SKYWORKS APN1001

APPLICATION NOTE
APN1001: Circuit Models for
Plastic Packaged Microwave Diodes
Abstract
This paper reports on the measurement and establishment of
circuit models for SOT-23 and SOD-323 packaged diodes.
Results indicate that the 1.5 nH estimate for the SOT-23 is a
useful result, as is 1.2 nH for SOD-323 single packaged diodes.
It was also determined that the effective inductance of the
SOT-23 may be reduced to approximately 0.4 nH by adding a
second bond wire and modifying the microstrip line. Other lead
configurations, including parallel bond wires and common
cathode configurations, were also studied.
SOT-23
SOD-323
Figure 1. Diode Package Styles
Package Modeling
Introduction
Network Analysis
Discrete, low-cost, surface mount semiconductor diodes are
attractive choices for UHF and microwave applications where
package parasitic may have a significant impact on performance.
The most common package styles are the SOT-23 and the
SOD-323 (Figure 1) which were neither designed nor intended
for RF service. A primary limitation to their high-frequency
performance, particularly in PIN diode shunt connected switches,
is parasitic package inductance, which limits high-frequency
isolation. The model information available from vendors of these
devices has been generally limited to estimates of inductance,
typically 1.5 nH, for single junction SOT-23 diodes. Establishing
a better model will enable circuit designers to better predict
performance and possibly give the manufacturer alternative
designs to reduce package parasitic effects.
To create a high-frequency device model S-parameter, measurements were taken over a wide frequency band so that resonance
and other high order effects would be included in the measurements. This procedure utilizes an HP 8510C vector network
analyzer. The package under test was inserted into an InterContinental Microwave test fixture as a series connected
element. This fixture uses a Thru-Reflect-Line calibration
procedure to produce accurate calibration and assures a
reference plane at the device under test.
L = 0.65 nH
C = 0.13 pF
L = 0.05 nH
C = 0.01 pF
Using this methodology, a circuit model was generated for each
of the devices as shown in Figures 2 and 3. These models produce very good correlation between the measured and simulated
performance as shown in Figure 4.
L = 0.7 nH
C = 0.015 pF
C = 0.13 pF
Figure 2. SOT-23 Circuit Model
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200311 Rev. A • Skyworks Proprietary Information • Products and Product Information are Subject to Change Without Notice. • July 21, 2005
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APPLICATION NOTE • APN1001: CIRCUIT MODELS FOR PLASTIC PACKAGED MICROWAVE DIODES
L = 0.57 nH
C = 0.2 pF
L = 0.05 nH
L = 0.57 nH
C = 0.02 pF
C = 0.02 pF
C = 0.2 pF
Figure 3. SOD-323 Circuit Model
0
0
Simulated
Return Loss
Isolation
Isolation
Loss (dB)
Loss (dB)
Measured
-20
Return Loss
Simulated
Center Conductor
-20
Measured
Ground
-40
-40
0.1
10.0
10.0
0.1
Frequency (GHz)
Frequency (GHz)
Figure 4. Measurement vs. Model Simulation
of a SOT-23 Package
Impedance Measurements
The HP 4291A Impedance Analyzer, an instrument based on measuring the vector V/I with coverage from 1 MHz–1.8 GHz, was
also utilized to characterize inductance of the packages under
consideration. Measurements were taken on a group of PIN
diodes that were forward biased to low values of forward resistance. The inductance values derived from these measurements
are shown in Table 1 and compare well with the values derived
from network analysis. The advantage of the direct impedance
measurement is the capability of a quick measurement without
the necessity of hard bonding the device to a substrate.
Validation of Simulated Model
Validation of the model was performed by placing the diode into a
test circuit that simulates a shunt connected switch. The test circuit was constructed using a Duriod microstrip board and the
device was placed as shown in Figure 5. This provided a different
operating environment because not only was the diode connected
differently, but the microstrip insulator had a different dielectric
constant.
Figure 5. SOT-23 Validation:
Simulation vs. Measurement
Alternative SOT-23 Designs for
Lower Inductance
To reduce the total inductance of the SOT-23 package, alternative
wire bonding schemes were studied. Figure 6 shows four
bonding wire designs considered in this study. The measured
inductance of these bonding schemes are shown on Table 1.
Single
Parallel Wires
Common Cathode
Dual Contact
Figure 6. SOT-23 Configurations
The measured performance of this circuit was imported into the
circuit simulator and compared to a simulation using the circuit
model. Figure 6 shows good validation of the network analyzer
generated model.
