AN178 - ESD Protection for RF Antennas using Infineon ESD112-B1-02ELS and ESD112-B1-02EL

Application Note, Rev. 1.1, May 2014
Application Note No. 178
ESD Protection for RF Antennas using Infineon
ESD112-B1-02ELS and ESD112-B1-02EL
RF and Protection Devices
Edition 2014-05-27
Published by
Infineon Technologies AG
81726 München, Germany
© Infineon Technologies AG 2014.
All Rights Reserved.
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Application Note No. 178
Application Note No. 178
Revision History: 2014-05-27, Rev. 1.1
Previous Version: 2008-12-05, Rev. 1.0
Page
Subjects (major changes since last revision)
All
Update to new sales codes
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Application Note No. 178
Introduction
1
Introduction
This application note deals with the applicability of
Infineon’s low capacitance (≤ 0.4 pF) ESD protection
diodes for RF antenna protection. The first one,
ESD0P4RFL—an
anti-parallel
ESD
protection
diode—exhibits a noise figure as low as 0.1 dB at 3 GHz
and is suitable for use as ESD protection before the
LNA (low noise amplifier). The second one, ESD112B1—a bidirectional ESD protection diode—exhibits a
capacitance as low as 0.2 pF and can handle voltages
of up to ±5.3 V, which makes it suitable to protect RF
interfaces for active antennas as well. ESD0P4RFL
comes in the TSLP-4-7 (thin small leadless package)
with dimensions of 1.2 mm x 0.8 mm x 0.39 mm (EIA
case size 0503) and ESD112-B1 is available in
TSSLP-2-4 (thin super small leadless package) with
dimensions of 0.62 mm x 0.32 mm x 0.31 mm (EIA case
size 0201) as well as in TSLP-2-20 with dimensions of
1.0 mm x 0.6 mm x 0.39 mm (EIA case size 0402).
Figure 1
Infineon’s Thin Super Small Leadless
Package TSSLP-2-4
ESD0P4RFL
The anti-parallel ESD protection diode ESD0P4RFL was designed to protect RF receiver interfaces from ESD
events. With a typical capacitance of 0.4 pF at a frequency of 1 GHz it features both lowest noise figure and lowest
clamping voltage.
ESD112-B1-02ELS / -02EL
The bidirectional ESD protection diode ESD112-B1 is very much suitable for ultra wide band applications or active
RF antennas operating at voltages of up to ± 5.3 V at leakage currents of less than 10 nA. With a typical capacitance
of 0.2 pF at 1 GHz it features lowest insertion loss and low clamping voltage.
2
Overview
S-parameters of packaged diodes were measured with wafer probes in order to avoid the error-prone procedure
of de-embedding S-parameters from a printed circuit board (PCB). However, for evaluation purposes a FR-4 eval
board is provided by Infineon (see Figure 2). Please note that the S-parameters provided by Infineon do not
include any PCB and SMA connector losses.
First of all some ESD protection concepts for RF antennas and their differences are discussed. Next, the
capacitance of Infineon’s ESD protection diodes versus frequency and voltage is shown. This is followed by a
discussion of basic RF parameters: insertion loss, return loss, noise figure and bandwidth. Since silicon diodes
are nonlinear devices, harmonic generation is considered as well. The reason why the analog bandwidth of the
scope is crucial for clamping voltage measurements is pointed out and clamping voltage, peak voltage and
response time of Infineon’s ESD protection diodes are presented. But most important, an application example,
layout guidelines and guidelines on how ESD hardness can be further enhanced are shown as well. Finally, other
solutions available on the market are discussed briefly.
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Application Note No. 178
ESD Protection Concepts
Figure 2
Photo of Infineon eval board for T(S)SLP (here with an ESD0P4RFL in TSLP-4-7)
3
ESD Protection Concepts
In order to use silicon diodes for RF interfaces in the gigahertz range, one important key feature has to be the low
parasitic capacitance of the diode. PIN diodes with its lightly doped intrinsic semiconductor region between the ptype and n-type region make capacitances of only a few tenths of a picofarad possible. However, the charge carrier
life time of general purpose PIN diodes is in the microsecond range and therefore these diodes are far too slow
for ESD events, for which carrier life times in the region of 1 nanosecond are a must-have. To overcome this
behavior of general purpose PIN diodes, Infineon developed fast switching, low-capacitive diodes suitable for ESD
protection. Unlike Zener diodes, these low-cap diodes must not be operated beyond their breakdown voltage and
even an ESD event in reverse biased condition permanently damages the diode. Thus, for ESD protection always
a pair of low-cap diodes is required, each one for either polarity of an ESD event, so that the current arising from
the ESD event is always conducted in forward direction by either diode. Figure 3 shows three different
configurations, each with a pair (or two pairs) of fast switching, low-capacitive diodes. In the anti-parallel
configuration either diode operates in forward biased condition, and thus the voltage on the signal line must be
approximately between -0.3 V and +0.3 V. This is equivalent to 0 dBm at an impedance of 50 Ω. Infineon’s
ESD0P4RFL with a line capacitance of 0.4 pF (this is the total parasitic capacitance) integrates two low-cap diodes
in anti-parallel configuration into one package. For all measurements presented herein ESD0P4RFL was
configured in the anti-parallel way.
There are two possibilities to overcome this limitation on the voltage. The first one is to use an additional Zenerlike diode as shown in Figure 3 (b). Since the Zener-like diode is in series with the low-cap diodes, the much
higher capacitance of the Zener-like diode does not count to the line capacitance. By using two pairs of low-cap
diodes in series, the line capacitance of the ESD protection diode is only half the capacitance of an anti-parallel
configuration. Such a bidirectional ESD protection diode can handle voltages between -VRWM and +VRWM (VRWM is
the maximum reverse working voltage) on the signal line. Infineon’s ESD protection diode ESD112-B1 with a line
capacitance of 0.2 pF and a reverse working voltage of 5.3 V max integrates this configuration into an incredible
small package (EIA 0201 case size).
