Solving EMI and ESD Problems with Integrated Passive Device Low Pass Pi Filters

AND8026/D
Solving EMI and ESD
Problems with Integrated
Passive Device Low
Pass Pi Filters
http://onsemi.com
Jim Lepkowski
Phoenix Central Applications Laboratory
APPLICATION NOTE
LOW PASS
FILTER
Background
The demand of cost sensitive portable products such as
cellular telephones has resulted in the development of the
ON Semiconductor NZMM7V0T4 Integrated Passive
Device (IPD) EMI filter with ESD protection. This
integrated filter array is used to replace low pass filters that
have been implemented with discrete resistors, capacitors,
and zener diodes. The filters, as shown in Figures 1, 2 and
3, use the capacitance of a zener diode to form a
resistor/capacitor (RC) low pass Pi filter. An IPD IC will
reduce the component count and the required printed circuit
board space. Also, this filter solution offers the advantage
that it is manufactured using standard integrated circuit
manufacturing processes to achieve a low cost solution in a
small IC package.
The NZMM7V0T4 multiple channel filter array, as shown
in Figure 5, is the first member of a new family of IPD EMI
filters that will include single, dual, and multiple filter arrays
with various cut–off frequencies (f–3dB). The NZMM7V0T4
was developed to protect cellular telephone I/O connectors;
however, this IC can provide a low cost EMI and ESD filter
solution for a wide range of applications. The ON
Semiconductor family of IPD EMI filters also consists of a
single and a dual channel filter. The NZF220TT1 is the single
channel device and is available in a three pin SC–75 package.
The NZF220DFT1 is the dual channel device and is available
in a five pin SC–88A package. Both the single and the dual
channel devices are functionally identical to the nine channel
NZMM7V0T4 filter array.
VIN
VOUT
Figure 1. Functional Schematic
Representation of the NZMM7V0T4
R1
VIN
VOUT
D1
D2
Figure 2. NZMM7V0T4 Filter Channel
R1
100 Ω
VIN
C1
22pF
VOUT
C2
22 pF
Figure 3. NZMM7V0T4 Filter
Channel – Equivalent Circuit
VIN
VOUT
Figure 4. Equivalent Discrete Pi Filter
 Semiconductor Components Industries, LLC, 2001
June, 2001 – Rev. 2
1
Publication Order Number:
AND8026/D
AND8026/D
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20
21
22
23
24
1
18
17
NC
2
16
3
15
4
14
5
13
6
12
11
10
9
8
7
Figure 5. NZMM7V0T4 Device Schematic
1
6
1
3
2
3
4
2
Figure 6. NZF220DFT1 Device Schematic
Figure 7. NZF220TT1 Device Schematic
Functional Description
The NZMM7V0T4 contains nine low pass filter channels
and three separate zener diodes. The low pass filters are
formed by a 100 ohm resistor and two zener diodes that
function as 22 pF capacitors. The resulting Pi filter
configuration attenuates noise signals that are both entering
and exiting the filter network. Components R1 and C2 form
a filter that attenuates the high frequency signals entering the
network via the I/O cable, while R1 and C1 attenuates the
high frequency noise that is exiting the network. The RC Pi
filters are first order filters with a frequency attenuation
roll–off of –20 dB/decade.
The NZMM7V0T4 also provides ESD protection by
clamping any high input voltage to a non–destructive
voltage level that is equal to the zener voltage of the diode.
In contrast, a RC filter will limit the slew rate of the transient
voltage waveform, but will not clamp the ESD voltage to a
safe voltage level unless external zener diodes are added to
the filter configuration. The NZMM7V0T4’s Pi filters are an
ideal configuration to provide ESD protection because two
zener diodes are used in the circuit. This configuration
results in a clamping voltage that is equal to the zener
breakdown voltage.
The NZMM7V0T4’s three separate zener diodes have a
capacitance of 8 pF and a zener breakdown voltage of 7 V.
These diodes can be used for a variety of applications,
including the protection of USB or RS232 serial ports.
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AND8026/D
IPD is housed in a 24 pin Lead Frame Chip Scale Package
(LFCSP). The LFCSP package is only 16 mm2 square in size
with a package height of less than 1 mm. Figure 8 shows a
cross section of the silicon wafer.
The zener diodes housed in the NZMM7V0T4 are small
in size compared to standard zener diodes; therefore, it is
possible to package multiple filter channels in the small
LFCSP IC package. The transient voltage pulse resulting
from an ESD event is relatively low in energy because of the
short pulse duration; therefore, a very small PN junction can
absorb the energy without damage. Furthermore, the
capacitance of a PN junction is proportional to the size of the
diode; thus the zener capacitance will be small in magnitude.
