Suppression of edge effects based on analytic model for leakage current reduction of sub-40 nm DRAM device

Soo Han Choi; Young Hee Park; Chul Hong Park; Sang Hoon Lee; Moon Hyun Yoo; Jun Dong Cho; Gyu Tae Kim

doi:10.1587/transele.E93.C.658

Suppression of edge effects based on analytic model for leakage current reduction of sub-40 nm DRAM device

Soo Han Choi, Young Hee Park, Chul Hong Park, Sang Hoon Lee, Moon Hyun Yoo, Jun Dong Cho, Gyu Tae Kim

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

Abstract

With the process scaling, the leakage current reduction has been the primary design concerns in a nanometer-era VLSI circuit. In this paper, we propose a new lithography process-aware edge effects correction method to reduce the leakage current in the shallow trench isolation (STI). We construct the various test structures to model I_leakage and I _{leakage fringe} which represent the leakage currents at the center and edge of the transistor, respectively. The layout near the active edge is modified using the look-up table generated by the calibrated analytic model. On average, the proposed edge effects correction method reduces the leakage current by 18% with the negligible decrease of the drive current at sub-40nm DRAM device.

Original language	English
Pages (from-to)	658-661
Number of pages	4
Journal	IEICE Transactions on Electronics
Volume	E93-C
Issue number	5
DOIs	https://doi.org/10.1587/transele.E93.C.658
Publication status	Published - 2010

Keywords

Analytic model
Drive current
Edge effects
Leakage current
OPC
Retargeting
Shaping gate channels

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Electrical and Electronic Engineering

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10.1587/transele.E93.C.658

Cite this

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abstract = "With the process scaling, the leakage current reduction has been the primary design concerns in a nanometer-era VLSI circuit. In this paper, we propose a new lithography process-aware edge effects correction method to reduce the leakage current in the shallow trench isolation (STI). We construct the various test structures to model Ileakage and I leakage fringe which represent the leakage currents at the center and edge of the transistor, respectively. The layout near the active edge is modified using the look-up table generated by the calibrated analytic model. On average, the proposed edge effects correction method reduces the leakage current by 18% with the negligible decrease of the drive current at sub-40nm DRAM device.",

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AU - Choi, Soo Han

AU - Park, Young Hee

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AU - Lee, Sang Hoon

AU - Yoo, Moon Hyun

AU - Cho, Jun Dong

AU - Kim, Gyu Tae

PY - 2010

Y1 - 2010

N2 - With the process scaling, the leakage current reduction has been the primary design concerns in a nanometer-era VLSI circuit. In this paper, we propose a new lithography process-aware edge effects correction method to reduce the leakage current in the shallow trench isolation (STI). We construct the various test structures to model Ileakage and I leakage fringe which represent the leakage currents at the center and edge of the transistor, respectively. The layout near the active edge is modified using the look-up table generated by the calibrated analytic model. On average, the proposed edge effects correction method reduces the leakage current by 18% with the negligible decrease of the drive current at sub-40nm DRAM device.

AB - With the process scaling, the leakage current reduction has been the primary design concerns in a nanometer-era VLSI circuit. In this paper, we propose a new lithography process-aware edge effects correction method to reduce the leakage current in the shallow trench isolation (STI). We construct the various test structures to model Ileakage and I leakage fringe which represent the leakage currents at the center and edge of the transistor, respectively. The layout near the active edge is modified using the look-up table generated by the calibrated analytic model. On average, the proposed edge effects correction method reduces the leakage current by 18% with the negligible decrease of the drive current at sub-40nm DRAM device.

KW - Analytic model

KW - Drive current

KW - Edge effects

KW - Leakage current

KW - OPC

KW - Retargeting

KW - Shaping gate channels

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Suppression of edge effects based on analytic model for leakage current reduction of sub-40 nm DRAM device

Abstract

Keywords

ASJC Scopus subject areas

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