A NON-BIASED FERRITES FOR THE SUPPRESSION OF FROM …kkochary/WMH_spkr6.pdf• Ferrite Microwave...

APPLICATION OF NON-BIASED FERRITES FOR THE SUPPRESSION OF EMI

FROM RF TO MM WAVES

Karén Kocharyan

RENAISSANCE Electronics Corporation12 Lancaster County Rd., Harvard, MA 01451kkocharyan@rec-usa.com

IMS-2004 Workshop WMH

OVERVIEW

• Dispersion of Initial Magnetic Permeability• Ferrites for Wire Line EMI Filters• Ferrite Microwave Absorbers• MM-Wave Ferrites and Characterization• Conclusion

K. Kocharyan 2

COMMON AND DIFFERENTIAL MODES INWIRE LINES

K. Kocharyan 3

SUPPRESSING COMMON MODE NOISE WITH CHOKE COIL

§ Frequency Characteristics § Design Limitations

K. Kocharyan 4

SUPPRESSING DIFFERENTIAL MODE WITH BAND-REJECT FERRITE FILTER

Differential Mode Noise and Signal at Different Frequency Bands

)Z(Z)ZZ(Z

log20IL(dB)LS

FLS10 +

K. Kocharyan 5

DISPERSION OF INITIAL MAGNETIC PERMEABILITY

I – Domain Wall ResonanceII – Natural Magnetic Resonance

K. Kocharyan 6

µ ′

µ ′′

0.1 1 10 100 1000 f (kHz)

µ ′′

EQUIVALENT CIRCUIT OF INDUCTANCE INCORPORATING FERRITE CORE

XL(f) RS(f)

ZF = RS + XL

XL = ωL0µ′

RS = ωL0µ″

L0 ~ N2 − air core inductance

N − the number of turns

Ferrite EMI Filters operating at resistive mode do not introduce parasitic oscillations and signal distortions ! f

K. Kocharyan 7

MAGNETOCRYSTALLINE ANISOTROPY AND NATURAL MAGNETIC RESONANCE

ω0 = γHint

Hint = H0 + HA + Hi (M)H0 — external magnetic field

HA — effective field of magnetocrystalline anisotropy

Hi(M) — magnetization-dependent terms

at H0 = 0, M = 0 and Hi (M) = 0

Hint = HAωNR = γHA

ωNR — frequency of natural magnetic resonance

K. Kocharyan 8

EVALUATING ANISOTROPY FIELD IN ISOTROPIC FERRITES

HA*) = 2K1/MS

K1 – constant of cubic anisotropy

µ′ ≅ MS2/3K1

HA ≅ 2MS/3µ′

*) Soft ferrite manufacturers usually do not specify this parameter

K. Kocharyan 9

E.W.Gorter, Proc. IRE 43, 245, (1955)

SNOEK’S LIMIT ON RF PERMEABILITY OF ISOTROPIC FERRITES

• CUBIC SYMMETRY IMPLIES LOW MAGNETIC ANISOTROPY:

|K1| ≤ 103 J/m3

HA < 104 A/m ≅ 100 Oe

fNR = 500 MHz

• S = fµ′ = 2γMS/3 = 5 GHz

K. Kocharyan 10

HEXAGONAL FERRITES WITH UNIAXIAL MAGNETIC ANISOTROPY

K1 – constant of axial anisotropyK2 – constant of in-plane anisotropy

K1 >> K2

K1 > 0 K1 < 0easy axis easy plane

K.Kocharyan 11

HA1 ~ 10,000 OeHA2 ~ 100 Oe

fNR = γ√(HA1× HA2) / 2π ~ 1GHz

S = γMS sin2θ0 (HA1/HA2)1/2 ~ 15 GHz

Jonker, Wijn and Brawn, Phillips, Tech. Rev., 18, 150 (1956-57)

SNOEK’S LIMIT ON PERMEABILITY OF EASY-PLANE HEXAFERRITES

K. Kocharyan 12

HEXAGONAL FERRITES WITH EASY-AXIS ANISOTROPY

TYPICAL CHARACTERISTICS

HA1 = 2000 - 20,000 OefNR = γHA1/ 2π ~ 6 - 60 GHz

µ ′, µ ″ ~ 0.5 - 3 ε ′ ~ 18 - 20

σ ~ 0.01 - 10 (MOhm m)-1

ε ″ ~ 0.02 - 10

K. Kocharyan 13

MICROWAVE FERRITE ABSORBERS FOR WIRELESS APPLICATIONS

• Broader Bandwidthµ is strongly dispersive

• Thinner Absorberk ~ (µ′ε″ + ε′µ″ ) / (µ′ε′)1/2

Available Forms

§ Ferrite Tiles § Ferrite Composites § Ferrite Paints

K. Kocharyan 14

METAL-TERMINATED FERRITE ABSORBER

§ Computational Methods

§ Matching Solution Map(Cole-Cole magnetic diagram)