The value of the capacitance (Co) is a function of
The NZMM7V0T4 IPD is an ideal EMI/ESD solution for
portable cost sensitive applications. Each filter channel in
the IPD can replace the equivalent discrete component filter
shown in Figure 4 that requires one resistor, two capacitors
and two zener diodes. Note the discrete filter requires the
two zener diodes to provide the ESD protection and to
protect the capacitor on the input side of the filter from an
over–voltage condition. Therefore, the nine filter channels
in the NZMM7V0T4 can replace 9 resistors, 18 capacitors,
and 18 diodes, in addition to the three separate zener diodes.
Thus the NZMM7V0T4 can replace 48 discrete
components, which reduces both the system cost and the
required PCB space. In addition, the integration of the
filtering network in the small chip scale package provides
for a better attenuation characteristic than a discrete filter by
minimizing the parasitic impedances that result from the
multiple contacts between the components.
The schematics for the NZF220TT1 single channel and
the NZF220DFT1 dual channel filters are shown in Figures
6 and 7. The single and dual filter channel devices are
identical to the NZMM7V0T4 nine channel device. Each
filter channel consists of a Pi filter that is formed by a 100
Ω resistor and two zeners that have a junction capacitance of
22 pF.
1. The material resistively (ρ) where the doping level
determines the nominal zener breakdown voltage
2. The diameter (D) of the junction which determines the
power dissipation
3. The voltage across the junction (Vc)
4. A constant K
This relationship is expressed as:
Co Manufacturing Details
The 24 pin NZMM7V0T4 is manufactured using
conventional planar processing on a silicon substrate. The
K D4
V
c
OXIDE
PASSIVATION
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RESISTOR
CONTACT METAL
ZENER JUNCTION
ZENER
JUNCTION
Si SUBSTRATE
Figure 8. Cross Section View of Filter Channel
Interpreting the Data Sheet Specifications
The IPD’s frequency and insertion loss characteristics can
be measured using a spectrum analyzer with a tracking
generator as shown in Figure 9. Figure 10 shows the
frequency response of the NZMM7V0T4 using the
evaluation PCB shown in Appendix I. The four main
characteristics of the NZMM7V0T4 that need to be
analyzed are listed below:
1. Cut–off (f–3dB) frequency
2. Insertion loss
3. High frequency rejection specification
4. ESD clamping voltage
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AND8026/D
TRACKING
GENERATOR
SPECTRUM
ANALYZER
50 TG OUTPUT
RF INPUT
NZMM7V0T4
+
VS
–
TEST BOARD
+
VOUT
–
+
VIN
–
50 Test Conditions:
Source Impedance = 50 Load Impedance = 50 Input Power = 0 dBm
NZMM7V0T4
Figure 9. Measurement Conditions
Cut–off (f–3dB) Frequency
impedance of the source (transmitter) and load (receiver)
circuits. The IPD’s frequency response in the customer
circuit will be different than the data sheet characteristics
because it is unlikely that the actual source and load
impedances are equal to 50 ohms. This issue is discussed in
the Filter Design Equations section of this paper.
The cut–off frequency, or f–3dB frequency, is defined as
the corner frequency where the gain (attenuation) of the
filter decreases (increases) by 3 dB from the low frequency
gain (attenuation). Also, the f–3dB frequency is the point
where the gain of the filter is equal to 0.707 (1/ 2). The
frequency response of a discrete filter is dependent on the
0
–5
–6.3
–10
–15
GAIN (dB)
–20
–25
–30
–35
–40
–45
–50
1.0
10
100
f, FREQUENCY (MHz)
Figure 10. Typical EMI Filter Response
(50 Source and 50 Load Termination,
Insertion Loss = –6.3 dB,
f–3dB = 220 MHz)
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1000
3000
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Insertion Loss
ESD Clamping Voltage
The insertion loss is defined as the ratio of the power
delivered to the load with and without the filter network in
the circuit. This characteristic is dependent on the
impedance of the source (transmitter) and load (receiver)
circuits, and is proportional to the magnitude of the filter
resistance. The insertion loss equation is listed below.