The third option shown in Figure 3 (c) is the rail-to-rail configuration where the low-cap diodes are not connected
to ground like for the anti-parallel configuration but to VEE and VCC instead (but often VEE is equivalent to ground).
Such a configuration can handle any voltage between VEE - 0.3 V and VCC + 0.3 V on the signal line. However, the
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Application Note No. 178
Capacitance
current arising from ESD events must be conducted to chassis ground and thus either big-sized capacitors or
unidirectional ESD protection diodes are needed for the VEE and VCC rail, which are not shown here. (Of course,
in case the VEE rail is equivalent to ground, this is only needed for the VCC rail.) Infineon’s ESD0P4RFL can also
be used in rail-to-rail configuration as shown in Figure 3.
VCC
-0.3 V...0 .3 V
-VRWM ...V RWM
VEE...VCC
VEE
(a) anti-parallel
(b) low cap bidirectional
(c) rail-to-rail
XXX
TVS_diodes _concepts.vsd
Figure 3
Three different concepts for ESD protection diodes: (a) two low-cap diodes in anti-parallel
configuration, (b) combination of four low-cap diodes and one Zener-like diode to a
bidirectional configuration and (c) two low-cap diodes in rail-to-rail configuration
4
Capacitance
The capacitance of silicon diodes is generally voltage- and frequency-dependent. Figure 5 shows the apparent
capacitance of ESD0P4RFL in anti-parallel configuration and of ESD112-B1 for a working voltage VR = 0 V. The
apparent capacitance shown in Figure 5 and Figure 6 is the capacitance of an equivalent, frequency dependent
parallel RC circuit as shown in Figure 4. Usually, capacitance reduces with frequency and working voltage, but at
higher frequencies the inductance of the bond wire—0.2 nH for ESD0P4RFL and ESD112-B1-02ELS and 0.4 nH
for ESD112-B1-02EL—apparently increases the capacitance of the diode. Figure 6 shows the apparent
capacitance of ESD112-B1-02ELS versus working voltage between 0 V and 5 V. Since the junction capacitance is
only about half the total line capacitance, the apparent capacitance shows only little dependence on the working
voltage, typically only about 3% change in capacitance up to 5 V. This is also true for ESD0P4RFL in rail-to-rail
configuration, but unlike ESD112-B1, it offers a maximum reverse working voltage as high as 50 V. See Figure 7
for a plot of the apparent capacitance of ESD0P4RFL in rail-to-rail configuration with the reverse working voltage
applied to either diode.
R
C
Equivalent_ parallel _RC_ circuit.vsd
Figure 4
Equivalent parallel RC circuit
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Capacitance
Apparent Capacitance
0.5
Capacitance (pF)
0.4
ESD0P4RFL (pF)
ESD112-B1-02ELS (pF) Capacitance .vsd
0.3
ESD112-B1-02EL(pF)
0.2
0.1
0
Figure 5
2
4
6
Frequency (GHz)
8
10
Apparent parallel capacitance of ESD0P4RFL and ESD112-B1
Apparent Capacitance vs. Voltage
0.24
0.23
Capacitance (pF)
1 GHz
0.22
0.21
2 GHz
0.2
3 GHz
4 GHz
0.19
6 GHz
0.18
0
1
2
3
4
5
Voltage (V)
Figure 6
Apparent parallel capacitance of ESD112-B1-02ELS vs. working voltage
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Insertion Loss and Return Loss
Apparent Capacitance vs. Reverse Voltage
0.4
0.8 GHz
1.6 GHz
Capacitance (pF)
0.39
3.2 GHz
0.38
0.37
0.36
0.35
0
5
10
Reverse Voltage (V)
15
20
Figure 7
Apparent parallel capacitance of ESD0P4RFL in rail-to-rail configuration vs. reverse working
voltage
5
Insertion Loss and Return Loss
Insertion loss, IL, and return loss, RL, are two key characteristics for RF applications that are mainly determined
by the capacitance of the ESD protection diode and are calculated from the S-parameters as follows:
IL = – 20 log S 21
(1)
RL = – 20 log S 11 ,
(2)
and
whereas IL and RL are expressed in decibel (dB). Figure 8 and Figure 9 show insertion loss and return loss
respectively of ESD0P4RFL in anti-parallel configuration and of ESD0P2RF for a reverse working voltage of
VR = 0 V. Up to 3 GHz insertion loss does not show a significant difference between these ESD protection diodes.
Due to the higher bond wire inductance of the bigger package, insertion loss of ESD112-B1-02EL is greater than
that of ESD112-B1-02ELS.
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Insertion Loss and Return Loss
Insertion Loss
2
ESD0P4RFL
1
Insertion Loss (dB)
ESD112-B1-02ELS
ESD112-B1-02EL
.1
Insertion _Loss.vsd
.01
0.3
1
10
Frequency (GHz)
Figure 8
Insertion loss of ESD0P4RFL and ESD112-B1
Return Loss
40
ESD0P4RFL
ESD112-B1-02ELS
ESD0P2RF-02LS
Return Loss (dB)
30
ESD112-B1-02EL
ESD0P2RF-02LRH
20
10
0
0.3
1
10
Frequency (GHz)
Figure 9
Return loss of ESD0P4RFL and ESD112-B1
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Noise Figure
6
Noise Figure
Noise figure, NF, expressed in dB, of a passive, lossy two-port circuit at room temperature (T ≅ 290 K) is given as
NF
dB
≅ –GA
dB
= IL
dB
– ML
dB
,
(3)
where GA is the available gain of the passive two-port circuit, IL is the insertion loss and ML is the mismatch loss,
all expressed in dB. Since the uncertainty of the Y-factor method which is used by noise figure analyzers to
measure noise figures increases to infinity at zero noise figure and zero gain, a noise figure analyzer can not be
used to measure noise figures of low-loss passive circuits. However, according to Equation (3) the noise figure
of a passive circuit can be calculated from the S-parameters measured at room temperature. For more details on
this please see “Appendix” on Page 25.
