Analytical models for calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials

Ivan Ndip; Abdurrahman Öz; Herbert Reichl; Klaus Dieter Lang; Heino Henke

doi:10.1109/TEMC.2014.2378284

Analytical models for calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials

Ivan Ndip, Abdurrahman Öz, Herbert Reichl, Klaus Dieter Lang, Heino Henke

Modern Languages Department

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

41 Citations (Scopus)

Abstract

Novel analytical models for accurately and efficiently calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials are derived. For verification, the inductances of bond wires having different geometrical dimensions and material properties were analytically calculated using our proposed models, and compared to those numerically extracted using Ansys Q3D. An excellent correlation was obtained, with a maximum discrepancy of approximately 1%. These models can be applied to rapidly predict the impact of the bonding parameters and their process variations right at the beginning of the design process. For example, using the models, we could predict within seconds that the loop inductance of a ground-signal bond wire configuration can be reduced by approximately 14%, 19%, or 37%, respectively, if the loop height, pitch or the distance between the bonding positions is reduced by 50%. To quantify the impact of the reductions in inductance on realistic signal transmission characteristics of the wires, we fabricated and measured bond wire interconnects up to 40 GHz.

Original language	English
Article number	6990557
Pages (from-to)	241-249
Number of pages	9
Journal	IEEE Transactions on Electromagnetic Compatibility
Volume	57
Issue number	2
DOIs	https://doi.org/10.1109/TEMC.2014.2378284
Publication status	Published - 1 Apr 2015

Keywords

Bond wire inductance
Gaussian function
intrasystem electromagnetic compatibility (EMC)
radio frequency (RF)/microwave
signal/power integrity
skin effect

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10.1109/TEMC.2014.2378284

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title = "Analytical models for calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials",

abstract = "Novel analytical models for accurately and efficiently calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials are derived. For verification, the inductances of bond wires having different geometrical dimensions and material properties were analytically calculated using our proposed models, and compared to those numerically extracted using Ansys Q3D. An excellent correlation was obtained, with a maximum discrepancy of approximately 1\%. These models can be applied to rapidly predict the impact of the bonding parameters and their process variations right at the beginning of the design process. For example, using the models, we could predict within seconds that the loop inductance of a ground-signal bond wire configuration can be reduced by approximately 14\%, 19\%, or 37\%, respectively, if the loop height, pitch or the distance between the bonding positions is reduced by 50\%. To quantify the impact of the reductions in inductance on realistic signal transmission characteristics of the wires, we fabricated and measured bond wire interconnects up to 40 GHz.",

keywords = "Bond wire inductance, Gaussian function, intrasystem electromagnetic compatibility (EMC), radio frequency (RF)/microwave, signal/power integrity, skin effect",

author = "Ivan Ndip and Abdurrahman {\"O}z and Herbert Reichl and Lang, \{Klaus Dieter\} and Heino Henke",

note = "Publisher Copyright: {\textcopyright} 1964-2012 IEEE.",

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AU - Ndip, Ivan

AU - Öz, Abdurrahman

AU - Reichl, Herbert

AU - Lang, Klaus Dieter

AU - Henke, Heino

PY - 2015/4/1

Y1 - 2015/4/1

N2 - Novel analytical models for accurately and efficiently calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials are derived. For verification, the inductances of bond wires having different geometrical dimensions and material properties were analytically calculated using our proposed models, and compared to those numerically extracted using Ansys Q3D. An excellent correlation was obtained, with a maximum discrepancy of approximately 1%. These models can be applied to rapidly predict the impact of the bonding parameters and their process variations right at the beginning of the design process. For example, using the models, we could predict within seconds that the loop inductance of a ground-signal bond wire configuration can be reduced by approximately 14%, 19%, or 37%, respectively, if the loop height, pitch or the distance between the bonding positions is reduced by 50%. To quantify the impact of the reductions in inductance on realistic signal transmission characteristics of the wires, we fabricated and measured bond wire interconnects up to 40 GHz.

AB - Novel analytical models for accurately and efficiently calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials are derived. For verification, the inductances of bond wires having different geometrical dimensions and material properties were analytically calculated using our proposed models, and compared to those numerically extracted using Ansys Q3D. An excellent correlation was obtained, with a maximum discrepancy of approximately 1%. These models can be applied to rapidly predict the impact of the bonding parameters and their process variations right at the beginning of the design process. For example, using the models, we could predict within seconds that the loop inductance of a ground-signal bond wire configuration can be reduced by approximately 14%, 19%, or 37%, respectively, if the loop height, pitch or the distance between the bonding positions is reduced by 50%. To quantify the impact of the reductions in inductance on realistic signal transmission characteristics of the wires, we fabricated and measured bond wire interconnects up to 40 GHz.

KW - Bond wire inductance

KW - Gaussian function

KW - intrasystem electromagnetic compatibility (EMC)

KW - radio frequency (RF)/microwave

KW - signal/power integrity

KW - skin effect

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Analytical models for calculating the inductances of bond wires in dependence on their shapes, bonding parameters, and materials

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