Gerard Luk-Pat scite author profile

Self-aligned double patterning (SADP) lithography is a leading technology for 10nm node Metal layer fabrication. In order to achieve successful decomposition, SADP-compliant design becomes a necessity. Spacer-Is-Dielectric (SID) is the most popular flavor of SADP with higher flexibility in design. This paper makes a careful study on the challenges for SID-compliant detailed routing and proposes a graph model to capture the decomposition violations and SID intrinsic residue issues. Then a negotiated congestion based scheme is adopted to solve the overall routing problem. The proposed SID-compliant detailed routing algorithm simultaneously assigns colors to the routed wires, which provides valuable information guiding SID decomposition. In addition, if one pin has multiple candidate locations, the optimal one will be automatically determined during detailed routing. The decomposability of the conflict-free routing layers produced by our detailed router is verified by a commercial SADP decomposition tool.

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A high-performance triple patterning layout decomposer with balanced density

Lin

Luk-Pat

et al. 2013

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Triple patterning lithography (TPL) has received more and more attentions from industry as one of the leading candidate for 14nm/11nm nodes. In this paper, we propose a high performance layout decomposer for TPL. Density balancing is seamlessly integrated into all key steps in our TPL layout decomposition, including density-balanced semi-definite programming (SDP), density-based mapping, and densitybalanced graph simplification. Our new TPL decomposer can obtain high performance even compared to previous state-of-the-art layout decomposers which are not balanced-density aware, e.g., by Yu et al. (ICCAD'11), Fang et al. (DAC'12), and Kuang et al. (DAC'13). Furthermore, the balanced-density version of our decomposer can provide more balanced density which leads to less edge placement error (EPE), while the conflict and stitch numbers are still very comparable to our non-balanced-density baseline.

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<title>Implications of triple patterning for 14nm node design and patterning</title>

Lucas

Cork²,

Yu³

et al. 2012

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The upcoming 14nm logic node will require lithographic patterning of complex layout patterns with minimum pitches of approximately 44nm to 50nm. This requirement is technically feasible by reusing existing 20nm litho-etch-litho-etch (LELE) double patterning (DPT) methods with very strong restricted design rules. However, early indications are that the cost-effective design and patterning of these layouts will require lithographic methods with additional resolution, especially in two-dimensional configurations. If EUV lithography reaches maturity too late, the 14nm logic node will need other lithographic techniques and the corresponding physical design rules and EDA methodologies to be available. Triple patterning technology (TPT) is a strong option for 14nm node logic on both hole and line-space pattern layers. In this paper we study major implications of a 14nm logic TPT lithographic solution upon physical design, design rules, mask synthesis/EDA algorithms and their process interactions.

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Design compliance for spacer is dielectric (SID) patterning

Luk-Pat

Miloslavsky

Painter

et al. 2012

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Gerard Luk-Pat

High-resolution three-dimensional in vivo imaging of atherosclerotic plaque

Spacer-is-dielectric-compliant detailed routing for self-aligned double patterning lithography

A high-performance triple patterning layout decomposer with balanced density

<title>Implications of triple patterning for 14nm node design and patterning</title>

Design compliance for spacer is dielectric (SID) patterning

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