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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
ANE012 // OLAN TSAI
1 Introduction
The function of a RF (Radio Frequency) transmission line is a directing RF signal from a source to a load with minimal loss and distortion. Impedance
plays an important role in signal transmission. Even if the trace impedance already matches, adding a connector can cause an impedance mismatch
and thus signal distortions due to reflections. The purpose of this application note is to outline methods for improving signal transmission when a
connector is added on a PCB.
1.1. Impedance
Impedance matching determines the transmission line performance. Characteristic impedance of a standard transmission line is expressed as:
Z
0
=
R+j
ω
L
G+j
ω
C
According to the formula above, the main factors include: R(resistance per meter), L(inductance per meter), C(capacitance per meter), G(conductance
per meter), and last but not least the angular frequency ω.
1.2. Types of RF Transmission line on PCB
Applications define the selection of suitable types of transmission lines:
Embedded Strip Line
There are ground planes above and below, and the
dielectric around the trace is homogeneous.
Microstrip Line
The dielectric material above the trace is different from that
below the trace. There must be a gound plane below the
trace, while a grould plane above the trace may be omitted.
Commonly applied on test PCBs.
Coplanar Waveguide with
Ground
The complanar wave guide basically consists of the signal
trace with the two adjacent GND traces on the left and right.
Additionally there might be a ground under the coplanar
waveguide to reduce the parasitic discontinuities. This
structure is common use in applications that need to
connect to a RF connector or an antenna. The ground plane
additionally helps to shield the transmission line against
parasitic couplings to close metal objects.
Figures 1 to 3 Types of RF transmission lines
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PCB-Transmission Line Design Guide
Application Note
2 RF Transimission Line Design Parameter _________________________________________
The coplanar waveguide with ground is typically found on PCBs with a coaxial connector; therefore, we use this RF transmission line as example.
Figure 4: Coplanar waveguide
Factors that determine the PCB transmission-line characteristic impedance are:
ε
r
Dielectric constant of the substrate
W
Conductor width
H
Substrate hight
T
Conductor thickness (copper thickness)
D
Distance of the signal conductor to the coplanar ground strips
r
Dielectric constant of the coating (solder resist)
Table 1: Influencing factors on characteristic impedance
Suggested design flow for a RF transmission line is as follows:
a) Select the PCB substrate.
For example: FR1, FR4, CEM1…etc.
b) Define the PCB’s properties:
ε
r
: Substrate dielectric constant
H: Substrate height
T: Trace thickness
Cε
r
: Coating dielectric constant
c) Control and adjust the value of W and D to reach the required characteristic impedance.
d) If step (c) cannot be achieved, please return to step (b) to select a different substrate height and trace thickness. Return to (a)
when the newly selected properties in step (b) still cannot achieve the desired impedance.
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
3 Relationship for Each Parameter with Characteristic Impedance ________________________
It is important to understand how each factor influences the transmission line.
Each paragraph below indicates how the characteristic impedance will change when only one of these factors is adjusted.
3.1. ε
r
- Substrate Dielectric Constant
Many different types of materials can be used as PCB substrate. Each substrate has its own dielectric constant. The user needs to be aware ofPCB
Material Dielectric Constant given by manufacturers.
On the other hand, material dielectric constant will vary not only between vendors but with the frequency, too.
PCB Type
Dielectric Constant
FR-1
5.5-6
FR-4
4.2-4.7
CEM-1
4.6
CEM-3
5.0
Table 2: Dielectric constants for common PCB materials
Figure 5: This figure shows impedance (Z
0
) is inversely proportional to dielectric constant (ε
r
)
40
45
50
55
3 3,2 3,4 3,6 3,8 4 4,2 4,4 4,6 4,8 5
Impedence (Ω)
Dielectric Constant, ε
r
Characteristic Impedance v s. Substrate Dielectric Constant
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PCB-Transmission Line Design Guide
Application Note
3.2. W
- Trace Width
For trace width design, the user needs to consider four things:
1) Narrow traces are more difficult to control
2) Wider traces need more space on the PCB.
3) Actual trace width may not be as designed due to manufacturing tolerance.
4) Because the wave impedance and the height of the dielectric material is fixed, these parameters will decide the trace width.
Figure 6: This figure shows impedance (Z
0
) is roughly inverse-proportional to trace width
3.3. H
- Substrate Height
The substrate height is the distance between the ground and signal layer of a PCB. The characteristic impedance reduces if the copper layers are
closer together and the other parameters are fixed. To maintain the impedance of the trace, the trace width can be reduced. This in turn saves space
on PCB. But please note, if narrower tracks are used, the tolerance of the impedance will be greater due to the undercutting during manufacturing
process!
