu H, Li Q J 2013 Chin. Phys. B 22 088502

    [3]

    Fang X D, Tang Y H, Wu J J, Zhu X, Zhou J, Huang D 2013 Chin. Phys. B 22 078901

    [4]

    Cai D L, Song Z T, Li X, Chen H P, Chen X G 2011 Chin. Phys. Lett. 28 018501

    [5]

    Zhu Z M, Li R, Hao B T, Yang Y T 2009 Chin. Phys. B 18 4995

    [6]

    Cobb N B, Avideh Zakhor 1995 15th Annual BACUS Symposium on Photomask Technology and Management Santa Clara, CA, September 20, 1995 p534

    [7]

    Cobb N, Dudau D 2006 Proc. SPIE 6154, Optical Microlithography XIX San Jose, CA, February 19, 2006 p61540I

    [8]

    Jaione T A, Alan E R, Timothy B 2014 J. Micro/Nanolith. MEMS MOEMS. 13 023014

    [9]

    Lori A J, Michael T R, Jason D, Christiane J 2002 Proc. SPIE 4691, Optical Microlithography XV Santa Clara, CA, March 03, 2002 p861

    [10]

    Bouton G, Connolly B, Courboin D, Di Giacomo A, Gasnier F, Lallement R, Parker D, Pindo M, Richoilley J C, Royere F, Rameau-Savio A, Tissier M 2011 27th European Mask and Lithography Conference Dresden, Germany, January 18, 2011 p79850R

    [11]

    Carau D, Bouyssou R, Dezauzier C, Besacier M, Gourgon C 2014 Optical Micro-and Nanometrology V Brussels, Belgium, April 14, 2014 p91320D

    [12]

    Michael Hyatt, Karen Huang, Anton DeVilliers, Mark Slezak, Zhi Liu 2014 Advances in Patterning Materials and Processes XXXI San Jose, California, USA, February 23, 2014 p905118

    [13]

    Drapeau M, Wiaux V, Hendrickx E, Verhaegen S, Machida T 2007 Conference on Design for Manufacturability through Design-Process Integration San Jose, CA 2007 p652109

    [14]

    Ghaida R S, Torres G, Gupta, P 2011 Semiconductor Manufacturing, IEEE Transactions on 24 93

    [15]

    Poonawala A, Milanfar P 2007 Image Processing, IEEE Transactions on 16 774

    [16]

    Alexandre Villaret, Alexander Tritchkov, Jorge Entradas, Emek Yesilada 2013 Optical Microlithography XXVI San Jose, California, USA, February 24, 2013 p86830E

    [17]

    Lv W, Xia Q, Liu S Y 2013 J. MicroNanolith. Mems Moems 12 043003

    [18]

    Wang J P, Qi S Y, Liu S G 2014 Acta Phys. Sin. 63 128503 (in Chinese) [王俊平, 戚苏阳, 刘士钢 2014 63 128503]

    [19]

    Kong JT 2004 IEEE Transactions on VLSI Systems 12 1132

    [20]

    Zhang Z M, Xiao P, Sun X, Ding Z J 2006 Acta Phys. Sin. 55 5803 (in Chinese) [张增明, 肖沛, 孙霞, 丁泽军 2006 55 5803]

    [21]

    Mazen Saied, Franck Foussadier, Jérô me Belledent, Yorick Trouiller, Isabelle Schanen, Emek Yesilada, Christian Gardin, Jean Christophe Urbani, Frank Sundermann, Frédéric Robert, Christophe Couderc, Florent Vautrin, Laurent LeCam, Gurwan Kerrien, Jonathan Planchot, Catherine Martinelli, Bill Wilkinson, Yves Rody, Amandine Borjon, Nicolo Morgana, Jean-Luc Di-Maria, Vincent Farys 2007 Photomask Technology 2007 Monterey, CA, September 17, 2007 p673050

    [22]

    Viviana Agudelo, Tim Fhner, Andreas Erdmann, Peter Evanschitzky 2013 J. MicroNanolith. MEMS MOEMS. 13 011002

    [23]

    Chen D L, Cao Y P, Huang Z F 2011 Chin. Phys. Lett. 28 068503

    [24]

    Ye Chen, Zheng Shi, Ke Zhou, Yue Ma, Shanhu Shen, Xiaolang Yan 2006 Solid-State and Integrated Circuit Technology, 2006 ICSICT'06 8th International Conference on 2006 pp1453-1455

    [25]

    Zavyalova L V, Lan Luan, Hua Song, Thomas Schmoeller, Shiely J P 2014 Optical Microlithography XXVII San Jose, California, USA, February 23, 2014 p905222

    [26]

    Chen D L, Cao Y P, Huang Z F, Lu X, Zhai A P 2012 Chin. Phys. B 21 084201

    [27]

    Wang H, Li C H, Pan F, Wang H B, Yan D H 2009 Chin. Phys. Lett. 26 118501

    [28]

    Katakamsetty U, Colin H, Yeo S, Valerio P, Yang Qing, Quek Shyue Fong, Aravind, N S Matthias, R Roberto S 2014 Design-Process-Technology Co-optimization for Manufacturability VIII 2014 San Jose, CA, USA, 23 Feb. 2014 p905312

    [29]

    Yan W X, Wang L Y, Zhang Z F, Liu W L, Song Z T 2014 Chin. Phys. B 23 048301

    [30]

    He A D, L B, Song Z T, Wang L Y, Liu W L, Feng G M, Feng S L 2014 Chin. Phys. B 23 088802

    [31]

    Yang Y W, Shi Z, Sun L T, Chen Y, Hu Z J 2010 i Design for Manufacturability through Design-Process Integration IV San Jose, CA, USA, 3 April 2010 p76410O

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出版历程
  • 收稿日期:  2014-07-19
  • 修回日期:  2014-10-09
  • 刊出日期:  2015-03-05

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