Noise Figure
1
ESD0P4RFL
Noise Figure (dB)
ESD0P2RF-02LS
ESD 112-B1-02ELS
ESD0P2RF-02LRH
ESD 112-B1-02EL
.1
.01
0.3
1
10
Frequency (GHz)
Figure 10
Noise figure of ESD0P4RFL and ESD112-B1
7
Bandwidth
Figure 11 shows a wide-span plot of the transmission coefficient S21, from which the 3 dB bandwidth can be read
off. With a 3 dB bandwidth of approximately 18 GHz, ESD112-B1-02ELS is very much suitable, for example, for
ESD protection of ultra-wide band applications. ESD112-B1-02EL has twice the bond wire inductance (due to the
bigger package) and ESD0P4RFL has twice the capacitance of ESD112-B1-02ELS, and thus the 3 dB bandwidth
of both ESD0P4RFL and ESD112-B1-02EL is approximately 12 GHz.
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Harmonic Generation
Transmission Coefficient
0
|S21|² (dB)
-2
12.2 GHz
-3 dB
-4
17.8 GHz
-3 dB
-6
ESD0P4RFL
ESD0P2RF-02LS
ESD112-B1-02ELS
-8
ESD0P2RF-02LRH
ESD112-B1-02EL
-10
0
5
10
Frequency (GHz)
Figure 11
3 dB bandwidth of ESD0P4RFL and ESD112-B1
8
Harmonic Generation
15
20
The frequency of the fundamental tone for the measurement of the 2nd and 3rd harmonic was 900 MHz and the
power level was swept from -10 dBm to 19 dBm (see Figure 12 for test setup). Thus, the 2nd harmonic was
measured at 1.8 GHz and the 3rd harmonic was measured at 2.7 GHz. In the small signal region, that is for power
levels less than 0 dBm, the intercept point characterizes the nonlinear behavior of the diode. The 2nd order intercept
point, IP2, and the 3rd order intercept point, IP3, are given by
IP 2 = P H1 + ( P H1 – P H2 ) and
(4)
P H1 – P H3
IP 3 = P H1 + ------------------------- ,
2
(5)
where PH1 is the power level of the fundamental tone, and PH2 and PH3 are the power levels of the 2nd and 3rd
harmonics respectively. All power levels are in dBm. See Table 1 for the small signal IP2 and IP3 values.
Please note that these values are only valid in a wide-band 50 Ω environment, which is usually not the case for
real-world applications. In order to minimize intermodulation products from strong interfering out-of-band signals,
the out-of-band impedance seen by the interfering signal at the ESD protection diode should be low. By this
means, the voltage drop across the diode is also low and thus the junction capacitance of the diode is less
modulated by the interfering signal. In the case of strong interfering signals there is often a filter following the ESD
protection diode. The intermodulation products generated by the ESD protection diode are then affected by tuning
the out-of-band impedance of this filter. If the out-of-band impedance of the filter itself cannot be adjusted, the
same effect is achieved, at least for interfering signals at high frequencies, by tuning the length of the transmission
line between antenna, ESD protection diode and filter. In principle, also the out-of-band impedance of the antenna
rather than the filter can be tuned. For example, a loop antenna can be designed such that it provides a short at
the E-field maxima of the interfering signal.
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Harmonic Generation
Table 1
Harmonic generation in the small signal region
TA = 25 °C, fH1 = 900 MHz, PH1 = -10 dBm, ZS = ZL = 50 Ω
Parameter
Symbol
Values
Min.
Typ.
Unit
Note / Test Condition
fH2 = 1.8 GHz
fH3 = 2.7 GHz
Max.
ESD0P4RFL
2nd order intercept point
rd
3 order intercept point
IP2
IP3
100
dBm
34
dBm
IP2
IP3
100
dBm
40
dBm
ESD112-B1
2nd order intercept point
rd
3 order intercept point
Signal
Generator
900 MHz
1 GHz
6 dB
DUT
DC Block
6 dB
fH2 = 1.8 GHz
fH3 = 2.7 GHz
Spectrum
Analyzer
1.5 GHz
Test_setup_harmonics.vsd
Figure 12
Test setup for harmonics measurements
Harmonics are generated due to nonlinearities. In the case of a silicon diode, there is a nonlinear dependence of
junction capacitance (leakage current) on voltage. In general, harmonics of even order (2nd, 4th, …) can be
suppressed by a balanced configuration of two diodes [1]. As shown in Figure 13, the DC voltage drop over either
diode must be exactly the same in a balanced configuration. When there is no DC voltage on the signal line, both
ESD0P4RFL and ESD112-B1 are balanced configurations and thus the 2nd harmonic is greatly reduced compared
to any unbalanced configuration such as an unidirectional ESD protection diode. For this reason, unidirectional
ESD protection diodes are not recommended for RF applications where the 2nd harmonic is critical.