In addition to its noise filtering function, the
NZMM7V0T4 also provides ESD protection. The
NZMM7V0T4 is rated to meet the IEC61000–4–2
specification that simulates the case when a person carrying
a metallic object touches an interface contact. The
NZMM7V0T4’s circuit configuration of two zeners results
in an ESD clamping voltage that will be within a few
millivolts of the zener breakdown voltage. The nominal
clamping voltage of 7 V should be safe for most designs;
however, the designer should verify that the clamping
voltage is less than the maximum input voltage rating of the
filter’s interface circuitry.
Insertion Loss(dB) 20 log 10
RSRS R1 RL RL
for RS RL 50 and R1 100 Insertion Loss 6.02 dB
If the transmitter and receiver circuits are digital circuits,
the insertion loss can be neglected and VOUT will be equal
to VIN . The output impedance of a digital circuit (RS) is
typically very small, while the input impedance (RL) is
usually equal to a small capacitor, and is essentially an open
circuit load at DC. The insertion loss is usually not a concern
for digital circuits; instead, the filter’s effect on the rise and
fall times of the digital pulse waveform must be evaluated.
This issue is discussed in Application Note AND8027 (2).
If the transmitter and receiver are analog circuits, the
insertion loss must be analyzed. The RC Pi filter will
function as a voltage divider because of the resistive
element. The DC voltage divider effect of the filter can be
analyzed by using the simplified schematic shown in Figure
11, with the equations listed below.
RS
R1 = 100 ohms
Filter Design Equations
Frequency Response
The two port analysis method can be used to obtain the
filter’s transfer equation and an equation for the f–3dB
frequency. Additional details on the derivation of the two
port equations and the equations defining the input
impedance (Zin), output impedance (ZOUT), and current
gain (AI) are provided in reference (3).
Table 2 lists the transfer equations that define the voltage
gain and filter characteristics of the Pi filter. Included in the
table are equations that show that the Pi filter’s f–3dB is
influenced by the source (transmitter) and load (receiver)
circuits that are connected to the filter. In addition, equations
are given that show the bi–directional filter feature of the Pi
network.
The f–3dB frequency is found by determining the location
of the poles of the transfer equation. Then the f–3dB
frequency is obtained by substituting s = jω into the
equation, where ω = 2 πf.
The transfer equation AV1 is the transfer equation that is
representative of the Pi filter when the effects of the source
impedance (ZS) and the load impedance (ZL) are neglected.
AV1 can be used to obtain an estimate of the f–3dB frequency;
however, the transfer equation AV⊕ should be used to obtain
a more accurate calculation. The voltage gain AV1 is defined
as the ratio of the output voltage (VOUT) to the input voltage
(VIN) when the load impedance is an open circuit (ZL = ∞
and IOUT = 0). AV1 can also be interpreted as the equation
defining the circuit that filters the noise signals that “enter”
the Pi network.
In contrast, AV2 reverses the input and output assignments
of the circuit to show the bi–directional filter characteristic
of a Pi network. AV2 is defined as the ratio of the input
voltage (VIN) to the output voltage (VOUT); therefore, AV2
can be interpreted as the equation defining the circuit that
filters the noise signals that “exit” the Pi network.
The transfer equation AV⊕ is the transfer equation that is
representative of the spectrum analyzer / tracking signal
generator frequency measurement system. AV⊕ is
calculated by comparing the output voltage (VOUT) to the
voltage at the input of the filter (VIN). AV⊕ can be derived
by substituting ZS = 0 into the AV* equation. In contrast to
RL
VIN
VOUT
RS = Transmitter output impedance
RL = Receiver input impedance
VOUT RS RRL1 RL VIN
Figure 11. Insertion loss analysis
In addition, the voltage divider equation can usually be
simplified. For example, if the transmitter is an operational
amplifier, RS will be equal to the output impedance of the
amplifier, which is typically equal to less then an ohm. Thus,
the RS term can be neglected.
High Frequency Rejection Specification
The attenuation or rejection level of a specific high
frequency is application specific and is used to verify the
attenuation of a particular frequency. For example, it is
critical in a cellular phone that the EMI filter attenuates the
system’s operating frequency. Thus, the NZMM7V0T4 has
a minimum attenuation level specified at 900 MHz. For
non–cellular applications, the designer should verify the
filter’s attenuation for noise sources such as the
microprocessor’s clock frequency.
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AND8026/D
the second order AV* equation, the AV⊕ equation is a first
order equation. Thus the AV⊕ equation provides for a simple
expression that can be solved to determine the f–3dB
frequency.
