Noise suppression and crosstalk analysis of on-chip magnetic film-type noise suppressor

This paper discusses near field, conduction and crosstalk noise suppression of magnetic films with uniaxial anisotropy on transmission lines for a film-type noise suppressor in the GHz frequency range. The electromagnetic noise suppressions of magnetic films with different permeability and resistivi...

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Veröffentlicht in:	AIP advances 2018-05, Vol.8 (5), p.056613-056613-6
Hauptverfasser:	Ma, Jingyan, Muroga, Sho, Endo, Yasushi, Hashi, Shuichiro, Naoe, Masayuki, Yokoyama, Hiroo, Hayashi, Yoshiaki, Ishiyama, Kazushi
Format:	Artikel
Sprache:	eng
Schlagworte:	Anisotropy Crosstalk Electrical resistivity Electromagnetic noise Integrated circuits Magnetic films Magnetic permeability Magnetic shielding Microstrip transmission lines Noise Noise reduction Permeability Transmission lines Zirconium
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container_title	AIP advances
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creator	Ma, Jingyan Muroga, Sho Endo, Yasushi Hashi, Shuichiro Naoe, Masayuki Yokoyama, Hiroo Hayashi, Yoshiaki Ishiyama, Kazushi
description	This paper discusses near field, conduction and crosstalk noise suppression of magnetic films with uniaxial anisotropy on transmission lines for a film-type noise suppressor in the GHz frequency range. The electromagnetic noise suppressions of magnetic films with different permeability and resistivity were measured and simulated with simple microstrip lines. The experimental and simulated results of Co-Zr-Nb and CoPd-CaF2 films agreed with each other. The results indicate that the higher permeability leads to a better near field shielding, and in the frequency range of 2–7 GHz, a higher conduction noise suppression. It also suggests that the higher resistivity results in a better crosstalk suppression in the frequency range below 2 GHz. These results can support the design guidelines of the magnetic film-type noise suppressor used in the next generation IC chip.
doi_str_mv	10.1063/1.5007315
format	Article
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The electromagnetic noise suppressions of magnetic films with different permeability and resistivity were measured and simulated with simple microstrip lines. The experimental and simulated results of Co-Zr-Nb and CoPd-CaF2 films agreed with each other. The results indicate that the higher permeability leads to a better near field shielding, and in the frequency range of 2–7 GHz, a higher conduction noise suppression. It also suggests that the higher resistivity results in a better crosstalk suppression in the frequency range below 2 GHz. 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subjects	Anisotropy Crosstalk Electrical resistivity Electromagnetic noise Integrated circuits Magnetic films Magnetic permeability Magnetic shielding Microstrip transmission lines Noise Noise reduction Permeability Transmission lines Zirconium
title	Noise suppression and crosstalk analysis of on-chip magnetic film-type noise suppressor
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