Coupled_Microstrip_Filters_Characteristics.pdf

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Coupled Microstrip Filters:
Simple Methodologies for Improved Characteristics
Kamaljeet Singh, R. Ramasubramanian, S. Pal
Communication Systems Group, ISRO Satellite Center, Bangalore, India
kamaljaz@yahoo.co.in
Abstract:
This paper presents improved characteristics of the hairpin filter topology. Standard hairpin
configuration has the drawback of broader bandwidth, more insertion loss along with poor skirt rate.
This paper demonstrates the approach to overcome the limitation inherent in hairpin as well as
suppression of the harmonic which is prominent in the microstrip coupled filter topology. This has been
achieved using the concept of the Q involved along with the compensation of the phase velocity. The
modified topologies of the hairpin along with the concept of transmission zeros for better skirt rate has
been explained in this paper. Furthermore, presented topologies are insensitive to parameter variations
and standard design equations can be used. The band pass filter topologies were designed at the center
frequency of 1.24 GHz, aimed to be part of the multiplier chain, in satellite communications.
Keywords: Hairpin filter, Q factor, coupled lines, even and odd mode
Introduction:
Filters are essential in the RF front end of microwave and wireless communication systems. Parallel
coupled topology proposed by Cohn is the most commonly used filter. Several configurations like
stepped impedance filter, open stub filter, semi lumped filter, parallel coupled filter, inter digital filter,
capacitive gap filter are widely used in microwave and millimeter wave integrated systems. These
configurations either increase the complexity of the design or having less Q. Also, all the filters
designed traditionally have a major drawback of the spurious response at twice the basic pass band
frequency (2f 0 ), which causes asymmetry in the upper and lower stop band and limits its application.
The other major constraint comes from the weak lateral coupling between the lines in the conventional
structure which causes small values of strip width and strip spacing which cannot be accurately
fabricated. These constraints are due to inhomogeneous nature of micro strip lines which results in the
inequality of even and odd mode phase velocities and also due to tight specifications resulting in
fabrication inaccuracies. This paper concentrates on the hairpin topology which was in use for so many
years, but still limitations have not been fully overcome yet. The traditional design of the hairpin
topology has the advantage of compact structure compared to edge coupled filter but wider bandwidth,
poor skirt rate due to unavoidable coupling, are the limitations in this approach. The second aspect is
the second harmonic content prominent in coupled lines. Many works have been done to tackle this
problem either providing different lengths for the even and odd modes or equalizing the modal phase
velocities. Some recently reported structures like Wiggly Line Filters [IEEE-MTT, 2001, Ref4],
Uni planar Coupled Photonic Band gap Filter [IEEE-MTT, 1999], Corrugated Coupled Micro strip
lines Filter [IEEE-MTT, 2002, Ref 2], Meandered Parallel Coupled Line Filter [IEEE-MTT,
2005, Ref 3] have been proposed, but limitations like fabrication tolerances, large size, recalculation of
design parameters, controllable phase velocities, practical realizability, and compatibility with other
circuits are the major constraint of these circuits.
So, in this paper we have shown that second harmonic content can be suppressed by modifying the
hairpin topology. This is cross-verified with the close agreement with the simulated and practical
results. The concept of Q has been explained for the first proposed topology along with reallocating the
transmission zero for better rejection characteristics has been used. The second proposed topology is
1
based on the equalization of the phase velocity. This not only gives the second harmonic suppression
but also have controllable transmission zeros which gives better attenuation rate.
1. Conceptualization for the Design
A. Concept of Transmission Zeros
The design criteria for the filter topology sometimes demand higher skirt rate. The traditional method is
to increase the number of sections. Another concept is to use cross coupling between the resonator
section along with over coupling gives controllable zero producing mechanism. The placement of zero
is determined by the polarity of the cross coupling. The Figure 2 shows the concept of the zero
producing mechanism in the case of triplet . Any realizable transfer function can be obtained by
adjusting the coupling between the resonators. The mechanism of producing improved pass band delay
or sharper filter skirt lies in the finite transmission zeros lying on the real axis. The placement of zeros
is determined by the polarity of the cross coupling. Cross coupled filter design is to reduce the coupling
matrix so that minimum number of resonators are coupled. The coupling between the resonators is
basically electric as open ends are on the same side. Figure 1 shows the cross coupling phenomena.