2.4V
+3V
1.2V
0V
3V
1.2V
0V
0V
3V
1.2V
-3V
(a)
(b)
X
Figure 13
(c)
Balanced _configurations.vsd
Examples of balanced configurations of two diodes: (a) anti-parallel configuration, (b) rail-torail configuration with superimposed DC voltage on signal line and (c) rail-to-rail
configuration with negative bias voltage
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Harmonic Generation
Second and Third Harmonic of ESD0P4RFL
-10
2nd Harmonic @ 1.8 GHz
-30
3rd Harmonic @ 2.7 GHz
Power (dBm)
-50
-70
-90
-110
-130
-10
Figure 14
-5
0
5
Power of Fundamental (dBm)
10
Harmonics generated by ESD0P4RFL from a fundamental tone at 900 MHz in a 50 Ω
environment
Second and Third Harmonic of ESD 112-B1
-40
2nd Harmonic @ 1.8 GHz
3rd Harmonic @ 2.7 GHz
Power (dBm)
-60
-80
Harmonics_ESD0P2RF.vsd
-100
-120
-10
Figure 15
0
10
Power of Fundamental (dBm)
19
Harmonics generated by ESD112-B1 in steady-state from a fundamental tone at 900 MHz in a
50 Ω environment
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Clamping Voltage
Clipping and Self-Biasing
At high RF power levels of more than 0 dBm there is a fundamental difference between the anti-parallel
ESD0P4RFL and the bidirectional ESD112-B1 (see Figure 14 and Figure 15). While ESD0P4RFL in anti-parallel
configuration starts to clip the RF signal and thus becomes even more nonlinear, ESD112-B1 starts to self-bias
and becomes less nonlinear. This is because a reverse biased diode, that is when a positive reverse working
voltage is applied, is more linear than an unbiased diode (VR = 0 V). The examples shown in Figure 13 are ordered
by their nonlinear behavior with Figure 13 (a) showing an unbiased diode (VR = 0 V) with lowest linearity and
Figure 13 (c) showing a reverse biased diode with higher linearity (VR = 3 V). The self-biasing of ESD112-B1 is
therefore an advantage when strong RF interferers are expected. Figure 16 shows how self-biasing works. The
nodes in the middle are gradually charged by the strong interfering signal, which improves the linearity of the
bidirectional ESD protection diode significantly. The charging process takes several milliseconds, which makes it
appropriate for permanent interfering signals such as TV signals or FM radio signals that are not expected to
change their signal strength rapidly within microseconds.
strong incident interfering
RF signal
node is charged
to -VBIAS by
interfering signal
VBIAS
bidirectional ESD protection
diode is biased by strong
interfering RF signal
RF signal
2 VBIAS
VBIAS
V BIAS
V BIAS
X
node is charged
to +V BIAS by
interfering signal
Self_biasing .vsd
Figure 16
Self-biasing of bidirectional ESD protection diode
9
Clamping Voltage
The clamping voltage were measured with a scope of at least 3 GHz analog bandwidth at a sample rate of 20 GS/s
and a load impedance of 50 Ω (see Figure 17). Since the maximum peak voltage at the 50 Ω input of the scope
must not exceed ±4 V, an attenuator is needed to damp the voltage to a safe level for the scope. The overall
attenuation of 40 dB, which forms a 1:100 voltage divider, has been calibrated out prior to measurements. In the
post-processing step, offset error and trigger offset were corrected and for noise reduction, a median discharge
waveform was calculated by taking the median over 20 consecutive discharges (statistical ensemble).
Of course, in the actual application there will never be a wide-band 50 Ω load, and therefore the following figures
of merit provide only some kind of benchmark to compare different types of ESD protection diodes. However, the
lower the clamping voltage the better the ESD protection capability, but there is no linear relationship between
clamping voltage and ESD hardness in the final application. The series resistance is around 1 Ω for the
bidirectional ESD protection diode ESD112-B1 and even less then 0.5 Ω for the anti-parallel ESD protection diode
ESD0P4RFL. Therefore, the systematic error due to the load impedance of 50 Ω is only 1% and 2%, respectively,
which is far less than the variance of the discharge current delivered by the ESD generator.
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Clamping Voltage
3 GHz Scope
ESD gun
20 dB
20 dB
base unit
Test_setup_clamping.vsd
Figure 17
Test setup for clamping voltage measurements
Figure 18 shows the contact discharge short-circuit current waveform of the ESD generator used for clamping
voltage measurements. Please note that an ESD source is a current source rather than a voltage source and thus
the short-circuit current waveform is defined by the IEC 61000-4-2 standard [5]. For more details on this please
also refer to Infineon’s application note AN103 [6].
The LNA can sustain damage either due to thermal overload because of too much of electrical energy that is
dissipated in the LNA or due to too high of a peak voltage (peak current) that results in some kind of breakdown
such as dielectric breakdown or second breakdown. It strongly depends on the technology the LNA is based on if
either dissipated energy or peak voltage (peak current) will irreversible destroy the LNA. In the following, we will
discuss both effects separately from each other.
Energy
Too much of electrical energy can damage the LNA. Therefore, the ESD protection diode has to absorb as much
energy as possible. This is equivalent to the claim that the ESD protection diode should have as low a clamping
voltage as possible. Due to the inherent nature of bidirectional diodes, their clamping voltage is always higher than
the clamping voltage of anti-parallel diodes, which achieve very low clamping voltages. As we will see in the next
chapter, low-frequency energy is further suppressed by a simple DC blocking capacitor, which may be already
integrated on-chip. ESD0P4RFL suppresses the energy that is dissipated in a wide-band 50 Ω load by 38 dB, that
is the energy of 682,000 nWs of the unclamped 8 kV ESD event is reduced down to only 106 nWs. This is due to
the very low clamping voltage, which is, for example, only 7.6 V after 30 ns. The clamping voltage of ESD112-B102ELS is 25 V after 30 ns and the energy of an 8 kV ESD event is suppressed by 27 dB down to 1,360 nWs. See
Figure 19 for a plot of the clamping voltage and Figure 20 for a plot of the single side band energy spectral density
that is dissipated in a broadband 50 Ω load. On the energy spectral density curve it can be seen that ESD
protection diodes are quite broadband suppressors with a fairly constant suppression up to 500 MHz. The high
broadband suppression of ESD0P4RFL is especially advantageous for ESD protection of broadband amplifiers,
where decoupling between ESD protection diode and ESD sensitive LNA is hardly possible (see also next
chapter).
