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Analytical Expressions for Inductances of 3-D Air-Core Inductors for Integrated Power Supply

Chandra Shetty, Youssef Kandeel, Liang Ye, Séamus O’Driscoll, Paul McCloskey, Maeve Duffy, Cian Ó Mathúna

2021IEEE Journal of Emerging and Selected Topics in Power Electronics17 citationsDOI

Abstract

This work presents analytical expressions for the dc inductance of 3-D air-core inductors with circular cross-sectional pillars (CCSPs) and rectangular cross-sectional pillars (RCSPs). We consider the following four types of inductor structures: 1) a toroid with CCSP; 2) a toroid with RCSP; 3) a solenoid with RCSP; and 4) a solenoid with CCSP. For each type, a unique analytical model is developed for obtaining dc inductance. High-frequency (1&#x2013;100 MHz) effects on inductance are also discussed. The inductance values predicted by the proposed analytical models of the first three types of inductor structures are in an acceptable agreement with numerical finite-element analysis (FEA) solutions, where the maximum difference is 7.3&#x0025;. Also, our analytical model for the fourth-type inductor reduces the error, when correlated with FEA inductance value, up to <inline-formula> <tex-math notation="LaTeX">$6\times $ </tex-math></inline-formula> compared with previously published models. A comparison of results using the proposed analytical expressions with published measured values as well as our measurement data demonstrates the error ranging from 0.5&#x0025; to 16.2&#x0025;, while conventional formulas show errors of up to 143&#x0025;. The results of the proposed models could serve as a good initial estimate for power supply-on-chip (PwrSoC) and power supply in package (PSiP) applications.

Topics & Concepts

InductanceInductorSolenoidPower (physics)Equivalent series inductanceFinite element methodToroidTopology (electrical circuits)Electrical engineeringElectronic engineeringPhysicsEngineeringMathematicsVoltageStructural engineeringPlasmaQuantum mechanicsElectromagnetic Compatibility and Noise SuppressionElectrostatic Discharge in Electronics3D IC and TSV technologies