AN414: EZRadioPRO® Layout Design Guide

AN414
EZR ADIO P R O ® L AYOUT D ESIGN G UIDE
1. Introduction
The purpose of this application note is to help users design EZRadioPRO® PCBs using design practices that allow
for good RF performance. This application note also help designers by separating TX and RX concerns.
The RF performance and the critical maximum peak voltage on the output pin strongly depend on the PCB layout
as well as the design of the matching networks. For optimal performance, Silicon Labs recommends the use of the
PCB layout design hints described in the following sections.
2. Design Recommendations when Using EZRadioPRO RF ICs

Extensive testing has been completed using reference designs provided by Silicon Labs. It is recommended to
designers to use the reference designs “as-is” since they minimize detuning effects caused by parasitics,
component placement, and PCB routing.
 When layouts cannot be followed as shown by the reference designs (due to PCB size and shape limitations),
the following layout design rules are recommended.
2.1. Guidelines for Layout Design when Using the Si4430/31
The Si4430/31 devices use a Class-E type TX matching network with a typical output power level of +13 dBm at
VDD = 3.3 V. Two basic types of board layout configurations exist at all frequency bands: the Split TX/RX type and
the Direct Tie type. In the Split TX/RX type, the TX and RX paths are separated, and individual SMA connectors are
provided for each path. In the Direct Tie type, the TX and RX paths are connected together directly, without any
additional RF switch. The operating principle of both types and the reference designs with element values are
given in “AN436: Si4030/4031/4430/4431 PA Matching” for wirewound and multilayer type 0402 size SMD
inductances as well.
The Split and Direct Tie type boards have slightly different PCB layouts, which are described in separate sections.
2.1.1. Split Type Matching Network Layout Based upon the 4431-T-B1_B Test Card
(Separate TX and RX Paths with Two Antennas)
Examples shown in this section of the guide are based upon the layout of the 4431-T-B1_B test cards. These cards
contain two separate antennas for the TX and RX paths. This type of test card is best suited for demonstrating the
output power and sensitivity of the EZRadioPRO RFICs. For this purpose, the TX and RX path layouts are
separated and isolated as much as possible to minimize the mutual coupling effects. This type of test card is
recommended for laboratory evaluation and not for range tests because the presence of two closely-spaced
antennas may cause “shadowing” when receiving a radiated signal.
The main layout design concepts are reviewed through this layout to demonstrate the basic principles. However,
for an actual application, the layouts of the test cards with a single antenna (or with antenna diversity) should be
used as references. The schematic of the Split type matching network for Si4431 RevB1 is shown in Figure 1.
Rev. 0.2 12/10
Copyright © 2010 by Silicon Laboratories
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Figure 1. Schematic of the Split Type Matching Network for the Si4431 RevB1
The layout structure of the Split type matching network is shown in Figure 2.
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Ground TX Section Metallization
RX Section VDD Filter Capacitors PCB Vias Crystal RF IC Figure 2. Split Type Matching Network Layout Structure
2.1.2. Layout Design Guidelines
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


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The choke inductor (LC) should be placed as close to the TX pin of the RF IC as possible (even if this means
the RX is further away).
The parallel inductor in the RX path (LR) should be perpendicular to the choke inductor (LC) in the TX path
because this will reduce TX-to-RX coupling.
The TX and RX sections should be separated by a GND metal on the top layer to reduce coupling.
The neighboring matching network components should be placed as close to each other as possible in order to
minimize any PCB parasitic capacitance to ground and the series parasitic inductances between the
components.
Increase the grounding effect in the thermal straps used with capacitors. In addition, thicken the trace near the
GND pin of these capacitors. This will minimize series parasitic inductance between the ground pour and the
GND pins. Additional vias placed close to the GND pin of capacitors (thus connecting it to the bottom layer GND
plane) will further help reduce these effects.
Figure 3 illustrates the positioning and orientation of the LC and LR components, the separating GND metal
between the TX and RX sections, and thermal strapping on the shunt capacitors.
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Thermal PCB Straps on Capacitors
LR LC Thermal PCB Straps on Capacitors
GND Metal between the TX and RX Sides TX Pin Figure 3. Si4331 Component Orientation, Placement, and GND Metallization