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Clamping Voltage
Contact Discharge Waveform
30
1.2 ns
29.3
25
0.96 ns
26.4
Current (A)
20
15
10
5
0 ns
2.93
0
-10
Figure 18
0
10
20
30
Time (ns)
40
50
60
70
Contact discharge waveform of ESD generator, charge voltage = 8 kV (level 4)
Clamping Voltage
140
ESD0P4RFL
120
ESD112-B1-02ELS
Voltage (V)
100
80
Clamping_Voltage.vsd
60
30 ns
25
40
30 ns
7.6
20
0
-10
Figure 19
0
10
20
30
Time (ns)
40
50
60
70
Clamping voltage of ESD112-B1-02ELS and ESD0P4RFL, charge voltage = 8 kV
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Clamping Voltage
SSB Energy Spectral Density
Energy Spectral Density (dB(Ws/Hz))
-90
Unclamped @ 50 Ohm
-100
ESD112-B1
ESD0P2RF @ 50 Ohm
-110
ESD0P4RFL @ 50 Ohm
-120
-130
-140
-150
-160
-170
-180
2
Figure 20
10
100
Frequency (MHz)
1000
3000
Single side band energy spectral density dissipated in a 50 Ω load, charge voltage = 8 kV
Peak Voltage
Too high of a peak voltage can damage the LNA. Therefore, the ESD protection diode should respond significantly
faster than 1 ns, because the typical rise time of a 5 kV ESD event is between 0.7 ns and 1 ns. Please note that the
contact discharge waveform of the ESD generator defined by the IEC 61000-4-2 standard is based on a typical
5 kV ESD event. This means that the rise time is independent of charge voltage while the discharge current scales
linearly with charge voltage. Figure 18 shows the 8 kV contact discharge waveform of the ESD generator, which
equates to level 4 of the IEC 61000-4-2 standard. As one can see, the rise time of the contact discharge waveform
of the ESD generator is 0.96 ns. Scopes are usually provided with an analog filter with maximally flat response.
For such filters, the relationship between 10% to 90% rise time, tr, and 3 dB bandwidth, f3dB, is as follows:
0.45
f 3dB ≈ ----------tr
(6)
According to Equation (6) a scope with an analog bandwidth of 1 GHz is sufficient to measure the peak voltage
of the contact discharge waveform of the ESD generator correctly. However, since the ESD protection diode must
be much faster than 1 ns, a scope with an analog bandwidth of at least 2.5 GHz is needed to measure the peak
voltage correctly. Furthermore, also a high sample rate is needed in order to make sure that the peak will be
sampled at all. All curves shown herein were measured on scopes with an analog bandwidth of at least 3 GHz and
at a sample rate of 20 GS/s. As shown in Figure 21 the 10% to 90% rise time of both ESD0P4RFL and ESD112B1 is about 0.2 ns and thus both are significantly faster than a typical ESD event.
The very low peak voltage of only 57 V together with the very low clamping voltage make ESD0P4RFL the first
choice for ESD protection of extremely ESD sensitive RF LNAs. Due to the inherent nature of ESD112-B1-02ELS,
the peak voltage of 136 V is roughly twice as high as that of ESD0P4RFL. However, by appropriate decoupling
ESD112-B1-02ELS can protect ESD sensitive LNAs almost as good as ESD0P4RFL (see also next chapter). The
low peak voltage is not only due to the fast response time, but also due to the very low parasitic inductance of the
Application Note
17
Rev. 1.1, 2014-05-27
Application Note No. 178
Application Example
leadless package. Even an additional inductance of only 0.2 nH results in an increase in peak voltage of
approximately 12 V. Therefore, diodes in leaded packages are not recommended to protect ESD sensitive RF
LNAs.
Attention: In order to measure peak voltage correctly, the analog bandwidth of the scope must be at least
2.5 GHz and the sample rate must be at least 10 GS/s. Do not trust clamping curves measured
with sample rate of only 5 GS/s or less!
Rise Time and Peak Voltage
140
0.214 ns
122
0.275 ns
136
120
ESD0P4RFL
ESD112-B1-02ELS
Voltage (V)
100
80
0.225 ns
56.6
60
0.189 ns
51.3
40
20
0
-1
0
1
Time (ns)
2
3
Figure 21
Peak voltage and rise time of ESD112-B1-02ELS and ESD0P4RFL, charge voltage = 8 kV
10
Application Example
Please also refer to Infineon’s application note AN167 [8] for an example of ESD protection with ESD0P4RFL and
ESD112-B1-02ELS.
10.1
Low-inductive ground path
Any inductance in series to the ESD protection diode must be avoided. This not only reduces the RF bandwidth,
but—even more critical—also results in excessive ringing of the clamping voltage and thus in an increased peak
voltage. Do not use a thin trace as ground for ESD protection diodes. Use a big copper pad and place vias to
ground as close as possible to the ground pad of the ESD protection diode. See Figure 22 for an example.
Application Note
18
Rev. 1.1, 2014-05-27
Application Note No. 178
Application Example
ESD112-B1-02ELS
ESD0P4RFL
PCB_Layout .vsd
Figure 22
PCB layout example for ESD112-B1-02ELS and ESD0P4RFL
10.2
Decoupling of ESD protection diode and LNA
Since most of the energy of an ESD event is located in the low-frequency region, ESD hardness can be enhanced
by a high-pass filter between ESD protection diode and LNA. Therefore, the greater the cut-off frequency of the
high-pass filter the greater the ESD hardness. Basically, decoupling means that due to Kirchhoff’s laws most of
the current arising from the ESD event is forced through the ESD protection diode rather than be divided more or
less equally between ESD protection diode and LNA. For example, in the case of a bipolar RF transistor as LNA
there would be two diodes in parallel without decoupling: The base-emitter diode of the transistor and the ESD
protection diode.
