Low-Resistance Integrated Toroidal Inductor for Power Management

5.6 mm times 5.6 mm integrated toroidal inductors with reduced thickness down to 200 mum have been realized. A high inductance-to-dc resistance ratio have been achieved using a toroidal geometry. The realization features thick Cu winding and a thick laminated Ni 80 Fe 20 core with crossed anisotropy...

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Veröffentlicht in:	IEEE transactions on magnetics 2006-10, Vol.42 (10), p.3374-3376
Hauptverfasser:	Orlando, B., Hida, R., Cuchet, R., Audoin, M., Viala, B., Pellissier-Tanon, D., Gagnard, X., Ancey, P.
Format:	Artikel
Sprache:	eng
Schlagworte:	Bias Copper Cross-disciplinary physics: materials science rheology DC-DC power conversion Direct current Electronic packaging thermal management Energy management Exact sciences and technology Fabrication Impedance measurement Inductance Inductors Magnetic cores Magnetism Management Materials science Other topics in materials science Physics Power management Solenoids Technology management Thermal conductivity Thin film inductors Toroidal magnetic fields Winding
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container_title	IEEE transactions on magnetics
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creator	Orlando, B. Hida, R. Cuchet, R. Audoin, M. Viala, B. Pellissier-Tanon, D. Gagnard, X. Ancey, P.
description	5.6 mm times 5.6 mm integrated toroidal inductors with reduced thickness down to 200 mum have been realized. A high inductance-to-dc resistance ratio have been achieved using a toroidal geometry. The realization features thick Cu winding and a thick laminated Ni 80 Fe 20 core with crossed anisotropy. Impedance measurements have been performed up to 100 MHz with dc bias current applied. As a typical result, we show an inductor with an inductance of 500 nH up to 10 MHz and a dc resistance of 95 mOmega. To the best of our knowledge, this is the highest inductance-to-dc-resistance ratio demonstrated by a fully integrated inductor. This demonstrates the interest of such integrated inductors to replace discrete components in compact low-power modules
doi_str_mv	10.1109/TMAG.2006.879571
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A high inductance-to-dc resistance ratio have been achieved using a toroidal geometry. The realization features thick Cu winding and a thick laminated Ni 80 Fe 20 core with crossed anisotropy. Impedance measurements have been performed up to 100 MHz with dc bias current applied. As a typical result, we show an inductor with an inductance of 500 nH up to 10 MHz and a dc resistance of 95 mOmega. To the best of our knowledge, this is the highest inductance-to-dc-resistance ratio demonstrated by a fully integrated inductor. 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A high inductance-to-dc resistance ratio have been achieved using a toroidal geometry. The realization features thick Cu winding and a thick laminated Ni 80 Fe 20 core with crossed anisotropy. Impedance measurements have been performed up to 100 MHz with dc bias current applied. As a typical result, we show an inductor with an inductance of 500 nH up to 10 MHz and a dc resistance of 95 mOmega. To the best of our knowledge, this is the highest inductance-to-dc-resistance ratio demonstrated by a fully integrated inductor. 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A high inductance-to-dc resistance ratio have been achieved using a toroidal geometry. The realization features thick Cu winding and a thick laminated Ni 80 Fe 20 core with crossed anisotropy. Impedance measurements have been performed up to 100 MHz with dc bias current applied. As a typical result, we show an inductor with an inductance of 500 nH up to 10 MHz and a dc resistance of 95 mOmega. To the best of our knowledge, this is the highest inductance-to-dc-resistance ratio demonstrated by a fully integrated inductor. This demonstrates the interest of such integrated inductors to replace discrete components in compact low-power modules</abstract><cop>New York, NY</cop><pub>IEEE</pub><doi>10.1109/TMAG.2006.879571</doi><tpages>3</tpages></addata></record>
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subjects	Bias Copper Cross-disciplinary physics: materials science rheology DC-DC power conversion Direct current Electronic packaging thermal management Energy management Exact sciences and technology Fabrication Impedance measurement Inductance Inductors Magnetic cores Magnetism Management Materials science Other topics in materials science Physics Power management Solenoids Technology management Thermal conductivity Thin film inductors Toroidal magnetic fields Winding
title	Low-Resistance Integrated Toroidal Inductor for Power Management
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