Nearby inductors of the TX path should be kept perpendicular to each other to reduce coupling between stages
of the low-pass filter and match. This helps to improve filter attenuation at higher harmonic frequencies.
 Use at least 0.5 mm separation between traces/pads to the adjacent GND pour in the areas of the matching
networks. This minimizes the parasitic capacitance and reduces detuning effects.
Figure 4 illustrates the orientation of the inductors of the TX path and the separation of the matching network
traces/pads from the GND metal.
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Separation of Traces from GND
LM2 LM L0 LC Figure 4. TX Side Inductor Orientation, Thermal Strapping, and Separation from GND

The smaller VDD bypass capacitors (C1 = 33 pF and C2 = 100 pF) should be kept as close to the VDD pin as
possible.
 The exposed pad footprint for the paddle of the RF IC should use as many vias as possible to ensure good
grounding and heatsink capability. In the reference designs, there are nine vias, each with 12 mil diameter. The
paddle ground should also be connected to the top layer GND metal (if possible) to further improve RF
grounding; this may be accomplished with diagonal trace connections through the corners of the RFIC footprint.
 The crystal should be placed as close as possible to the RFIC to ensure that wire parasitic capacitances are
kept as low as possible; this reduces any frequency offsets that may occur.
 Place ground metal between the crystal and the VDD trace to reduce coupling effects.
Figure 5 illustrates the grounding of the RFIC, the crystal, and VDD filter capacitor positions, and the isolating
ground metal between the VDD trace and the crystal.
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VDD Pin
C2 C1 GND Metal between the Crystal and VDD
Connection to GND through more vias Crystal Figure 5. RFIC GND Vias and GND Metallization

To achieve good RF ground on the layout, it is recommended to add large, continuous GND metallization on the
top layer in the area of the RF section (at a minimum). Better performance may be obtained if this is applied to
the entire PCB. To provide a good RF ground, the RF voltage potentials should be equal along the entire GND
area because this helps maintain good VDD filtering and provides a good ground plane for a monopole
antenna. Ideally, gaps should be filled with GND metal, and the resulting sections on the top and bottom layers
should be connected with as many vias as possible.
 The area under the matching network (on the bottom layer) should be filled with ground metal because this
helps reduce or eliminate radiation emissions. Board routing and wiring should not be placed in this region to
prevent coupling effects with the matching network. It is also recommended that the GND return path between
the GND vias of the TX LPF/Match and the GND vias of the RFIC paddle should not be blocked in any way; the
return currents should see a clear unhindered pathway through the GND plane to the back of the RFIC.
Figures 6 and 7 illustrate the GND metal filled sections on the entire 4431-T-B1_B test card PCB. The top and
bottom layers are shown.
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Figure 6. Ground Poured Sections with PCB Vias around the Matching Network (Top Layer)
Figure 7. Ground Poured Sections with PCB Vias (Bottom Layer)
Rev. 0.2
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
To reduce sensitivity to PCB thickness variation, use 50  grounded coplanar lines wherever possible to
connect the SMA connector(s) to the matching network and/or the RF switch. This also reduces radiation and
coupling effects. The interconnections between the elements are not considered transmission lines because
their lengths are much shorter than the wavelength and, thus, their impedance is not critical. As a result, their
recommended width is the smallest possible (i.e. equal to the width of the pad of the applied components). In
this way, the parasitic capacitances to ground can be minimized. In the case of the 4431-T-B1_B type test card,
the only routes where 50  coplanar transmission line is used are between the output of the matching networks
and the SMA connectors. Examples for the trace dimensions are shown in Table 1.
Figure 8 illustrates the 50  grounded coplanar line of the TX side on the 4431-T-B1_B test cards.
Figure 8. 50  Grounded Coplanar Line on 1.5 mm Thick Substrate
Table 1. Parameters for 50  Grounded Coplanar Lines
f
240−960 MHz
T
0.018−0.035 mm
Er
4.6
H
1.5 mm
0.26 mm*
G
0.25 mm
0.64 mm
W
1.26 mm
0.45 mm
*Note: For four-layer PCBs, the thickness between the top and the next inner layer should
be taken into account.
Figure 9. Grounded Coplanar Line Parameters
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2.1.3. Direct Tie Type Matching Network Layout Based upon the 4431-T-B1_D Test Card
(Single Antenna without RF Switch)
For reference, layout examples shown in this section are based upon the layout of the 4431-T-B1_D RF test cards.
These boards contain a single antenna, and the TX and RX paths are connected directly together, without the use
of an RF switch.
The schematic of the Direct Tie type matching network is shown in Figure 10. For this type of matching, an
additional inductor is necessary at the RX side, forming a four-element RX matching network (described in “AN436:
Si4030/4031/4430/4431 PA Matching”).
During TX mode operation, the built-in LNA protection circuit should be enabled by setting the lna_sw bit of the TX
Power register 6Dh to “1” (see “AN440: Si4430/31/32 Register Descriptions”). In this case, the dc path from the
output of the matching network to GND is not blocked through the RX side; so, a dc blocking capacitor (CC1) is
necessary.
In the case of Direct Tie type matching, coupling between the RX and TX sides is not critical since no harmonic
leakage through the coupled RX path occurs; both of them are filtered after the common connection point.
Figure 10. Schematic of the Direct Tie Type Matching Network
Rev. 0.2
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2.1.4. Layout Design Guidelines
The principles in this case are the same as for Split type matching, except for the following issues:

