Design optimization of a current mirror amplifier integrated circuit using a computational statistics technique

Yiming Li; Yih Lang Li; Shao Ming Yu

doi:10.1016/j.matcom.2007.11.002

Design optimization of a current mirror amplifier integrated circuit using a computational statistics technique

Yiming Li, Yih Lang Li, Shao Ming Yu^*

^*Corresponding author for this work

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

12 Scopus citations

Abstract

In this work, we implement a computational statistics technique for design optimization of integrated circuits (ICs). Integration of a well-known circuit simulation software and central composite design method enables us to construct a second-order response surface model (RSM) for each concerned constraint. After construction of RSMs, we verify the adequacy and accuracy using the normal residual plots and their residual of squares. The constructed models are further employed for design optimization of current mirror amplifier ICs with 0.18μ m CMOS devices. By considering the voltage gain, cut-off frequency, phase margin, common-mode rejection ratio and slew-rate, six designing parameters including the width and length of different transistors are selected and optimized to fit the targets.

Original language	English
Pages (from-to)	1165-1177
Number of pages	13
Journal	Mathematics and Computers in Simulation
Volume	79
Issue number	4
DOIs	https://doi.org/10.1016/j.matcom.2007.11.002
State	Published - 15 Dec 2008

Keywords

Central composite design
Current mirror amplifier
Integrated circuits
Optimization
Response surface model

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10.1016/j.matcom.2007.11.002

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abstract = "In this work, we implement a computational statistics technique for design optimization of integrated circuits (ICs). Integration of a well-known circuit simulation software and central composite design method enables us to construct a second-order response surface model (RSM) for each concerned constraint. After construction of RSMs, we verify the adequacy and accuracy using the normal residual plots and their residual of squares. The constructed models are further employed for design optimization of current mirror amplifier ICs with 0.18μ m CMOS devices. By considering the voltage gain, cut-off frequency, phase margin, common-mode rejection ratio and slew-rate, six designing parameters including the width and length of different transistors are selected and optimized to fit the targets.",

keywords = "Central composite design, Current mirror amplifier, Integrated circuits, Optimization, Response surface model",

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T1 - Design optimization of a current mirror amplifier integrated circuit using a computational statistics technique

AU - Li, Yiming

AU - Li, Yih Lang

AU - Yu, Shao Ming

PY - 2008/12/15

Y1 - 2008/12/15

N2 - In this work, we implement a computational statistics technique for design optimization of integrated circuits (ICs). Integration of a well-known circuit simulation software and central composite design method enables us to construct a second-order response surface model (RSM) for each concerned constraint. After construction of RSMs, we verify the adequacy and accuracy using the normal residual plots and their residual of squares. The constructed models are further employed for design optimization of current mirror amplifier ICs with 0.18μ m CMOS devices. By considering the voltage gain, cut-off frequency, phase margin, common-mode rejection ratio and slew-rate, six designing parameters including the width and length of different transistors are selected and optimized to fit the targets.

AB - In this work, we implement a computational statistics technique for design optimization of integrated circuits (ICs). Integration of a well-known circuit simulation software and central composite design method enables us to construct a second-order response surface model (RSM) for each concerned constraint. After construction of RSMs, we verify the adequacy and accuracy using the normal residual plots and their residual of squares. The constructed models are further employed for design optimization of current mirror amplifier ICs with 0.18μ m CMOS devices. By considering the voltage gain, cut-off frequency, phase margin, common-mode rejection ratio and slew-rate, six designing parameters including the width and length of different transistors are selected and optimized to fit the targets.

KW - Central composite design

KW - Current mirror amplifier

KW - Integrated circuits

KW - Optimization

KW - Response surface model

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EP - 1177

JO - Mathematics and Computers in Simulation

JF - Mathematics and Computers in Simulation

IS - 4

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Design optimization of a current mirror amplifier integrated circuit using a computational statistics technique

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