DC Blocking Capacitor
The easiest high-pass filter is a simple DC blocking capacitor as shown in Figure 23 (a). For a high cut-off
frequency one should use low-cap DC blocking capacitors on the antenna RF line (between ESD protection diode
and LNA). For example, a 15 pF capacitor of 0402 case size has a typical self-resonant frequency of 1.8 GHz. So,
for an application operating above 1 GHz there is no benefit from using a 1 nF capacitor instead. Quite the contrary,
the higher impedance of the 15 pF capacitor at low frequencies significantly enhances ESD hardness. The
minimum DC blocking capacitance, C, for a given insertion loss, IL (expressed in dB), at the lower pass-band
frequency is as follows:
1
C = -------------------------------- ,
2ω 1 Z 0 a – 1
(7)
where Z0 is the source and load impedance seen by the capacitor (usually Z0 = 50 Ω), ω1 = 2πf1 and
a = S 21
–2
= 10
IL ⁄ 10
(8)
is the attenuation of the DC blocking capacitance at frequency f1 (see also Figure 24). Of course, if the DC
blocking capacitor is already integrated on-chip on the LNA, no additional external DC blocking capacitor is
needed anymore. Furthermore, even on-chip capacitors that are realized as MIM-caps are limited to some
picofarad only and therefore provide a high cut-off frequency.
Band-pass filter
For pass-band frequencies below 100 MHz a simple DC blocking capacitor may not be sufficient to block the first
pulse arising from the ESD event. In this case, decoupling can be enhanced by an additional inductor forming a
band-pass filter as shown in Figure 23 (b). Due to the low quality factor of inductors at low frequencies we have
Application Note
19
Rev. 1.1, 2014-05-27
Application Note No. 178
Application Example
to consider the loss of the inductor as well. Thus, the inductance, L, for a given insertion loss, IL, at the lower passband frequency can be calculated as follows:
2Z 0 Q ind 1 + q ( a – 1 ) – 1
ω0 2 2
2
L = -------------------- ⋅ ------------------------------------------ , with q = 1 + Q ind ⎛⎝ 1 – ⎛⎝ ------⎞⎠ ⎞⎠ ,
ω1
ω1
q
(9)
where Z0 is the source and load impedance seen by the filter,
ω0 =
ω1 ω2
(10)
is the resonant frequency of the band-pass filter, ω1 = 2πf1 is the lower pass-band frequency, ω2 = 2πf2 is the upper
pass-band frequency, Qind is the quality factor of the inductor at the lower pass-band frequency, f1, and a is the
attenuation of the band-pass filter at the lower pass-band frequency, f1, as given by Equation (8). See Figure 24
for an equivalent circuit of the band-pass filter. The capacitance, C, is then given by:
1
C = --------2
ω0 L
(11)
Vbias
C
L
C
LNA
Cbypass
L
C
LNA
(a) High-pass filter
LNA
(b) Band-pass filter
(b) Noise matching network
X
Filters.vsd
Figure 23
Three different techniques for decoupling of ESD protection diode and LNA: (a) simple DC
blocking capacitor as 1st order high-pass filter, (b) band-pass filter for applications operating
around 100 MHz or lower and (c) noise matching network as 2nd order high-pass filter
Equivalent circuit of band-pass
filter with lossy inductor
Frequency domain
Q ind =
R
Z0
L
lossy inductor
C
ω1 L
R
IL
Z0
f1
X
Figure 24
f2
f
Filter_2.vsd
Equivalent circuit of band-pass filter. Insertion loss, IL, is defined at the lower frequency f1
Application Note
20
Rev. 1.1, 2014-05-27
Application Note No. 178
Application Example
Noise matching network
If an impedance matching network for optimum noise match for an ESD sensitive LNA is needed, the noise
matching network should be designed as 2nd order high-pass filter as shown in Figure 23 (c). The 3 dB cut-off
frequency of the noise matching filter is usually somewhat lower than the application frequency, but it should be
greater than one third of the application frequency. In this way one gets noise matching and decoupling for LNAs
operating in the gigahertz range in one go. An example of a GPS LNA operating at 1.575 GHz is shown in
Figure 25. The Infineon RF transistor BFP740F, which can withstand only 400 V as per HBM (Human Body Model
[4]), is effectively protected up to ±10 kV as defined by the IEC 61000-4-2 standard by simple using ESD0P4RFL
together with a noise matching network that has a cut-off frequency of 1.1 GHz. ESD0P4RFL increases noise
figure of the LNA only by 0.06 dB.
high-pass noise matching filter
3V
6mA
56Ω
68kΩ
100nF
100nF
10Ω
±10 kV
1.8pF
3.9nH
3.9nH
BFP740F
2.2pF
ESD0P4RFL
RF OUT
5.6pF
PCB trace
(0.9mm)
GPS _LNA_Schematic.vsd
Figure 25
Example of a high-pass noise matching network to decouple ESD protection diode and ESD
sensitive RF transistor
Table 2
Electrical characteristics of GPS LNA shown in Figure 25
Parameter
Symbol
Values
Min.
Supply voltage
Supply current
Gain
Noise figure
1)
Input return loss
Output return loss
Reverse isolation
Stability factor
ESD hardness
VCC
ICC
|S21|2
NF
RLIN
RLOUT
IREV
k
VESD
Typ.
Unit
Note / Test Condition
Max.
3
V
6
mA
20
dB
0.85
dB
11
dB
12
dB
27
dB
>1
incl. SMA connector and PCB losses
from 0 to 8.5 GHz
> 10
kV
IEC 61000-4-2 contact discharge
1) Noise figure without ESD0P4RFL is 0.8 dB (including SMA connector and PCB losses)
Application Note
21
Rev. 1.1, 2014-05-27
Application Note No. 178
Application Example
10.3
Ultra wide band applications
For ultra wide band applications the low capacitance of ESD112-B1-02ELS can be easily compensated to extend
the frequency range of the 20 dB return loss point from 3.2 GHz to 10 GHz, which is more than adequate for recent
UWB applications. Here, compensation is achieved by a 1.9 mm long, 84 Ω microstrip line surrounding the ESD
protection diode as shown in Figure 27. Even with compensation the 20 dB return loss point cannot be extended
to any frequency range, because the length of the compensation structure must be significantly shorter than the
wave length. Thus, for UWB applications an inherent low capacitance of the ESD protection diode is mandatory.