10 20 00 .ZZZZdBRL *in

*in ≤+−⇒−<

**in eµ

eµZ 2tanh

K. Kocharyan 15

BROADBAND FERRITE ABSORBER DESIGN PARAMETERS

INPUT PARAMETERS

§ Dispersion of Complex Magnetic Permeability§ Complex Dielectric Permittivity§ Required Suppression Level

OUTPUT PARAMETERRange for product - (fd)

K. Kocharyan 16

MM-WAVE MATERIAL CHARACTERIZATION METHODS

§ Waveguide- rectangular/cylindrical sample- deteriorating effect of the air gap- standard equipment

§ Coaxial Line- complicated sample geometry- moderate accuracy- standard equipment

§ Quasi-Optical- simple sample geometry- high accuracy- custom designed spectrometer

K. Kocharyan 17

BLOCK DIAGRAM OF QUASI-OPTICAL MM-WAVE BWO-SPECTROMETER*)

*)At TUFTS University, Medford, MA

K. Kocharyan 18

TECHNICAL CHARACTERISTICS OF BWO-SPECTROMETER

§ RADIATION SOURCE - Backward Wave Tubes§ RADIATION TYPE - Coherent, Tunable§ POLARIZATION - Linear/Circular§ DETECTORS - Diodes/Bolometer§ SCAN RANGE (GHz) - 35 - 56; 44 - 76; 70 - 120§ SCAN STEP - ≥ 3 MHz§ SCAN TIME (1000 point) - 1 min.§ DYNAMIC RANGE - > 40 dB§ MAGNETIC FIELD - up to 15 kOe

K. Kocharyan 19

EQUATIONS

( )[ ]( ) ( )r

AERERRRE

ϕϕ++−

+−==2

sin41sin41

( ) ( )[ ]( ) ( )r

AERERAEER

++−++−==

sin41sin41

( )ckdfE π4exp −=

( )( ) 22

+++−=

22 bab

atanrϕ

εµ=≡+ Zjba

cndfA π2=

**εµ=− jkn

K. Kocharyan 20

APPROXIMATIONS

§ Dielectric Permittivity, ε* = ε′ - jε″ :

§ Magnetic Permeability, µ* = µ′ - jµ″ :

oriented ceramic:

randomly oriented:

Simulation Parameter Set

constσ

0 +′′≡′′

( )[ ] ( )

2222 fffffj ACMAC −−+=′′−′ µµ

( )[ ] ( )2222

31 fffffj ACMAC −−++=′′−′ µµ

πγπγα 2 ,2 , SMANRGNRAC MfHffjff ==+=

fNR, αG, fM , ε′, ε0″, σ

K. Kocharyan 21

EXAMPLE 1: LOW-LOSS CERAMIC

Frequency, GHz30 45 60 75 90 105 120

0.9ExperimentTheory

Frequency, GHz40 60 80 100 120

ExperimentTheory

MM-Wave transmission a) and reflection b) spectra of M-(easy-axis) type oriented Ba-hexaferrite ceramic. Wave propagation is along the direction of orientation. Sample thickness is 12.67 mm.

K. Kocharyan 22

EXAMPLE 1: BEST-FIT PARAMETERS

Frequency, GHz30 45 60 75 90 105 120

µ'' ×

0.0918.80.0012< 0.0547.610.6

ε0″ε′αGσ (MOhm m)-1fNR (GHz)fM (GHz)

K. Kocharyan 23

EXAMPLE 2: LOSSY CERAMIC

Frequency, GHz30 45 60 75 90 105 120

0.0000

0.0005

0.0010

0.0015

0.0020

0.0025

0.0030

0.0035

Experiment Theory

Frequency, GHz30 45 60 75 90 105 120

0.9ExperimentTheory

MM-Wave transmission a) and reflection b) spectra of lossy M-(easy-axis) type oriented Ba-hexaferrite ceramic. Wave propagation is along the direction of orientation. Sample thickness is 9.67 mm.

0.7819.70.0011451.211.5

ε0″ε′αGσ (MOhm m)-1fNR (GHz)fM (GHz)

K. Kocharyan 24

CONCLUSION

§ In Wire Line EMI Applications the Anisotropy Field of Ferrite Core Should Match to the Noise Spectrum

§ Hexagonal Ferrites with Uniaxial Anisotropy are Suitable for Application at Short Microwaves

§ Quasi-Optical BWO Spectroscopy Allows Complete MM-Wave Characterization of Ferrite Materials

K. Kocharyan 25

A NON-BIASED FERRITES FOR THE SUPPRESSION OF FROM …kkochary/WMH_spkr6.pdf• Ferrite Microwave...

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