Figure 7: Impedance (Z
0
) increases more slowly when substrate height is at specific distance
40
45
50
55
60
0,5 0,55 0,6 0,65 0,7 0,75 0,8 0,85 0,9 0,95 1
Impedence (Ω)
Trace Width (mm)
Characteristic Impedance vs. Trace Width
30
35
40
45
50
55
0 1 2 3 4
Impedence (Ω)
Subtrate Height (mm)
Characteristic Impedance vs. Substrate Height
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PCB-Transmission Line Design Guide
Application Note
3.4. T
- Trace Thickness (height of the copper layer)
Copper is commonly used as the PCB metal layer in layer heights of 0.5 oz/ft
2
(0.017mm), 1 oz/ft
2
(0.035mm) or 2 oz/ft
2
(0.070mm). The characteristic
impedance reduces, if the Cu copper thickness (height of the copper layer) is increased.
Figure 8: Impedance (Z
0
) is roughly inverse-proportional to the trace thickness (height of the copper layer)
3.5. D
- Distance between Trace and Coplanar Ground
This factor is very sensitive. It can influence the impedance by 1~2 with only 0.01 mm variation, hence the PCB manufacturing precision needs to
be checked when doing this adjustment.
Figure 9: Impedance (Z
0
) is roughly proportional to the distance between trace and coplanar ground
20
30
40
50
60
0 0,01 0,02 0,03 0,04 0,05 0,06 0,07 0,08
Impedence (Ω)
Trace Thickness (height of the copper layer) (mm)
Characteristic Impedance vs. Trace Thickness (height of the copper layer)
35
40
45
50
55
60
0,09 0,11 0,13 0,15 0,17 0,19 0,21
Impedence (Ω)
Distance between Trace and Ground (mm)
Characteristic Impedance vs. Distance between Trace and Coplanar Ground
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
3.6. Cε
r
- Coating Dielectric Constant
The coating material’s permittivity also has an influence on characteristic impedance. It should be considered early in the design stage in order to avoid
deviation from calculated values.
Figure 10: Impedance (Z
0
) is roughly inverse-proportional to the coating dielectric constant
4 Connector Pin Contact to PCB
When the connector center pin is connected to the PCB trace, it adds a certain height on top of the PCB trace due to its defined size. This height
creates a discontinuity and should be fixed by adjusting the trace width on PCB.
4.1. End Launch Round Post Pin
Figure 11: Round post connectors have a larger center pin
which creates significant discontinuity after soldering.
To match with the “microstrip line”, the trace width needs to be changed to fit with the round post pin.
49,5
50
50,5
51
51,5
3,1 3,3 3,5 3,7 3,9 4,1 4,3
Impedence (Ω)
Coating Dielectric Constant, Cε
r
Characteristic Impedance vs. Coating Dielectric Constant
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PCB-Transmission Line Design Guide
Application Note
Figure 12: Example of modify the trace shape to improve matching.
If the impedance value is too low from the ideal matching impedance, try to use the shape shown on the left side of figure 12. The trace width
near the connector center pin must be reduced. Making the trace width narrower at the end will make a better match.
For a coplanar waveguide, the impedance value can be increased by increasing the distance between the trace and its coplanar ground (GND). It is
also possible to reach the ideal impedance by reducing the width of signal trace.
Figure 13: Example of increase the gap distance to improve impedance matching.
Round Post Pin Solder Area
Increase Gap Distance
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
4.2. End Launch Flat Tab Pin
This connector usually has a smaller center pin and has less influence on impedance discontinuity after soldering. When the flat pin makes the
impedance lower, it can be raised by reducing the width of trace or increasing the gap distance between trace and its coplanar ground (GND).
Figure 14: End Launch Flat Tab Pin
Figure 15: Example of reduced trace width to improve impedance matching
4.3. THT Pin & SMT Pin
THT and SMT connectors are more difficult to reach the ideal match. This is often caused by the gap after the connector is soldered on to PCB. The
gap will make the impedance value higher.
Figure 16: Gap between PCB and connector
Furthermore, THT and SMT connectors that are perpendicular to the trace on PCB which make the impedance lower. For THT center pin, the extended
connector legs will make the impedance value lower. Impedance discontinuity occurs over a very short distance for THT and SMT connectors, which
is more difficult to fix by adjusting the traces on PCB.
THT and SMT connectors are normally not used in very high-frequency products, because of impedance matching issues.
Reduce trace width
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
How the signal is routed from a THT connector changes the impedance.
Figure 17: Signal route: Connector interface PCB trace
Figure 18: Impedance in time domain
1. Gaps make the impedance higher
2. Vertical area and extended center contact make the impedance lower
How the signal is routed from a SMT connector changes the impedance.
Figure 19: Signal route: Connector interface PCB trace
Figure 20: Impedance in time domain
1. Gaps make impedance higher
2. Vertical area makes impedance lower
42
44
46
48
50
52
54
56
Impedance(
Ω)
Time
Impedance Vary
34
36
38
40
42
44
46
48
50
52
54
56
58
Impedance (
Ω)
Time
Impedance Vary
Extended center contact
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
Figures 17 to 20 show the impact of the connector construction and its connections to the PCB in the time domain. It was measured with a time-
domain reflectometer (TDR) which determines the impedance of the measured construction by observing the reflected waveform. The change of the
impedance over time can be recalculated via ε
r
to the point of reflection.