For example, to compensate the capacitance of ESD0P4RFL a 84 Ω microstrip line with a length of 3.7 mm is
needed. This is twice the length that is needed for ESD112-B1-02ELS, and therefore the frequency range of the
20 dB return loss point can be extended to “only” 6 GHz. Figure 26 shows a plot of the return loss of ESD112-B102ELS with compensation of capacitance, which is based on the simulation of the layout shown in Figure 27. For
more details on this please refer to Infineon’s application note AN140 [7].
ESD112-B1-02ELS
Return Loss of ESD0P2RF-02LS
40
Uncompensated
35
Compensated
Return Loss (dB)
30
25
3.2 GHz
20
10 GHz
20
20
6.2 GHz
15
13 GHz
15
15
10
5
0
2
10
20
Frequency (GHz)
Figure 26
Return loss of ESD112-B1-02ELS without and with compensation of capacitance
Application Note
22
Rev. 1.1, 2014-05-27
Application Note No. 178
About Other Solutions
1.9 mm
50 Ω
50 Ω
84 Ω
ESD112-B1-02ELS
PCB_Layout _Compensation .vsd
Figure 27
Layout example on how the small capacitance of ESD112-B1-02ELS can be compensated
11
About Other Solutions
On the market one can find other sub-picofarad solutions than low-cap ESD protection diodes such as polymerbased suppressors or multilayer varistors. For a comparison of clamping voltages please refer also to Infineon’s
application note AN103 [6]. So, the question that arises is whether they can protect ESD sensitive RF transistors
as well. To answer this question, the GPS LNA shown in Figure 25 was also tested with a multilayer varistor
(MLV), which has a typical capacitance of 0.5 pF, and a polymer-based suppressor, which has a typical
capacitance of less than 0.15 pF up to 1.8 GHz. The ESD test voltage was increased step-by-step until the supply
current significantly decreased, which indicates a failure or significant degradation of the RF transistor. At each
step 10 contact discharges with either polarity were applied to the RF input pin. Figure 28 shows the results as
plot of supply current versus ESD test voltage. After the DC failure level was known a before and after comparison
was done, for which the ESD test voltage was chosen to be approximately 30% below the DC failure level. See
Table 3 for a summary of the before and after comparison. Infineon’s ESD0P4RFL effectively protects the RF
transistor from ±10 kV contact discharges and there is no significant change in electrical characteristics even after
500 contact discharges. This well exceeds protection level 4 as defined by the IEC 61000-4-2 standard, which is
the highest protection level that is defined for contact discharge (8 kV charge voltage).
Polymer-based suppressor
As expected, the polymer-based suppressor cannot protect the ESD sensitive RF transistor, because its trigger
voltage of 300 V is far too high. The RF transistor dies long before the polymer-based suppressor gets triggered.
This makes polymer-based suppressors completely useless and a before and after comparison pointless.
Multilayer varistor
Multilayer varistors (MLVs) have a similar structure like multilayer ceramic capacitors (MLCCs), except that MLVs
make use of zinc oxide (ZnO) grains as dielectric between two electrodes. In order to get sub-picofarad MLVs, the
electrode spacing has to be increased, which lengthens the path through which the current must travel, increasing
varistor voltage (= breakdown voltage) and series resistance. Therefore, sub-picofarad MLVs suffer from very high
clamping voltages and their ESD protection capability is much worse compared to sub-picofarad ESD protection
diodes. Furthermore, the before and after comparison has revealed that MLVs suffer from a large number of ESD
events. After 500 contact discharges with only 4.5 kV, which is quite below the maximum rating of the MLV, its
noise figure increases by more than 0.4 dB. Hence, MLVs are absolutely inadequate for ESD protection of ESD
sensitive RF LNAs with noise figures around 1 dB or less.
Application Note
23
Rev. 1.1, 2014-05-27
Application Note No. 178
Conclusion
Contact discharge as per IEC 61000-4-2
6.5
Infineon ESD0P4RFL
Multilayer Varistor
Supply Current (mA)
6.3
Polymer-based Suppressor
6.1
5.9
5.7
5.5
0
2
4
6
8
10
ESD Test Voltage (± kV)
Figure 28
DC failure levels for different ESD protection devices
Table 3
Results of before and after comparison
Parameter
Symbol
Noise figure
DC failure level
14
ESD Protection Device
w/o
Capacitance
12
ESD0P4RFL
MLV
Unit
Polymer-based
C
NF
VESD-Failure < 1
0.4
0.5
< 0.15
pF
0.06
0.10
< 0.02
dB
14
6
<1
kV
ICC
NF
-
6.14
6.00
-
mA
-
0.87
0.93
-
dB
Before ESD testing
Supply current
Noise figure
After applying 500 contact discharges as per IEC 61000-4-2 (250 discharges per polarity)
ESD test voltage
Supply current
Noise figure
VESD
ICC
NF
-
10
4.5
-
6.08
5.96
-
0.88
1)
1.37
-
kV
-
mA
-
dB
1) After the stressed MLV was replaced by a new one, noise figure was again 0.93 dB. So, it was the MLV that degraded and
not the Infineon RF transistor BFP740F.
12
Conclusion
It has been shown that Infineon’s ESD protection diodes ESD0P4RFL and ESD112-B1 are very much suited for
ESD protection of RF interfaces up to frequencies as high as 10 GHz. Even though low capacitance is necessary
for RF applications operating in the gigahertz range, it is not all to be considered. Low noise figure, low parasitic
Application Note
24
Rev. 1.1, 2014-05-27
Application Note No. 178
Appendix
inductance to gain high bandwidth, low harmonic generation, robustness against interferer, fast response time
and, most important, low clamping voltage to protect even the most ESD sensitive RF transistor are also crucial
factors for RF applications. And of course, the ESD protection device must not suffer from a large number of ESD
events! Nothing is more annoying than an ESD protection device that ruins noise figure after several ESD events.
Then all the effort and money spent on the LNA’s low noise figure was to no avail. To cap it all off, Infineon shrunk
the ESD protection diode and put it into an incredible small package of only 0201 case size. So, now there is no
excuse anymore for not having enough space for ESD protection!
