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Synthesis of Planar Filters Using Defected Ground 

Structure Miniaturized Hairpin Resonators 
 

Marin Nedelchev 

Radiocommunication and Videotechnologies Dept. 

Faculty of Telecommunications 

Technical University Sofia 

Sofia, Bulgaria 

mnedelchev@tu-sofia.bg 

Aleksandar Kolev 

Radiocommunication and Videotechnologies Dept. 

Faculty of Telecommunications 

Technical University Sofia 

Sofia, Bulgaria 

alex.n.kolev@gmail.com 
 

 

Abstract—This paper presents an effective technique to suppress 

the spurious passbands in planar filters by using defected ground 

structure (DGS) resonators etched in the ground plane. The 

proposed miniaturized hairpin DGS slot resonator is researched 

in terms of its resonance frequency, corresponding coupling 

topologies, and filter design. The resonator and the topologies of 

coupled DGS resonators are simulated in a fullwave 

electromagnetic (EM) simulator. Using a curve-fitting technique, 

useful design formulas are proposed for filter synthesis. Using the 

synthesis procedure, a 3rd order filter design is simulated, 

manufactured and measured. The insertion loss of -3dB in the 

passband of 280MHz is observed, while the suppression of the 

spurious passbands up to 12GHz is more than 24dB. 

Keywords-microstrip; defected ground resonator; coupling 

coefficient; slot line filter deisgn 

I. INTRODUCTION  

Bandpass filters used in modern microwave communication 
systems have to comply with very strict requirements about 
their performance, size and volume. The manufacturing process 
of such filters must be technologically easy to produce and 
adjust. Many compact microstrip resonators are reported in [1-
10]. The introduction of etched slots in the ground plane of a 
microstrip line adds degrees of freedom in the design and 
synthesis of microstrip filters. These are also known as 
defected ground structures (DGS). They can be periodic or 
non-periodic disturbances in the ground plane of the microstrip 
line. Their shape can be adopted from microstrip resonators [1] 
and appears to be dual to them. This encourages the 
development of new topologies of planar filters with special 
specifications. The use of half wave square open loop and 
miniaturized hairpin resonators as DGS is researched in-depth 
in [5-8]. A combination of microstrip resonators and DGS 
resonators are used in [8] as building elements of planar filters. 
Both applications of slot resonators are a promising way of 
adding additional degrees of freedom in filter design. The use 
of DGS resonators can solve a serious problem in filter design - 
the small gap that is required between coupled lines in order to 
achieve strong coupling. One of the problems encountered in 
the design of wideband and ultra-wideband filters is the 
physical realization of very small gaps between coupled 

resonators. The manufacturing tolerances and the precision of 
the manufacturing process associated with realization of small 
gaps affect the frequency response of the designed filter. By 
utilizing different shaped slots in the ground plane of the 
microstrip line – DGS [1-3, 5-8], it is possible to enhance the 
coupling coefficient. 

This paper researches miniaturized hairpin DGS resonator 
and the coupling structures formed by placing two resonators 
close to each other. The resonance frequency of the DGS 
resonator is investigated and a design formula is proposed. The 
main topologies of coupled DGS resonators are researched and 
based on the simulation results, simple formulas are proposed 
using a curve fitting technique. A three-resonator filter is 
synthesized, simulated, produced and measured in order to 
verify the design equations. There is a good agreement between 
theoretical, simulated and measured results. 

II. MINIATURIZED HAIRPIN DGS RESONATOR 

All the simulations and design procedures in this paper are 
performed in Ansys Electromagnetics Suite v.17.2 for a FR-4 
dielectric substrate with εr=4.4, 1.5mm height and loss tangent 
tgδ=0.02. The miniaturized hairpin microstrip resonator is 
proposed and its synthesis method is described in [1, 3]. The 
resonator consists of a main slot line loaded with two parallel-
coupled slots with a small gap between them. The etched 
resonator is symmetrical around the axis and the open end is in 
the middle of the main line. The magnetic field is concentrated 
in the coupled lines and the electric field is at its maximum 
near the open end of the resonator. Based on the field 
distribution there are three main coupling topologies that can 
be realized, namely electric, magnetic and mixed coupling. The 
occupied area of a miniaturized hairpin DGS resonator is less 
than the conventional hairpin or slow wave resonators. This 
makes the miniaturized hairpin DGS resonator suitable for 
devices working in the lower microwave bands, where the 
physical dimensions of the transmission lines are relatively 
large and miniaturization is not possible. Another advantage of 
the DGS resonator is its rectangular form, which allows its 
usage in the design of canonical and pseudo-elliptic filters with 
cross coupling. 

