Sampling-based imaging model for fast source and mask optimization in immersion lithography

Yiyu Sun; Yanqiu Li; Guanghui Liao; Miao Yuan; Pengzhi Wei; Yaning Li; Lulu Zou; Lihui Liu

doi:10.1364/AO.437655

Sampling-based imaging model for fast source and mask optimization in immersion lithography

Yiyu Sun, Yanqiu Li^*, Guanghui Liao, Miao Yuan, Pengzhi Wei, Yaning Li, Lulu Zou, Lihui Liu

^*Corresponding author for this work

School of Optics and Photonics

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Current source and mask optimization (SMO) research tends to focus on advanced inverse optimization algorithms to accelerate SMO procedures. However, innovations of forward imaging models currently attract little attention, which impacts computational efficiency more significantly. A sampling-based imaging model is established with the innovation of an inverse point spread function to reduce computational dimensions, which can provide an advanced framework for fast inverse lithography. Simulations show that the proposed SMO method with the help of the proposed model can further speed up the algorithm-accelerated SMO procedure by a factor of 3.

Original language	English
Pages (from-to)	523-531
Number of pages	9
Journal	Applied Optics
Volume	61
Issue number	2
DOIs	https://doi.org/10.1364/AO.437655
Publication status	Published - 10 Jan 2022

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title = "Sampling-based imaging model for fast source and mask optimization in immersion lithography",

abstract = "Current source and mask optimization (SMO) research tends to focus on advanced inverse optimization algorithms to accelerate SMO procedures. However, innovations of forward imaging models currently attract little attention, which impacts computational efficiency more significantly. A sampling-based imaging model is established with the innovation of an inverse point spread function to reduce computational dimensions, which can provide an advanced framework for fast inverse lithography. Simulations show that the proposed SMO method with the help of the proposed model can further speed up the algorithm-accelerated SMO procedure by a factor of 3.",

author = "Yiyu Sun and Yanqiu Li and Guanghui Liao and Miao Yuan and Pengzhi Wei and Yaning Li and Lulu Zou and Lihui Liu",

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AU - Sun, Yiyu

AU - Li, Yanqiu

AU - Liao, Guanghui

AU - Yuan, Miao

AU - Wei, Pengzhi

AU - Li, Yaning

AU - Zou, Lulu

AU - Liu, Lihui

PY - 2022/1/10

Y1 - 2022/1/10

N2 - Current source and mask optimization (SMO) research tends to focus on advanced inverse optimization algorithms to accelerate SMO procedures. However, innovations of forward imaging models currently attract little attention, which impacts computational efficiency more significantly. A sampling-based imaging model is established with the innovation of an inverse point spread function to reduce computational dimensions, which can provide an advanced framework for fast inverse lithography. Simulations show that the proposed SMO method with the help of the proposed model can further speed up the algorithm-accelerated SMO procedure by a factor of 3.

AB - Current source and mask optimization (SMO) research tends to focus on advanced inverse optimization algorithms to accelerate SMO procedures. However, innovations of forward imaging models currently attract little attention, which impacts computational efficiency more significantly. A sampling-based imaging model is established with the innovation of an inverse point spread function to reduce computational dimensions, which can provide an advanced framework for fast inverse lithography. Simulations show that the proposed SMO method with the help of the proposed model can further speed up the algorithm-accelerated SMO procedure by a factor of 3.

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JO - Applied Optics

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Sampling-based imaging model for fast source and mask optimization in immersion lithography

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