13
Appendix
For more details on the following please refer to [2] and [3]. A noisy microwave component can be characterized
either by noise temperature or by noise figure. Noise temperature is the equivalent temperature of a resistor at the
input of the component, which is then considered as noiseless, while noise figure is a measure of the degradation
in the signal-to-noise power ratio between the input and output of the component. It is important to understand,
that noise figure is defined for a matched noise source that consists of a resistor at temperature T0 = 290 K.
RN
VN
PNi+PSi
Noisy
two-port
GA, Te
PNo+P So
ZL
Noisy_Two_port_network.vsd
Figure 29
Equivalent circuit of a noisy resistor delivering noise power to a noisy two-port network
A noisy source resistor RN can be modeled by a noiseless source resistor RN and a noise voltage source VN as
shown in Figure 29. The maximum available noise power from the source resistor RN is given by
2
VN
P N = ---------- = kTB ,
4R N
(12)
where k = 1.38 10-23 J/K is the Boltzmann constant, T is the temperature in kelvin (K), B is the bandwidth of the
system in Hz and VN is the rms-value of the noise voltage in volt.
Noise factor F is defined as the ratio of the available signal-to-noise power ratio at the input to the available signalto-noise power ratio at the output:
P Si ⁄ P Ni
F = ----------------------- .
P So ⁄ P No
(13)
Since the available noise power at the input, PNi, and output, PNo, of the microwave component is considered, also
the available signal power at the input, PSi, and output, PSo, and thus the available power gain GA of the microwave
component must be considered, rather than simply the transducer power gain. Using the available power gain,
GA, of the microwave component, we can rewrite Equation (13) to
P No
F = ----------------- ,
P Ni G A
Application Note
(14)
25
Rev. 1.1, 2014-05-27
Application Note No. 178
Appendix
where
P So
G A = --------- .
P Si
(15)
By definition, the available noise power at the input, PNi, is due to a resistor at temperature T0 and thus from
Equation (12) it follows that
P Ni = kT 0 B .
(16)
The noise power internally generated by the microwave component can also be thought of as noise power due to
a resistor at equivalent temperature Te at the input of an otherwise noiseless microwave component. The available
noise power at the output of the microwave component can then be expressed as
P No = k ( T 0 + T e )BG A ,
(17)
where Te is the equivalent noise temperature of the microwave component. Using these results in Equation (14)
gives noise factor as
Te
F = 1 + ----- .
T0
(18)
Now we will consider the special case for a passive, lossy two-port network [2]. When the entire system is in
thermal equilibrium at temperature T, the maximum available noise power at the output must be PNo = kTB. But
we can also think of this power coming from the source resistor and from the lossy two-port network itself:
P No = kTB = k ( T + T e )BG A .
(19)
Solving Equation (19) for the equivalent noise power Te gives
T e = ( L – 1 )T ,
(20)
where L is the loss factor, defined as L = 1/GA > 1. Then from Equation (18) noise factor is
T
F = 1 + ( L – 1 ) ----- .
T0
(21)
Therefore, noise factor of a passive, lossy two-port network at room temperature, that is T ≅ T0, is given by
F
T ≅ T0
1
≅ L = ------- .
GA
(22)
Noise figure NF, which is noise factor F expressed in decibel (dB), of a passive, lossy two-port network at room
temperature is therefore given as
NF
dB
≅L
dB
= –GA
dB
.
(23)
Insertion loss, IL, and return loss, RL, are defined as follows:
IL
RL
dB
dB
= – 20 log S 21 ,
(24)
= – 20 log S 22 ,
(25)
Application Note
26
Rev. 1.1, 2014-05-27
Application Note No. 178
Appendix
where S21 = S12 is the transmission coefficient and S22 = S11 is the reflection coefficient of the diode in a 50 Ω
environment as per Figure 30. The available gain, GA, of the diode when the source impedance is matched to
50 Ω, that is ΓS = 0, calculates from the S-parameters as follows:
S 21 2
G A = ---------------------21 – S 22
.
(26)
ΓS = 0
Thus, noise figure can also be interpreted as insertion loss minus mismatch loss:
NF
dB
= IL
dB
– ML
dB
,
(27)
where mismatch loss ML is according to Equation (26) as follows:
1
ML = ---------------------2- ,
1 – S 22
(28)
or expressed in dB
ML
dB
= – 10 log ( 1 – 10 – RL ⁄ 10 ) .
(29)
Z0
Z0
50Ω
50Ω
Diode_in_ 50ohm_environment .vsd
Figure 30
Diode, for example ESD0P4RFL, as two-port network in a 50 Ohm environment
References
[1]
Steven H. Voldman, “ESD: RF Technology and Circuits,” John Wiley & Sons, 2006.
[2]
David M. Pozar, “Microwave Engineering,” John Wiley & Sons, 2005.
[3]
Guillermo Gonzales, “Microwave Transistor Amplifiers: Analysis and Design,” Prentice-Hall, N.J., 1984.
[4]
JESD22-A114D, “Electrostatic Discharge (ESD) sensitivity testing Human Body Model (HBM),” JEDEC Solid
State Technology Association, March 2006.
[5]
IEC 61000-4-2, Electromagnetic Compatibility (EMC) Part 4: Testing and measurement techniques –
Section 2: “Electrostatic discharge immunity test,” International Electrotechnical Commission, 1995.
[6]
Infineon Technologies: “Application Note No. 103: ESD and Antenna Protection using Infineon ESD0P8RFL”
[7]
Infineon Technologies: “Application Note No. 140: ESD Protection for Digital High-Speed Interfaces (HDMI,
FireWire,...) using ESD5V3U1U”
[8]
Infineon Technologies: “Application Note No. 167: ESD Protection for Broadband Low Noise Amplifier
BGA728L7 for Portable and Mobile TV Applications”
Application Note
27
Rev. 1.1, 2014-05-27