M12 shows the coupling between the 1 st and the 2 nd section. M23 shows the coupling between 2 nd and
3 rd section. M13 shows the coupling between 1 st and 3 rd section. This overall coupling affects the
circuit Q in the coupled resonators which can be varied. Microstrip model can predict this behavior
more accurately.
Figure 1 Cross Coupling Between Three Resonator Sections
B. Equalization of modal phase velocities
Due to inhomogeneous nature of the micro strip lines, the odd mode phase velocity is faster than the
even mode phase velocity. Mathematically it can be represented as Ȳ o< Ȳ e. This can further be written
w
w
?
w
?
eff ?
?
as for the odd mode as
b
=
;
b
=
;
q
=
;
q
=
2
p
f
e
o
o
o
V
V
V
c
0
o
o
w
w
?
w
?
b
=
;
b
?
=
;
q
?
=
e
e
e
V
V
V
e
e
e
2
917833899.021.png 917833899.022.png 917833899.023.png 917833899.024.png 917833899.001.png 917833899.002.png
Figure 2 Concept of Even/Odd Mode Current Distribution in the Coupled Line
So in the microstrip structure, because the even mode phase velocity of a microstrip coupled line is
always slower than that of the odd mode ȶ e is always larger than ȶ o for all frequencies. Therefore, the
spurious pass band of a conventional microstrip parallel coupled filter at 2f 0 occurs . This implies that
odd mode length has to be lengthened to equalize the phase velocity. To equalize the phase velocity,
the traveling path for the odd mode has to be extended. For a symmetric coupled microstrip lines,
typical current distribution of the odd and even mode is shown in Figure 2. It shows that
electromagnetic energy for the odd mode gathers around the center gap, while for the even mode, it
gathers around the outer metallic edges. So for equalization, one way is to extend the path of the odd
mode and another way is to shorten the path for the even mode. Other reported topologies are with the
use of shield, which makes the redistribution of the fields, second one involves lumped capacitors and
third one the dielectric overlay. In the proposed design, reduction in even mode is achieved by
trimming the coupled line section in the middle. This is due to the fact that odd mode transmission
phase ȶ 0 is not affected by meandering but even mode path got reduced. This makes the energy
propagation of odd mode nearer to the even mode resulting in ȶ e = ȶ 0 . This methodology gives the
harmonic suppression.
2. Hairpin Topologies
A. Design Equations for Coupled Line Filter
To design coupled band pass filter a low pass filter prototype is selected .For the required roll off five
sections are selected. Designed topology is converted into band pass using standard transformation
equations. Further lumped sections are converted into distributed elements using Richard's
transformation. The required coupling coefficient is found by equation 1[1].
f
f
K
=
l
h
-------------------------------------
(1)
f
0
and the inverter constants were found using (2),(3),(4)
p
×
K
Z
J
=
-------------------------------------
(2)
o
1
2
1
p
×
K
Z
Jn
=
----------------------------
(3)
(
)
o
2
g
×
g
n
1
n
p
×
K
Z
J
=
----------------------------
(4)
(
)
o
n
+
1
2
g
×
g
n
n
+
1
3
917833899.003.png 917833899.004.png 917833899.005.png 917833899.006.png 917833899.007.png 917833899.008.png 917833899.009.png 917833899.010.png 917833899.011.png 917833899.012.png 917833899.013.png
The g 1 ,g 2 ,g 3 .....g n are found from the filter tables. From the obtained results the even and odd
impedances are found by (5) and (6).