To minimize the parasitics (i.e., the length) of the trace connecting the RX and TX sides, the RX side
components are closer to the TX side components. Also, because of this, the nearby inductors are not
perpendicular to each other.
 The trace parasitics are very critical for the connection of LR2; so, the shortest traces possible should be used
for connecting LR2 to the TX side.
 Since the RX-TX coupling is not critical, there is not any separating GND metal between the two sides.
Figure 11 illustrates the positioning and orientation of components and ground pour flooding.
Ground Metallization DC Blocking Capacitor TX Section RX Section L0 LR2 LC LR TX Pin Figure 11. Direct Tie Matching Network Layout Structure
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2.2. Guidelines for Layout Design when Using the Si4432
For the versions of RF test cards using the Si4432 RFIC (i.e., +20 dBm PA), similar general layout guidelines can
be applied as described for the Si4431 RFIC (i.e., +13 dBm PA). However, some minimal additional filtering and
circuitry must be implemented.
The increased TX output power of the Si4432 chip is accompanied by a corresponding increase in the absolute
level of harmonic signals. Since most regulatory standards (e.g. FCC, ETSI, ARIB, etc.) require the harmonic
signals to be attenuated below some absolute power level (in watts or dBm), the amount of low-pass filtering
required is generally greater on an RF test card using an Si4432 chip. Thus, the RF test card layout for the Si4432
RFIC may contain a slightly higher number of components in the L-C lowpass filter.
Further, due to the increase in output power, it is necessary to pay closer attention to the shape and amplitude of
the voltage waveform at the TX output pin of the device. Silicon Labs recommends that a harmonic termination
circuit be placed in a parallel shunt-to-GND configuration at the input of the lowpass filter. This harmonic
termination circuit helps maintain the desired voltage waveform at the TX output pin by providing a good
impedance termination at very high harmonic frequencies. For further information on this subject, refer to “AN435:
Si4032/4432 PA Matching”.
Unlike the Si4431, the test cards for the Si4432 are manufactured on a four-layer PCB. The purpose of this is to
allow most traces to be placed on the inner layers while the outer layers function as shields for further reduction of
the radiated levels of harmonics.
2.2.1. Switch Type Matching Network Layout Based upon the 4432-T-B1_C Test Card
(Single Antenna with RF Switch)
For reference, examples shown in this section are based upon the layout of the 4432-T-B1_C RF test cards. These
boards contain a single antenna and an RF switch to select between the TX and RX paths. The schematic of the
Switch type matching network for the Si4432 RevB1 is shown in Figure 12.
Figure 12. Schematic of the Switch Type Matching Network for the Si4432 Rev B1
Rev. 0.2
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2.2.2. Layout Design Guidelines