The AV⊕ equation is often a very good approximation of
the system transfer equation AV* for analog circuits. For
example, assume that the transmitter circuit is an operational
amplifier. The output impedance of an ideal analog
amplifier is zero; therefore, the ZS in the AV* equation can
be neglected because ZS << R1 and ZS << RL.
In addition, the AV⊕ equation is also a very good
approximation of AV* for digital logic circuits. Now assume
that the transmitter circuit is a CMOS digital logic IC that
has an output stage consisting of a PMOS and a NMOS
transistor. For both the logic output “high” and “low” cases,
the output impedance of the logic chip will be equal to the
channel resistance (rds_ON) of the transistor that is turned
“ON”. The output impedance of the CMOS IC can be
neglected because the output impedance of the “ON”
transistor (rds_ON ≈ milli–ohms) is in parallel with the output
impedance of the “OFF” transistor (rds_OFF ≈ mega–ohms).
The major factor effecting the f–3dB frequency of a passive
filter is the magnitude of the source and load impedances. To
a smaller degree, the frequency response is also a function
of the initial tolerances of the resistors and capacitors, the
component changes over temperature, and the bias voltage
of the signal. These errors can be neglected for most
applications; however, a detailed analysis of the component
error terms is shown in Application Note AND8027
reference (2).
The transfer equation AV* is defined as the system voltage
gain and is the transfer equation that is representative of the
ESD characteristics of the Pi filter. AV* is calculated by
dividing the output voltage (VOUT) by the input voltage of
the source (VS). AV* shows that the frequency response of
the Pi filter is dependent on the impedance of the driver and
receiver circuits that are connected to the filter. Because the
transfer equation includes the source and load impedances,
AV* will be a second order equation that is relatively
complex with a frequency roll–off of –40 dB. Thus, a simple
expression to determine the poles of the equation (i.e. the
f–3dB frequency) is not readily apparent. However, AV* can
be evaluated by using a mathematical software program
such as Microsoft’s Excel to obtain a Bode plot of the
frequency response. Then the –3 db frequency can be
determined directly from the Bode plot. Also, the –3 db
frequency can be determined by performing a SPICE circuit
simulation.
Table 1. Definition of Y Parameters
Admittance matrix (Y)
I1
Y Y
= 11 12
I2
Y21 Y22
V1
V2
Pi filter Y parameters
Short circuit input
admittance
I
Y11 1
V1
| V2 0
Y11 sC1 G1
Short circuit forward
transfer admittance
I
Y21 2
V1
| V2 0
Y21 G 1
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Short circuit reverse
transfer admittance
I
Y12 1
V2
| V1 0
Y12 G 1
Short circuit output
admittance
I
Y22 2
V2
| V1 0
Y22 G1 sC2
AND8026/D
Table 2. Pi Filter Frequency Characteristics
IIn
Pi Filter
Circuit
IOUT
R1
+
VIN
C1
+
VOUT
C2
–
–
V
Y21
AV1 OUT VIN
Y22
AV2 VIN
Y21
Y11
VOUT
1
Voltage Gain
V
G1
R 1C 2
AV1 OUT VIN
G1 sC2
s R 1C
1 2
1
AV2 G1
R 1C 1
VIN
VOUT
G1 sC1
s R 1C
1 1
1
f3dB_AV1 2 R1C2
1
f3dB_AV2 2 R1C1
f–3dB
f3dB_AV1 f3dB_AV2 72 MHz with C1 C2 22 pF and R1 100 Application
*Useful to approximate f–3dB
*ZS = 0 & ZL = ∞
IIn
Pi Filter
Circuit
IOUT
R1
+
VIN
C1
+
C2 VOUT
–
ZL
–
V
Y 21
Av OUT VIN
Y22 YL
Voltage Gain
G1
V
G1
C2
AV OUT Y G
VIN
sC2 YL G1
s L 1
C2
f–3dB
Y
G
f3dB L 1
2 C2
f3dB 217 MHz with RL 50 , C1 C2 22 pF and R1 100 Application
*Representative of most analog and digital circuits
*Representative of Spectrum Analyzer/Tracking Generator System
*ZS = 0 & ZL ≠ ∞
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IIN
ZS
+
Pi Filter
Circuit
IOUT
R1
+
VIN
VS
–
+
C2 VOUT
C1
–
ZL
–
V
Y21
AV * OUT VS
Y22 YL ZS (Y Y11YL)
AV * VOUT 2 G1
VS
as bs c
Voltage Gain
where
a ZSC1C2
b ZSC1G1 ZSC2G1 ZSYLC1 C2
c ZSG1YL YL G1
*Note 4
S
b b 24ac
2a
S j 2 f
f–3dB
f3dB 2
f3dB 121 MHz with RS RL 50 , C1 C2 22 pF and R1 100 *Representative of ESD analysis circuit
*ZS ≠ 0 & ZL ≠ ∞
Application
1.
