IPC-TM-650 EN 2022 试验方法.pdf - 第502页

from metric units will lead to inherent accuracy and/or preci- sion errors. 10 References [ 1 ] Fundamental Physical Constant, Permittivity, http:// physics.nist.gov/cgi-bin/cuu/V alue?ep0|search_for=permittivity [2] M. …

For

each frequency repeat the following procedure:

1. Compute the complex permittivity using Equations (2b) and

(2c). This is an initial trial solution of the iterative process for

k=0, where k is the iterative step:

[

k = 0

]

=ε’ −

’’

(7b)

Compute successive approximations for subsequent itera-

tive steps k.

[

k + 1

]

=ϕ(

[

]

)

(7c)

(k = 0,

1, 2, 3...)

3. The iteration procedure is terminated when the absolute

value of Equation (7d) is sufficiently small, for example

smaller than 10

-5

[

]

−ε

[

k − 1

]

[

]

<10

−5

(7d)

Typically

it may require five to about twenty iterations to reach

the terminating criterion.

Commercially available software can be used to program and

automate the computational steps 1 through 3 and solve

Equation (7) numerically for ε

and the corresponding uncer-

tainty values. The software should be capable of handling

simultaneously both real and imaginary parts of complex S

cot (x) and ε

*, (for

example Visual Basic, C or Agilent VEE

and National Instruments LabView programming platforms

can be employed).

Report

The

report shall include:

• Dimensions of the specimen.

• Plot of magnitude and phase of the measured impedance

as a function of frequency, (similar to Figure 3) or Smith

Chart.

• Plot of ε’ and ε’’ or ε’ and tan δ as a function of frequency.

Notes

9.1 Measurements at Frequency Range Above 12 GHz

The

presented APC-7 test fixture design may be utilized in the

frequency range of 100 kHz to 18 GHz. The computational

algorithm and in particular Equations (4) and (5) have been

validated up to the first cavity resonance frequency, ƒ

cav

which

is determined by the propagation length l, and the

dielectric constant of the specimen:

cav

l Re (

√

)

≈ 121/(

√

[

GHz

]

(8)

where

Re indicates the real part of complex square root of

permittivity and l = 2.47 mm, which is the propagation length

for the test fixture presented in Figure 1, [5]. For example, in

the case of a specimen having the dielectric constant of 100

cav

about 12 GHz.

9.2

Accuracy Considerations

Several uncertainty factors

such as instrumentation, dimensional uncertainty of the test

specimen geometry, roughness and conductivity of the con-

duction surfaces contribute to the combined uncertainty of the

measurements. The complexity of modeling these factors is

considerably higher within the frequency range of the LC reso-

nance. Adequate analysis can be performed, however, by

using the partial derivative technique [1] for Equations (2b) and

(2c) and considering the instrumentation and the dimensional

errors. The standard uncertainty of S

can

be assumed to be

within the manufacturer’s specification for the network ana-

lyzer, about ± 0.005 dB for the magnitude and ± 0.5° for the

phase. The combined relative standard uncertainty in geo-

metrical capacitance measurements is typically better than

5%, where the largest contributing factor is the uncertainty in

the film thickness measurements.

Equation (5) for the residual inductance has been validated for

specimens 8 µm to 300 µm thick. However, since residual

inductance becomes smaller with thinner dielectrics, mea-

surements can be accurately made for sample thicknesses

down to 1 µm.

Measurements in the frequency range of 100 MHz to 12 GHz

are reproducible with relative combined uncertainty in ε’ and

ε’’ of better than 8% for specimens having ε’ <80 and thick-

ness d <300 µm. The resolution in the dielectric loss tangent

measurements is <0.005.

Additional limitations may arise from the systematic uncer-

tainty of the particular instrumentation, calibration standards

and the dimensional imperfections of the actually imple-

mented test fixture. Results may be not reliable at frequencies

where

decreases

below 0.05 Ω, which in Figure 3 is

shown as a frequency range of 11.9 GHz to 13.5 GHz.

9.3

Test Software

Test

software enabling this technique to

be performed is available in the Agilent VEE platform. Please

contact Dr. Jan Obrzut at NIST-Gaithersburg, MD

(jan.obrzut@nist.gov) to obtain such.