Skyworks Solutions, Inc. • Phone [781] 376-3000 • Fax [781] 376-3100 • [email protected] • www.skyworksinc.com
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July 21, 2005 • Skyworks Proprietary Information • Products and Product Information are Subject to Change Without Notice. • 200311 Rev. A
APPLICATION NOTE • APN1001: CIRCUIT MODELS FOR PLASTIC PACKAGED MICROWAVE DIODES
The single wire SOT-23 diode with 1.5 nH inductance will perform with 10.1 dB isolation at 900 MHz as a shunt connected
switch. The inductance is reduced to 1.2 nH if a parallel bond
wire is attached to the diode contact. This will increase the isolation to 11.6 dB. A further reduction of inductance may be
obtained by adding a second diode chip in a common cathode
configuration. This reduces the inductance to 0.84 nH resulting in
an increase in isolation to 14.6 dB.
transmission line as shown in Figure 7, then the effective inductance is reduced to below 0.4 nH and the isolation is increased to
20 dB at 900 MHz. Figure 7 shows a plot of the measured isolation of the dual bond wire package versus frequency to 4 GHz. A
plot of an inductance of 1.5 nH is shown as a reference.
Table 1 shows a summary of the effective package inductance
values for the SOD-323 and SOT-23 packaged diodes with alternative wiring configurations using the measurement techniques
described.
Since two junctions are employed, in the common cathode alternative, the capacitance is doubled under reverse bias. The
consequence may be an adverse effect on insertion loss. The
inductance of the dual bond wire design is similar to the common
cathode design resulting in similar performance. But, if the
package is inserted in the microstrip circuit with a gap in the
0
Output
Isolation
Input
Gap
1.5 nH
-10
w/o Gap (0.83 nH)
-20
w/Gap (0.32 nH)
-30
-40
Ground
-50
0
4
2
Frequency (GHz)
Figure 7. SOT-23 Dual Bond Wire With and Without a Gap
Package
Configuration
S-Parameter Model
(nH @ 1 GHz)
S-Parameter Validation
(nH @ 1 GHz)
HP 4291A Inductance
(nH)
SOT-23
Single junction
SOT-23
Dual no gap
1.45
1.5
1.5/1.7
1.2
0.9
SOT-23
Dual gap
SOT-23
Parallel bonds
0.5
0.4
SOT-23
Common cathode
SOT-323
Single junction
1.2
0.84
1.1
1.19
1.2
Table 1. Summary of Package Inductance Values
Skyworks Solutions, Inc. • Phone [781] 376-3000 • Fax [781] 376-3100 • [email protected] • www.skyworksinc.com
200311 Rev. A • Skyworks Proprietary Information • Products and Product Information are Subject to Change Without Notice. • July 21, 2005
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APPLICATION NOTE • APN1001: CIRCUIT MODELS FOR PLASTIC PACKAGED MICROWAVE DIODES
Conclusion
Reference
As a result of this effort, accurate and concise microwave models
are now available for commonly used, low-cost, surface mount,
SOT-23 and SOD-323 packaged diodes. The measurement
methodology utilized de-imbedding techniques valid at frequencies through 10 GHz. This material will assist design engineers
to design and predict circuit performance using these popular
devices.
R.W. Waugh and D. Gustedt, “Low Cost Surface Mount Power
Limiters,” Proceedings RF EXPO WEST,
March 1992, pp. 19-40.
© Skyworks Solutions, Inc., 1999. All rights reserved.
In addition, it was demonstrated that the inductance of the
SOT-23 may be significantly reduced by modifying both the
internal package wiring and the microstrip transmission line.
This further improves the frequency response of the package.
Skyworks Solutions, Inc. • Phone [781] 376-3000 • Fax [781] 376-3100 • [email protected] • www.skyworksinc.com
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July 21, 2005 • Skyworks Proprietary Information • Products and Product Information are Subject to Change Without Notice. • 200311 Rev. A
APPLICATION NOTE • APN1001: CIRCUIT MODELS FOR PLASTIC PACKAGED MICROWAVE DIODES
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Skyworks Solutions, Inc. • Phone [781] 376-3000 • Fax [781] 376-3100 • [email protected] • www.skyworksinc.com
200311 Rev. A • Skyworks Proprietary Information • Products and Product Information are Subject to Change Without Notice. • July 21, 2005
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