Corresponding author: M. Nedelchev 



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Coupled slot lines can be used for altering the resonant 
frequency of the resonator. The dimensions of the resonator 
tuned to central frequency f0=2.4Gzh are shown in Figure 1. 
The main slot’s width is w=2.8mm which equals the width of a 
50Ω microstrip line for the used substrate. Figure 2 shows the 
dependence between the length of the coupled lines 𝑝 and the 
first resonant frequency of the resonator, obtained with 
fullwave electromagnetic simulations. Following the 
simulation results, the resonance frequency of the DGS 
resonator is easily tuned by adding or removing metal to the 
ground plane. Using a curve fitting technique, a useful 
expression is derived for the length of the coupled arms: 

𝑝 = 103.8𝑒 −0.9858𝑓0[𝐺𝐻𝑧], [𝑚𝑚]   (1) 

The accuracy of (1) compared to the electromagnetic 
simulations is better than 2.5% and prevents errors caused by a 
wrong read of the graphic results shown in Figure 2. 

 

 

Fig. 1.  Dimensions of the DGS resonator tuned to f0=2.4Gzh 

 

Fig. 2.  Dependence of the resonant frequency of the coupled lines length 

III. COUPLING COEFFICIENTS AND EXTERNAL QUALITY 
FACTOR SIMULATIONS 

As described in [2], the coupling coefficient for 
synchronously tuned resonators can be calculated by finding 
the eigenfrequencies of even (𝑓𝑒 )  and odd (𝑓)𝑜  mode 
associated with coupling between a pair overcoupled 
resonators. 

𝑘 =
𝑓𝑒

2−𝑓𝑜
2

𝑓𝑒
2+𝑓𝑜

2     (2) 

A finite element method (FEM) based fullwave EM 
simulator is used to identify the resonance frequencies in the 
response [2]. Figure 3 shows the coupling topologies used to 

evaluate the coupling coefficients and the external quality 
factor. The miniaturized hairpin slot resonators are dual to the 
miniaturized hairpin resonators and the electromagnetic field is 
inversely distributed in it. The magnetic field has a maximum 
value in the connection point of the coupled lines with the 
transmission line and the electric field has a maximum value in 
the center of the main slot line. 

 
(a) 

 
(b) 

 
(c) 

 
(d) 

Fig. 3.  Coupling topologies of miniaturized hairpin DGS resonators: 
(a) electric, (b) magnetic, (c) mixed, (d) external quality factor 

There are three main types of coupling topologies – 
electric, magnetic and mixed. The electric coupling is shown 
on Figure 3(a), where the electric field has a maximum and 
dominates over the magnetic field. In this configuration the 
sign of the coupling coefficient is negative and can be used for 
cross coupled filters. On Figure 3(b) the magnetic coupling is 
shown. In this configuration, the magnetic field is dominant 
and the sign of the coupling coefficient is positive. The mixed 
coupling is shown on Figure 3(c). In this case neither the 
electric nor the magnetic field is dominant. When a microstrip 
filter is being synthesized, an important point is the 
determination of the gap between the coupled resonators with 
respect to the value of the coupling coefficient calculated from 
the approximation. Three main approaches exist to determine 
the separation between the resonators: analytic formulas [2], 
approximate formulas from curve fitting [8] and extraction 
from EM simulations [2, 3]. Using (2) and EM simulation of 
the coupling structures, which are weekly coupled to a 50Ω 
microstrip feed line the coupling coefficients are extracted. 
Figures 4-6 show the coupling coefficients for the three types 
of coupling as a function of the distance between the resonators 
s. Using a curve fitting method, the following dependences are 
derived for design purposes: 

For electric coupling : 

𝑠𝑒 = 6.88𝑒
−40.36𝑀𝑒     (3) 

For magnetic coupling: 

𝑠𝑚 = 12.36𝑒
−18.45𝑀𝑚      (4) 

For mixed coupling: 

𝑠𝑚𝑖𝑥 = 13.05𝑒
−28.73𝑀𝑚𝑖𝑥      (5) 



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Fig. 4.  Coupling coefficient as function of the separation between the 
resonators for the electric coupling 

 

Fig. 5.  Coupling coefficeint as function of the separation between the 
resonators for the magnetic coupling 

 

Fig. 6.  Dependance of thecoupling coefficient as a function of the 
separation between the resonators for the mixed coupling 

By using (3)-(5) it is easy to compute the separation 
between the coupled lines with accuracy better than 5% 
compared to the EM simulations. The external quality factor 
defines the position of the input/output lines. In the case of 
miniaturized hairpin slot resonators, the external quality factor 
is realized by a 50Ω microstrip line on the top layer of the 
substrate (Figure 3(d)). The dependence of the external quality 
factor as a function of the linear position of the microstrip line 
is shown on Figure 7. The input/output microstrip line 
influences the resonance frequency of the slot resonator and 
shits it towards lower frequencies. This effect must be 
compensated while the filter is being designed by reducing the 
length of the coupled lines of the input/output resonators. 
Because the feed line is placed on the top layer of the substrate, 

input/output lines can overlap the slot resonators. The external 
quality factor changes its value at a very high rate when the 
microstrip line is placed near the DGS resonator. 