9.4

Metric Units of Measure

This

test method uses only

metric units of measure, as is the case with nearly all such

high frequency test methods. Conversion to English/Imperial

units has not been done in this document, as any conversions

IPC-TM-650

Number

2.5.5.10

Subject

High

Frequency Testing to Determine Permittivity and Loss

Tangent of Embedded Passive Materials

Date

07/05

Revision

age5of8

电子技术应用　　　　　　　ｗｗｗ．ＣｈｉｎａＡＥＴ．ｃｏｍ

from

metric units will lead to inherent accuracy and/or preci-

sion errors.

References

[

1] Fundamental Physical Constant, Permittivity,

http://

physics.nist.gov/cgi-bin/cuu/V

alue?ep0|search_for=permittivity

[2] M. A. Stuchly, S. S. Stuchly, ‘‘Coaxial line reflection meth-

ods for measuring dielectric properties of biological sub-

stances at radio and microwave frequencies: A review,’’

IEEE Trans. Instrum. Meas., vol. 29, pp. 176-183, 1980.

[3] N. Marcuvitz, Waveguide Handbook. McGraw-Hill, New

York: 1951.

[4] H. J. Eom, Y.C. Noh, J.K. Park, ‘‘Scattering analysis of a

coaxial line terminated by a gap,’’ IEEE Microwave Guided

Wave Lett., vol. 8, pp. 218-219, 1998.

[5] N.-E. Belhadj-Tahar, O. Dubrunfaut, A. Fourrier-Lamer,

‘‘Equivalent circuit for coaxial discontinuities filled with

dielectric materials - frequency extension of the Marcu-

vitz’s circuit’’ J. Electromagnet. Wave, vol. 15, pp. 727-

743, 2001.

[6] J. Obrzut, A. Anopchenko, ‘‘Input Impedance of a Coaxial

Line Terminated with a Complex Gap Capacitance -

Numerical and Experimental Analysis’’ IEEE Trans.

Instrum. Meas., vol. 53(4), Aug. (2004).

[7] ‘‘Mathematical Handbook for Scientists and Engineers,’’

G. A. Korn and T. M. Korn, McGraw-Hill, 2

edition

(1968),

page 719.

Test Fixture Drawings

IPC-25510-4

1 Center conductor pin

= 3.05 mm

2 Supporting dielectric in the APC-7 section

3 Center conductor in the APC-7 to APC-3.5

4 Supporting dielectric in the APC-3.5 section

5 APC-3.5 section of the adaptor

6 Section A outer conductor (

=7.00 mm)

7 Section B outer conductor (

=7.00 mm)

8 APC-7 mount

Section B

Section A

Section A details

Test Fixture for HF Permittivity of Embedded Passive Materials

Originator: IPC Embedded Passives Test Methods

50 Ω

Calibration Plane

METRIC, dimensions are in mm

APC-3.5 female mount

IPC-TM-650

Number

2.5.5.10

Subject

High

Frequency Testing to Determine Permittivity and Loss

Tangent of Embedded Passive Materials

Date

07/05

Revision

age6of8

电子技术应用　　　　　　　ｗｗｗ．ＣｈｉｎａＡＥＴ．ｃｏｍ

APPENDIX

Example

of the specimen preparation

Figure

A1 shows an example of three test specimens pre-

pared from a free standing dielectric film. The dielectric was

25 µm thick. About 242 nm thick layer of gold was sputtered

on both sides. A shadow mask with a pattern of circles hav-

ing each diameter of 2.9 mm was used to pattern the top sur-

face. The bottom surface was sputtered without masking. The

specimens were extracted from the film using a 3.0 mm

puncher.

Instrumentation

Example

Figure

A2 shows a photo of the assembled test fixture during

measurements. An APC-7 to APC-3.5 microwave adapter

(Agilent 1250-1746) is connected via a phase preserving

coaxial cable (Agilent 85131-60013) to a network analyzer. An

APC-7 short termination (Agilent 04191-85300), is attached

on top of the APC-7 to APC-3.5 adapter. The termination has

a custom machined gap to accommodate a specimen of a

particular thickness.

Figure

A1 Test specimens

Figure

A2 Test instrumentation

IPC-TM-650

Number

2.5.5.10

Subject

High

Frequency Testing to Determine Permittivity and Loss

Tangent of Embedded Passive Materials

Date

07/05

Revision

age7of8

电子技术应用　　　　　　　ｗｗｗ．ＣｈｉｎａＡＥＴ．ｃｏｍ