TY - JOUR
T1 - Embedded Inductors Using Composite Magnetic Materials for 12-1-V Integrated Voltage Regulators
AU - Alvarez Barros, Claudio
AU - Murali, Prahalad
AU - Swaminathan, Madhavan
AU - Yusuke, Oishi
AU - Junichi, Takashiro
AU - Ryo, Nagatsuka
AU - Watanabe, Naoki
N1 - Publisher Copyright:
© 2011-2012 IEEE.
PY - 2021/12/1
Y1 - 2021/12/1
N2 - Substrate-embedded inductors enable the miniaturization of power modules and integrated voltage regulators (IVRs) with higher power efficiencies and performance. However, embedded inductors for single-stage 12- or 48-1-V high-conversion-ratio IVRs present new performance challenges due to limitations in magnetic materials, limited space, high frequency, and low duty cycle. In this work, we analyze seven embedded inductor designs fabricated with four metal-polymer composites magnetic materials. These inductors have inductances ranging from 20 to 500 nH, dc resistances between 14 and 40 text{m}Omega , and saturation currents from 100 mA to over 5 A. Each inductor is characterized for its small-signal spectra with and without dc bias current and for its large-signal response. With all these measurements, a relation between the small- and large-signal losses is made, showing that using the new R_{mathrm{ acx}} metric, they are related by a factor kappa . The measurements show that, in the megahertz range, the large-signal losses can be over four times larger than the small-signal ones. These analyses allow us to understand the material properties and modeling new magnetic materials targeted for high-conversion-ratio IVRs with input voltages greater than 5 V.
AB - Substrate-embedded inductors enable the miniaturization of power modules and integrated voltage regulators (IVRs) with higher power efficiencies and performance. However, embedded inductors for single-stage 12- or 48-1-V high-conversion-ratio IVRs present new performance challenges due to limitations in magnetic materials, limited space, high frequency, and low duty cycle. In this work, we analyze seven embedded inductor designs fabricated with four metal-polymer composites magnetic materials. These inductors have inductances ranging from 20 to 500 nH, dc resistances between 14 and 40 text{m}Omega , and saturation currents from 100 mA to over 5 A. Each inductor is characterized for its small-signal spectra with and without dc bias current and for its large-signal response. With all these measurements, a relation between the small- and large-signal losses is made, showing that using the new R_{mathrm{ acx}} metric, they are related by a factor kappa . The measurements show that, in the megahertz range, the large-signal losses can be over four times larger than the small-signal ones. These analyses allow us to understand the material properties and modeling new magnetic materials targeted for high-conversion-ratio IVRs with input voltages greater than 5 V.
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U2 - 10.1109/TCPMT.2021.3116946
DO - 10.1109/TCPMT.2021.3116946
M3 - Article
AN - SCOPUS:85118672868
SN - 2156-3950
VL - 11
SP - 2183
EP - 2192
JO - IEEE Transactions on Components, Packaging and Manufacturing Technology
JF - IEEE Transactions on Components, Packaging and Manufacturing Technology
IS - 12
ER -