 

 

Fig. 7.  Dependance of the external coupling as a function of the position 
of the input/output microtrip line 

IV. BANDPASS FILTER SYNTHESIS, SIMULATIONS AND 
MEASUREMENTS 

The proposed topologies of coupled resonators and the 
formulas for the coupling coefficients can be verified by 
designing a three-resonator Chebyshev filter. The required 
coupling coefficients must be computed by using the standard 
technique described in [2]: 

𝑀𝑛,𝑛+1 =
𝐹𝐵𝑊

√𝑔𝑛𝑔𝑛+1
     (6) 

where 𝐹𝐵𝑊  is the fractional bandwidth and 𝑔𝑛 , 𝑛 = 0,1,2,3 
are the values of the elements of the lowpass filter prototype. 
Different sources of precomputed values for the elements for 
different pass band ripple can be found. The current filter is 
designed for center frequency f0=2400MHz, bandwidth 
Δf=200MHz and return loss in the pass band RL=-20dB. The 
values for the coupling coefficients are M12=M23=0.086 and 
the external quality factor is Qe=25.92. The gaps between the 
resonators are s12=s23=1.13mm and the overlapping between 
the input/output line and slot resonator is d=-1.25mm. Ansys 
Electromagnetics suite v.17.2 is used to simulate the filter in its 
planar simulator. The topology of the simulated filter is shown 
on Figure 8 and the results are shown on Figures 10 and 11. 
The simulated filter has a bandwidth of 280MHz and the 
coupling between the resonators appears to be stronger than 
designed. Due to the effect of the input/output lines on the first 
and third resonators frequency response the length of the 
coupled lines has to be reduced by 0.6mm in order to achieve 
the desired frequency. From Figure 10 it is seen that the filter 
has no spurious pass band response up to 12GHz. The 
minimum suppression of the out of bandpass is -23dB, while 
the maximum suppression is below -45dB. The designed filter 
was produced using standard PCB manufacturing technology 
on a FR-4 substrate with 1.5mm thickness and 0.035mm 
copper foil (Figure 11). On Figure 12 the simulated and 
measured frequency responses for the 𝑠11  and 𝑠21  in 
narrowband are both shown. The measurements were 
performed on a 2 port network analyzer PNA-X N5242B. 
There is good agreement between the simulated and the 
measured results.  



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Fig. 8.  Topology of the synthesized three resonator Chebyshev filter 

 

Fig. 9.  Simulated narrowband frequency response of the synthesized filter. 

 

Fig. 10.  Simulated wideband frequency response of the synthesized filter 

 
(a) 

 
(b) 

Fig. 11.  Fabricated PCB of the synthesized three resonator Chebyshev 
filter: (a) top layer, (b) bottom layer 

The measured bandwidth of the filter is 287MHz, while the 
insertion loss in the passband is -2.79dB. The maximum value 
of the reflection coefficient in the passband is -20dB, which 
corresponds to 0.1dB ripple of the transmission coefficient. The 

measured center frequency of the filter is 2.35GHz. Figure 13 
shows the wideband frequency response of the simulated and 
measured filter. The measured suppression of the spurious 
passbands is lower than -24dB as predicted in the filter 
simulations.  

 

 

Fig. 12.  Measured and simulated narrowband freqeuncy response of the 
synthesized filter 

 

Fig. 13.  Measured and simulated wideband freqeuncy response of the 
synthesized filter 

V. CONCLUSION 

A design of a DGS resonator and its corresponding 
coupling structures are presented in this paper. Topologies of 
coupled DGS resonators are researched and the use of curve 
fitting technique designed formulas is proposed. A three 
resonator filter is synthesized, simulated and produced in order 
to verify the design equations. A good agreement between the 
simulated, theoretical and measured results is observed. The 
proposed DGS resonators can be used in the design of 
microstrip filters in the ISM band on 2.4GHz. 

ACKNOWLEDGEMENT 

This work has been supported by the research grant No – 
182ПД0011-07 with the Scientific Research Center – 
Technical University of Sofia.  

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