When using a TX/RX switch, or a switch to select antennas in an antenna diversity implementation, a series
capacitor may be required on all ports (e.g., TX, RX, Antenna) of the switch to block the dc patch between the
switch and the ground. Refer to the exact requirements and specifications of the switch used in the application.
 RF switches may themselves behave in a slightly non-linear fashion, resulting in some re-generation of
harmonic energy regardless of the cleanliness of the input signal to the switch. Thus it may be necessary to
move a portion of the TX lowpass filter to after the RF switch (i.e., just prior to the antenna) in order to further
attenuate these re-generated harmonic signals.
 If the RX side matching network is relatively far from the RF switch then the connecting trace should be a 50?
grounded coplanar line.
 The area between the RX and TX sides should be filled with GND metal to increase the isolation (just as in case
of the Split type design).
Figure 13 demonstrates the positioning and orientation of components, ground flooding, and thermal strapping.
Filter Section after the RF Switch DC Blocking Capacitors RF Switch Filter Section before the RF Switch 50 Ohm Grounded Coplanar Line for 0.26 mm Substrate Thickness Harmonic Termination Circuit Isolating GND Metal Figure 13. Si4432 Switch Type Matching, Component Orientation,
Placement, and GND Metallization
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The return path to GND of the harmonic termination circuit is important. This trace and current path should be kept
as short as possible and should be allowed to return directly to the GND paddle of the RFIC; it should be connected
to the GND metal only at that point. Also, to avoid coupling with the matching network itself, it should be routed on
the second inner layer under the matching network, not on the first one (the first inner layer should be filled with
ground metal under the matching network). Figure 14 demonstrates the dc return path of the harmonic termination
circuit.
Harmonic Termination Circuit DC Return Trace of the Harmonic Termination Circuit on the Second Inner Layer Isolation from the Rest of the GND Connect to GND under the Paddle of the RF IC Figure 14. DC Return Path on the Second Inner Layer
(The First Inner Layer under the Top One is Suppressed)
2.2.3. Diversity Type Matching Network Layout Based upon the 4432-T-B1_A Test Card
(Two Antennas with RF Switch)
The purpose of this type of test card is to demonstrate the Antenna Diversity feature of the EZRadioPRO RFICs.
Antenna diversity is often used to provide better range in case of an obstructed environment where the range with
a single antenna board configuration is lessened due to multipath fading and/or different RX antenna and TX field
polarizations.
Multipath fading causes nulls in the radiated field of the TX with 1/2 wavelength period. To compensate for this, the
separation distance of the antennas should be around 1/4 wavelength.
If the polarization of the radiated field is not parallel with the RX antenna, either because of the different
polarization of the TX antenna or the polarization changes caused by reflections, then positioning the RX antennas
perpendicular to the each other can help. (Refer to “AN379: Antenna Diversity with EZRadioPRO®” for further
information on this subject.)
As with the Switch type matching network, a portion of the TX lowpass filter (LPF) should be placed after the RF
switch to further attenuate any harmonics regenerated by the switch. Since, in this case, transmission is possible
on both antennas, the portion of the LPF should be inserted into both paths.
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The schematic of the Diversity type matching network is shown in Figure 15.
Figure 15. Schematic of the Diversity Type Matching Network
2.2.4. Layout Design Guidelines

