Lithography driven layout of Logic Cells for 65nm node

被引：0

作者：

Pramanik, D ^{[1
]}

Cote, M ^{[1
]}

机构：

[1] Synopsys Inc, Mountain View, CA 94043 USA

来源：

DESIGN AND PROCESS INTEGRATION FOR MICROELECTRONIC MANUFACTURING | 2003年

关键词：

D O I：

10.1117/12.485349

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

The ITRS roadmap for the 65nm technology node, targets poly gate lengths of 65nm and poly pitches between 140-180nm. In addition, contact overlaps and spacing to diffusion contacts will need to be scaled down. It is very likely that the poly layer will be printed using 193nm high NA steppers and Strong Phase Shift Technologies. Attempts to capture the effect of RET on layout by adding more constraints to the design rules make it difficult to lay out cells using manual tools and can also lead to sub optimal designs. In this paper we describe a methodology that couples automatic cell generation with Phase shifter insertion and image simulation to allow the design space to be explored more fully.

引用

页码：126 / 134

页数：9

共 50 条

[21] Advanced photomask repair technology for 65nm lithography (5)
Aramaki, Fumio
Kozakai, Tomokazu
Sugiyama, Yasuhiko
Muramatsu, Masashi
Koyama, Yoshihiro
Matsuda, Osamu
Suzuki, Katsumi
Okabe, Mamoru
Hagiwara, Ryoji
Yasaka, Anto
Adachi, Tatsuya
Tanaka, Yoshiyuki
Suga, Osamu
Nishida, Naoki
Usui, Youichi
[J]. PHOTOMASK AND NEXT GENERATION LITHOGRAPHY MASK TECHNOLOGY XIII, PTS 1 AND 2, 2006, 6283
[22] The study of contact hole for 65nm node with KrF
You, Tae-Jun
Ko, Sung-Woo
Moon, James
Ahn, Yeong-Bae
Nam, Byung-Ho
Yim, Dong-Gyu
[J]. PHOTOMASK AND NEXT GENERATION LITHOGRAPHY MASK TECHNOLOGY XIII, PTS 1 AND 2, 2006, 6283
[23] Advanced photomask repair technology for 65nm lithography (6)
Aramaki, Fumio
Kozakai, Tomokazu
Muramatsu, Masashi
Sugiyama, Yasuhiko
Koyama, Yoshihiro
Matsuda, Osamu
Suzuki, Katsumi
Okabe, Mamoru
Doi, Toshio
Hagiwara, Ryoji
Adachi, Tatsuya
Yasaka, Anto
Tanaka, Yoshiyuki
Suga, Osamu
Nishida, Naoki
Usul, Youichi
[J]. PHOTOMASK TECHNOLOGY 2006, PTS 1 AND 2, 2006, 6349
[24] Advanced photomask repair technology for 65nm lithography (3)
Itou, Y
Tanaka, Y
Sugiyama, Y
Hagiwara, R
Takahashi, H
Takaoka, O
Kozakai, T
Matsuda, O
Suzuki, K
Okabe, M
Kikuchi, S
Uemoto, A
Yasaka, A
Adachi, T
Nishida, N
[J]. Photomask and Next-Generation Lithography Mask Technology XII, Pts 1 and 2, 2005, 5853 : 1000 - 1008
[25] Microeconomics of overlay control at the 65nm technology node
Allgair, JA
Monahan, KM
[J]. 2003 IEEE INTERNATIONAL SYMPOSIUM ON SEMICONDUCTOR MANUFACTURING, CONFERENCE PROCEEDINGS, 2003, : 103 - 106
[26] Advanced photomask repair technology for 65nm lithography (1)
Itou, Y
Tanaka, Y
Yoshioka, N
Sugiyama, Y
Hagiwara, R
Takahashi, H
Takaoka, O
Tashiro, J
Suzuki, K
Okabe, M
Kikuchi, S
Uemoto, A
Yasaka, A
Adachi, T
Nishida, N
Ozawa, T
[J]. PHOTOMASK AND NEXT GENERATION LITHOGRAPHY MASK TECHNOLOGY XI, 2004, 5446 : 301 - 312
[27] Application of CPL with Interference Mapping Lithography™ to generate random contact reticle designs for the 65nm node
Van Den Broeke, D
Laidig, T
Chen, JF
Wampler, K
Hsu, S
Shi, XL
Socha, R
Dusa, M
Corcoran, N
[J]. PHOTOMASK AND NEXT GENERATION LITHOGRAPHY MASK TECHNOLOGY XI, 2004, 5446 : 550 - 559
[28] AAPSM space-imbalance reduction for 65nm lithography
Jhaveri, T
Cottle, R
Zhang, Y
Progler, CJ
[J]. MICROLITHOGRAPHY WORLD, 2005, 14 (02): : 16 - +
[29] Optimized illumination settings extend ArF lithography to 65nm
Hsu, SH
Fang, SP
Huang, IH
Lin, BSM
Hung, KC
[J]. SOLID STATE TECHNOLOGY, 2004, 47 (08) : 39 - +
[30] Investigation of quartz defect printability at the 65nm node
Poortinga, E
Taylor, D
[J]. PHOTOMASK AND NEXT GENERATION LITHOGRAPHY MASK TECHNOLOGY XI, 2004, 5446 : 279 - 284

← 1 2 3 4 5 →