2.
3.
4.
Admittance (Y) is equal to the reciprocal of the impedance (i.e. Y = 1/Z)
Conductance (G) is equal to the reciprocal of the resistance (i.e. G = 1/R)
∆Y = Y11 Y22 – Y12 Y21
Typically solved using Excel or SPICE
ESD Equations
The protection characteristics of the Pi filter can be
analyzed by considering the Pi circuit as two separate stages,
as shown in Figure 12. The voltage at the first stage (VIN)
will have a peak or overshoot voltage that is significantly
above the clamping voltage of because of the dynamic
resistance of the zener as shown below. In contrast, the
voltage at the second stage (VOUT) will be very close to the
zener’s clamping voltage because the RD*IP term is small in
comparison to the magnitude of the RD*IP term of the first
stage.
1st Stage
2nd Stage
RS
330
8 KV
VS
+
R1
+
+
RD
VIN
VOUT
D1
–
RD
RL
D2
–
–
Figure 12. ESD Analysis of Pi Filter
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Circuit to be
protected
AND8026/D
The equations describing the ESD characteristics are
listed below.
The results for the ESD calculation gives the results listed
below, assuming RD is equal to one ohm:
VIN = 31.2 V
VOUT = 7.3 V
VClamping_voltage Vbr RD * IP
VIN Vbr RSRDRDVS Vbr RRDSVS
VOUT Vbr R
The voltage at VOUT confirms that the NZMM7V0T4 will
clamp the ESD voltage to a safe value. Note that these
equations do not include any parasitic inductances that cause
the clamping voltage to have an overshoot peak voltage. It
is necessary to locate the NZMM7V0T4 close to the
connector (ESD source) and to minimize the PCB
inductances in order to optimize the ESD performance.
RD
R
VIN Vbr D VIN
R1
1 RD
Where
VS = IEC 61000–4–2 Voltage waveform = ± 8 kV
RS = IEC 61000–4–2 source impedance = 330 Ω
Vbr = breakdown voltage = 7 V
RD = dynamic resistance of the zener ≤ 1 Ω
IP = Peak ESD Current
R1 = 100 Ω
C1 = C2 = 22 pF
RD << RS
RD << R1
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Application Information
PCB Design Issues
The design of the NZMM7V0T4’s PCB is critical to the
ESD and filter performance of the device. Standard high
frequency PCB design rules should be used in the layout to
minimize any parasitic inductance and capacitance that will
degrade the filter’s performance. The most important PCB
layout issue is to locate the NZMM7V0T4 as close to the
connector as possible.
The Pi filter is a bi–directional filter. By convention, the
NZMM7V0T4’s input pins (VIN) are normally connected to
the I/O connector, while the output (VOUT) pins are
connected to the circuitry on the PCB. The labeling of the
filter pins as either inputs or outputs is arbitrary; therefore,
the user has the flexibility to re–assign the inputs and outputs
in order to simplify the PCB routing.
Listed below are design guidelines to follow to optimize
the NZMM7V0T4’s EMI/ESD performance. This list was
derived from experience and the references (1), (4) and (5).
The NZMM7V0T4 can be used as a low cost EMI and
ESD filter solution for a wide range of applications
including cellular phones, PCs, and input circuits such as
analog switches and multiplexers / demultiplexers. Listed
below are a list of application examples. Figures 13 through
17 show example circuits using the NZMM7V0T4.
Cellular Telephones
•
•
•
•
•
•
Personal Computers
•
•
•
•
•
•
PCB Recommendations
Optimizing EMI Filter Performance
• Filter all I/O signals entering / leaving the noisy
•
•
•
Remote speaker
Microphone
Earphone
SIM connector
RS232 / USB serial port
Keypad
environment
Locate the NZMM7V0T4 as close to the I/O connector
as possible
Minimize the loop area for all high speed signals
entering the filter array
Use ground planes to minimize the PCB’s ground
inductance
Keyboard
Game port
Parallel port
Mouse
USB / RS232 serial port
Flat panel display I/O port
General Purpose Applications
• ESD/EMI protection of analog switches, multiplexers,
and demultiplexers
• ESD protection for industrial motherboards
Optimizing ESD Protection
• Locate the NZMM7V0T4 as close to the I/O connector
as possible
• Minimize the PCB trace lengths to the NZMM7V0T4
• Minimize the PCB trace lengths for the ground return
connections
Appendix I shows the PCB artwork that was used to
evaluate the NZMM7V0T4.
