Integrating Magnetics for On-Chip Power: A Perspective

Author

Sullivan, C.R. ; Harburg, Daniel V. ; Jizheng Qiu ; Levey, Christopher G. ; Di Yao

Author_Institution

Thayer Sch. of Eng., Dartmouth Coll., Hanover, NH, USA

Volume

28

Issue

9

fYear

2013

fDate

Sept. 2013

Firstpage

4342

Lastpage

4353

Abstract

Integration of efficient power converters requires technology for efficient, high-power on-chip inductors and transformers. Increases in switching frequency, facilitated by advances in circuit designs and silicon or wide-bandgap semiconductors, can enable miniaturization, but only if the magnetics technology works well at the higher frequencies. Technologies, geometries, and scaling of air-core and magnetic-core inductors and transformers are examined, and their potential for integration is discussed. Air-core inductors can use simpler fabrication, and increasing frequency can always be used to decrease their size, but magnetic cores can decrease the required thickness without requiring as high a frequency.

Keywords

geometry; inductors; power convertors; transformer cores; air-core inductor; circuit design; fabrication; geometries; high-power on-chip inductor; magnetic-core inductor; magnetics technology; on-chip power; power converter; switching frequency; transformer; wide-bandgap semiconductor; Conductors; Inductors; Magnetic cores; Magnetic materials; Resistance; Windings; Air-core magnetics; air gaps; electromagnetics; high-frequency dc-dc converter; inductors; integrated power converter; magnetic films; proximity effect; soft magnetic materials; thin-film inductors; transformers; very-high-frequency (VHF);

fLanguage

English

Journal_Title

Power Electronics, IEEE Transactions on

Publisher

ieee

ISSN

0885-8993

Type

jour

DOI

10.1109/TPEL.2013.2240465

Filename

6412808