Performance trade-off analysis of analog circuits by normal-boundary intersection

Guido Stehr; Helmut Graeb; Kurt Antreich

doi:10.1145/776072.776073

Performance trade-off analysis of analog circuits by normal-boundary intersection

Guido Stehr
, Helmut Graeb
, Kurt Antreich

Chair of Electronic Design Automation

Technical University of Munich

Research output: Contribution to journal › Conference article › peer-review

58 Scopus citations

Abstract

We present a new technique to examine the trade-off regions of a circuit where its competing performances become "simultaneously optimal", i.e. Pareto optimal. It is based on circuit simulation, sizing rules, which capture elementary topological and technological constraints, and an advanced multicriteria optimization formulation called normal-boundary intersection. We are able to efficiently calculate a well-balanced discretization of a Pareto surface, identify the active constraints, which prevent a further improvement, and even rank these constraints in terms of stringency. Experimental results demonstrate the efficacy and efficiency of the method and its potential for topology selection and analog synthesis.

Original language	English
Pages (from-to)	958-963
Number of pages	6
Journal	Proceedings - Design Automation Conference
DOIs	https://doi.org/10.1145/776072.776073
State	Published - 2003
Event	Proceedings of the 40th Design Automation Conference - Anaheim, CA, United States Duration: 2 Jun 2003 → 6 Jun 2003

Keywords

Analog circuits
Normal-boundary intersection
Pareto optimality
Performance space exploration
Topology selection
Trade-off analysis

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10.1145/776072.776073

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title = "Performance trade-off analysis of analog circuits by normal-boundary intersection",

abstract = "We present a new technique to examine the trade-off regions of a circuit where its competing performances become {"}simultaneously optimal{"}, i.e. Pareto optimal. It is based on circuit simulation, sizing rules, which capture elementary topological and technological constraints, and an advanced multicriteria optimization formulation called normal-boundary intersection. We are able to efficiently calculate a well-balanced discretization of a Pareto surface, identify the active constraints, which prevent a further improvement, and even rank these constraints in terms of stringency. Experimental results demonstrate the efficacy and efficiency of the method and its potential for topology selection and analog synthesis.",

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language = "English",

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T1 - Performance trade-off analysis of analog circuits by normal-boundary intersection

AU - Stehr, Guido

AU - Graeb, Helmut

AU - Antreich, Kurt

PY - 2003

Y1 - 2003

N2 - We present a new technique to examine the trade-off regions of a circuit where its competing performances become "simultaneously optimal", i.e. Pareto optimal. It is based on circuit simulation, sizing rules, which capture elementary topological and technological constraints, and an advanced multicriteria optimization formulation called normal-boundary intersection. We are able to efficiently calculate a well-balanced discretization of a Pareto surface, identify the active constraints, which prevent a further improvement, and even rank these constraints in terms of stringency. Experimental results demonstrate the efficacy and efficiency of the method and its potential for topology selection and analog synthesis.

AB - We present a new technique to examine the trade-off regions of a circuit where its competing performances become "simultaneously optimal", i.e. Pareto optimal. It is based on circuit simulation, sizing rules, which capture elementary topological and technological constraints, and an advanced multicriteria optimization formulation called normal-boundary intersection. We are able to efficiently calculate a well-balanced discretization of a Pareto surface, identify the active constraints, which prevent a further improvement, and even rank these constraints in terms of stringency. Experimental results demonstrate the efficacy and efficiency of the method and its potential for topology selection and analog synthesis.

KW - Analog circuits

KW - Normal-boundary intersection

KW - Pareto optimality

KW - Performance space exploration

KW - Topology selection

KW - Trade-off analysis

UR - https://www.scopus.com/pages/publications/0043136424

U2 - 10.1145/776072.776073

DO - 10.1145/776072.776073

M3 - Conference article

AN - SCOPUS:0043136424

SN - 0738-100X

SP - 958

EP - 963

JO - Proceedings - Design Automation Conference

JF - Proceedings - Design Automation Conference

T2 - Proceedings of the 40th Design Automation Conference

Y2 - 2 June 2003 through 6 June 2003

ER -

Performance trade-off analysis of analog circuits by normal-boundary intersection

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Keywords

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