How to Improve:
1) Gaps make the impedance higher: Use solder paste to fill up gaps to improve the impedance.
Figure 21: Use solder paste to fill up gaps
2) Vertical area makes the impedance lower: Increase the gap between the contact pin and the GND to reduce the impedance
Figure 22: Layout modification to improve the matching
3) Extended connector legs make the impedance lower:
Extended connector legs not only make the impedance value lower, they might also cause an antenna effect. Methods to solve this are:
Select the connector pin length to better match PCB thickness.
Cut long legs for a significant improvement.
Gap between solder area and ground
Solder Area
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
5 Other factors affecting the impedance
Following a few points that will influence the transmission line impedance when making a PCB:
5.1. PCB cut Line(End Launch Coaxial Connector Issue)
PCB routing tolerances occur during PCB production. If the ground layer does not extend to end of the PCB, the PCB routing tolerance might cause a
gap between PCB and the connector which will cause an impedance discontinuity.
Figure 23: Ground not extended to end of the PCB
Figure 24: After soldering the connector, a gap exist without ground
We would suggest extending the ground layer on the connector side to the edge. If PCB routing tolerances issues occur, there will be no gap after the
connector is soldered to the PCB
Figure 25: Extended ground to the end of the PCB
PCB cut-line
Existing gap to cause
the impedance
Real situation after
routing the PCB
PCB cut-line
Existing gap but the area is
still in ground
Real situation after
routing the PCB
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
5.2. PCB Trim Line (End Launch Edge Card Coaxial Connector Issue)
The PCB routing cannot cut a sharp right angle and the round corners might cause a gap between the connector and the PCB. Because they could
not meet closely this causes an impedance discontinuity (figure 25). To fix this, we suggest using Ø0.6-2 mm relief holes in the corners in order to
remove the corner radius, as displayed in figure 26.
Figure 25: Round corners cause poor mechanical matching of the connector
Figure 26: additional holes improve the fit of the connector
5.3. End Launch Connector and the Backside of a PCB
When an end launch connector is placed on a PCB, if the copper layer is not extended to the PCB edge, there would be a small gap in between. Use
of solder paste to fill up the gap can be helpful to impedance control (figure 27).
Figure 27: Use solder paste to fill up the gap
Round Corners
Drilled Holes
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PCB-Transmission Line Design Guide
Application Note
5.4. Via Hole
When using a coplanar waveguide design, it is suggested to add some via holes to the coplanar GND surrounding the trace, as shown in figure 28.
The via holes connect the upper traces and the bottom layer which is the ground layer. Depending on the highest signal frequency, the vias should
have a distance of not more then 2 4 mm to make sure, that the coplanar GND-traces keep their GND potential
Figure 28: Via implementation from the coplanar ground traces to the ground (GND) layer
6 Simulation Examples
60312202114509
PCB End Launch Jack Round Post for 1.6mm PCB
Figure 29: Original Design
Figure 30: Matching Design
Increase the gap between trace and ground to increase the impedance and reach impedance matching
Via Hole
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
Result of TDR measurement (Original Design):
Figure 31: Result of TDR measurement (Original Design)
Result of TDR measurement (Matching Design):
Figure 32: Result of TDR measurement (Matching-Design)
Lower impedance in the
area of contacting
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
Result of S-Parameter measurement (Original Design):
Figure 33: Result of S-Parameter VSWR measurement (Original Design)
Figure 34: Result of S-Parameter - Return Loss measurement (Original Design)
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Coaxial PCB Connector
PCB-Transmission Line Design Guide
Application Note
Result of S-Parameter measurement (Matching Design):
Figure 35: Result of S-Parameter - VSWR measurement (Matching Design)
Figure 36: Result of S-Parameter Return Loss measurement (Matching Design)
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PCB-Transmission Line Design Guide
Application Note
7 Conclusion
Simulation software is very useful when designing a transmission line, Software like AppCAD, for example, can simulate transmission lines with different
factors. Using the result from AppCAD, software like HFSS can provide full-wave simulations, including both connector and PCB. Overall, using
simulation software can save a lot of time.
Knowing the preciseness of PCB production will also help the user design a transmission line because most transmission lines are very narrow. If the
PCB has wide tolerances from production, the user’s test results will have huge difference compared to software simulations. Sometimes, roughness
of copper layer is a factor that affects impedance of transmission line.
The quality of a transmission line is one part of transmission quality in a product. Users now should understand how to enhance transmission line
quality after reading through these suggestions
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PCB-Transmission Line Design Guide
Application Note
IMPORTANT NOTICE
The Application Note is based on our knowledge and experience of
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guidance and should not be construed as a commitment for the
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Co. KG. The information in the Application Note is subject to change
without notice. This document and parts thereof must not be reproduced
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