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Gain = K
10 Ω
22 pF
32 Ohm
Speaker
Gain = –K
10 Ω
22 pF
Figure 13a
Gain = K
10 Ω
R1
D1
Gain = –K
D2
32 Ω
Speaker
10 Ω
R2
D3
D4
I/O Connector
NZMM7V0T4
Figure 13b
Figure 13. Bridge Tied Load (BTL) Audio Power Amlifier (13a) with Remote Speaker (13b)
Key
VCC
R1
D1
Encoder
D2
Key
VCC
R2
D4
D3
Key
VCC
R3
D6
D5
NZMM7V0T4
Figure 14. Keypad Application
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4 Bit Key Code
AND8026/D
R1
D1
D2
R2
D3
To Remote
Transceiver
D4
I/O Connector
R3
D5
Digital Logic
Transceiver
D6
NZMM7V0T4
Figure 15. Digital Application where the
NZMM7V0T4 Protects a Logic Transceiver
VCC
NZMM7V0T4
R1
D1
D2
Amplifier
+
–
R2
D3
D4
Figure 16. Microphone Amplifier Application
IN1
VCC
OUT1
IN2
OUT2
Figure 17. NTZMM7V0T4’s Zener Diodes
Protect a USB or RS232 Serial Port
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Bibliography
4. Ott, Henry W., Noise Reduction Techniques in
Electronic Systems, Second Edition, New York, Wiley
& Sons, 1988.
5. Terrell, David L. and Keenan, R. Kennan, Digital
Design for Interference Specifications, Second Edition,
Boston, Newnes, 1997.
1. Gerke, Daryl and Kimmel, Bill, “The Designer’s
Guide to Electromagnetic Compatibility,” EDN,
January 20, 1994.
2. Lepkowski, Jim, Application Note: “AND8027: Zener
Diode Based Integrated Passive Device Filters, An
Alternative to Traditional I/O EMI Filter Devices,” ON
Semiconductor, September, 2000.
3. Lindquist, Claude, Active Network Design with Signal
Filtering Applications, Long Beach, Steward & Sons,
1977.
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AND8026/D
Appendix I
Listed below is the documentation on the test PCB
that was used to evaluate the NZMM7V0T4.
PIN18
PIN19
PIN20
PIN21
PIN24
PIN23
PIN22
ON8471–0
PIN1
PIN3
PIN4
PIN17
PIN16
PIN5
PIN6
PIN15
DUT1
PIN14
PIN12
PIN8
PIN11
PIN9
PIN10
PIN7
PIN13
Figure A2: PCB Solder Side
Figure A1: PCB Component Side
Note: Dashed circles are ground connections and solid circles
are signal connections
Note: Connector Part Number: AMP414026–3
2825 MILS
X
ON8471–0
X
X
X
X
X
Y
X
Y
X
X
X
X
Y
X
X
X
X
Y
X
X
X
X
X
X
X
V
V
X
X
X
X
X
X
SYM
V
W
X
Y
Z
PLTD
PLTD
PLTD
PLTD
PLTD
PLTD
3000 MILS
Y
X
V
X
X
X
4 LAYER STRUCTURE
Y
X
X
X
X
X
X
X
X
Y
X
X
X
Y
X
X
X
X
Y
X
X
0.008
X
0.062
0.008
X
SCALE: NONE
DETAIL A–A
Y
X
X
ÇÇÇÇ
ÇÇÇÇ
ÇÇÇÇ
X
Y
Y
X
X
V
W
Y
X
X
QTY
4
1
72
18
5
Y
Y
X
X
X
X
X
X
X
Z
MATERIAL FR–4 0.062 FINISHED
DISTANCE BETWEEN LAYER CRITICAL
SOLDERMASK LPI GREEN
DISTANCE BETWEEN LAYERS SHALL
MEET IPC 600 D
SIZE
15
14.96
60
50
37
Y
Y
X
X
Z
X
X
X
Y
Z Z Z
X
1.
2.
3.
4.
X
Figure A3: PCB Drill Plot
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14
COMPONENT SIDE
2 oz. copper
GND PLANE
1 oz. copper
GND PLANE
1 oz. copper
SOLDER SIDE
2 oz. copper
AND8026/D
Notes
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15
AND8026/D
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AND8026/D