----------------------------
(5)
[
]
(
)
(
)
2
Z
=
Z
1
+
JZ
JZ
0
e
o
o
o
----------------------------
(6)
[
]
(
)
(
)
2
Z
=
Z
1
+
JZ
+
JZ
0
o
o
o
o
with the Z 0e and Z 0o of each section the width, spacing and length of each section is found out.
B. Design Aspect
The coupling between the resonator sections in the hairpin topology is mainly inductive. Five sections
resonator has been chosen with the given specifications. The tapping position is calculated from the
singly loaded Q of the first and the last section. It is related to the tapping position as defined by
equation (7):
Z
p
0
Q
=
------------------------------------
(7)
Ä p
?
Ô
2
R
×
2
sin
Æ
Ö
2
L
where ƭ is the tapping position and L is the length of the filter.
The detailed procedure can be looked into in Ref[10]. Bandwidth of the filter is set up by the loaded Q
of the resonator. The loaded Q L , of a resonator depends on its losses and the external circuit connected
to it. The relation Q L -1 =Q U -1 +Q C -1 is well known, and when Q E <<Qu, the bandwidth is almost
independent of the Qu but Q E Ä Qu, and then the circuit becomes lossy. These effects in three major
parameters: broaden the bandwidth, introduces extra insertion loss and reduces rejection in the stop
band [10]. To demonstrate the effect of Q, two hairpin topologies has been simulated and realized. The
first topology has been based on the standard design where the spacing between coupled sections is
equal and line widths are kept to be 1.13 mm corresponding to 50 ohms [Figure 3]. However, this
approach results in poor Q resulting from the Qu approaching towards QE, resulting in high insertion
loss and poor stop band characteristic. This cannot be overcome with the standard design.
The five section hairpin filter has been further modified by having different coupling coefficients and
widths to have better skirt and harmonic suppression [Figure 5]. This has been found out that in MIC
design the Q of middle resonator section has a greater role in determining the overall Q rather than
outer resonator section [11]. The high impedance line along with greater spacing makes inequality
between Q E with that of Qu, thus the performance of the overall circuit can be improved as shown in
the Figure 6. This approach is compounded by the transmission zero theory which shows the improved
attenuation rates keeping the same size which has been done by optimization using EM software tool.
The bandwidth got reduced to 10% from the standard topology bandwidth of 20%. The corresponding
spacing termed as A equals to 1.18 mm and the middle section width comes out to be 0.84 mm whereas
the 50 ohms width corresponds to 1.13 mm. The spacing between the resonator termed as B equals to
3.2 mm. Still alignment and tuning is difficult as all couplings are responsible in a collective way to
produce poles and zeros. So, a second harmonic peak is difficult to avoid in these configurations.
4
917833899.014.png 917833899.015.png
Figure 3 Hairpin Standard Topology Figure 4 Measured Results
The other way round in this approach is to make strip width as wide as possible to maximize the Qu.
But as the strip width becomes wider, the first section gap becomes smaller and put hindrance on the
practical limitation of the realizability [12].
4
343
×
f
Ã
0
InsertionL
oss
(
dB
)
=
×
g
----------
(8)
i
BW
×
Q
U
Figure 5 Hairpin Modified Topology Figure 6 Measured Results
The measured results shows improved characteristics along with better insertion loss, which validates
the theory adopted.
C. Harmonic Suppression Topology
The proposed structure giving harmonic suppression along with steep attenuation rate is shown in
Figure 7. The concept of edge coupled has been clubbed with the hairpin giving a compact size and
better performance. The standard design equations as described in section 2A are used to find out the
number of sections and coupling coefficients. The number of sections chosen is six for symmetry. The
elimination of second harmonics has been achieved due to phase velocity equalization which is
explained in section 1B. Also the coupling coefficient and coupled lengths have been optimized for
controlling transmission zeros. Further more the input and output planes are aligned without much
bending.
5
917833899.016.png 917833899.017.png 917833899.018.png 917833899.019.png 917833899.020.png

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