As discussed above, the distance between the two antennas on a Diversity type layout should be approximately
1/4 wavelength (on the 4432-T-B1_A test card, it is true for the higher ISM bands i.e. for 868/915 MHz), and the
antennas should be perpendicular to each other.
 If the antennas must be closer than 1/4 wavelength (due to PCB size) it is important to position them
perpendicularly not only to compensate the polarization diversity but to minimize their effect on each other.
Figure 16 demonstrates antenna orientations and distances on the 4432-T-B1_A test card.
Distance of the antennas ~1/4 wavelength at HB 90° Figure 16. Antenna Orientations and Distance on the 4432-T-B1_A Test Card
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3. Available Manufacturing Packs
Table 2 contains a partial list of the reference design packs available for download on www.silabs.com.
Table 2. Available Manufacturing Packs
Part Number
Frequency
[MHz]
Antenna Configuration
4031-T-B1 B 434
434
Single antenna
4031-T-B1 B 868
868
Single antenna
4032-T-B1 B 470
470
Single antenna
4032-T-B1 B 915
915
Single antenna
4330-T-B1 B 434
434
Single antenna
4330-T-B1 B 470
470
Single antenna
4330-T-B1 B 868
868
Single antenna
4330-T-B1 B 915
915
Single antenna
4330-T-B1 B 950
950
Single antenna
4430-T-B1 B 950
950
Separate TX and RX designed for lab testing
4430-T-B1 D 950
950
Single antenna implemented without RF switch
4431-T-B1 B 434
434
Separate TX and RX designed for lab testing
4431-T-B1 D 434
434
Single antenna implemented without RF switch
4431-T-B1 B 868
868
Separate TX and RX designed for lab testing
4431-T-B1 D 868
868
Single antenna implemented without RF switch
4432-T-B1 B 470
470
Separate TX and RX designed for lab testing
4431-T-B1 C 470
470
Single antenna implemented with RF switch
4431-T-B1 D 470
470
Single antenna implemented without RF switch
4431-T-B1 B 915
915
Separate TX and RX designed for lab testing
4431-T-B1 C 915
915
Single antenna implemented with RF switch
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4. Checklist
4.1. Main Layout Design Principles
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1
Is the choke inductor (LC) as close to
the TX pin as possible?
2
Is the RX parallel inductor (LR) perpendicular to the choke inductor (LC)
in the TX path? (except for the Direct
Tie type matching)
3
Is the TX and RX separated by a
ground metal on the top layer?
(except for the Direct Tie type matching)
4
Are the neighboring matching network components as close to each
other as possible?
5
Are there more thermal straps used
with the capacitors?
6
Are the TX path inductors
perpendicular to each other?
7
Is there at least 0.5 mm separation
in the matching between the
traces/pads and the GND metal?
Rev. 0.2
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8
Are the smallest value VDD filter
capacitors kept closer to the VDD
pin of the RF IC?
9
Does exposed pad footprint use
more vias?
10
Is the crystal as close to the RF IC
as possible?
11
Does ground metal exist between
the crystal and the VDD feed?
12
Was large, continuous GND
metallization added to at least the
RF sections?
13
Was the area on the bottom layer
under the matching network filled
with GND metal and was wiring and
routing avoided in this region?
14
Were 50  grounded coplanar lines
used for connecting the matching
network, the switch and/or the SMA
connector(s)?
Rev. 0.2
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4.2. Additional Concerns for Direct Tie Matching
18
15
Is the length of the trace
connecting the RX and TX sides
minimal?
16
Is LR2 connected with as short
traces as possible?
17
Is an additional dc blocking
capacitor added to the output of
the matching network to block the
dc path in RX mode?
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4.3. Additional Concerns for the Si4432 and the Switch and Diversity Type Matching
18
Was the additional harmonic
termination circuit is added into
the TX path?
19
Were series capacitors added to
the TX path to block the dc when
a TX/RX switch (or Diversity
switch) is used?
20
Was 50  grounded coplanar line
used for connecting the RX side
matching to the RF switch (if they
are far from each other)?
21
Was the area between the RX
and TX sides filled with GND
metal?
22
Was the dc return path of the
harmonic termination circuit
constructed properly?
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23
Are the antennas perpendicular
to each other?
24
Is the distance of the antennas
approximately 1/4 wavelength?
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DOCUMENT CHANGE LIST
Revision 0.1 to Revision 0.2

Updated to latest reference designs
Rev. 0.2
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