Microsoft Word - ETASR_V11_N3_pp7247-7250


Engineering, Technology & Applied Science Research Vol. 11, No. 3, 2021, 7247-7250 7247 
 

www.etasr.com Bitra & Miriyala: An Ultra-Wideband Band Pass Filter using Metal Insulator Metal Waveguide … 

 

An Ultra-Wideband Band Pass Filter using Metal 

Insulator Metal Waveguide for Nanoscale 

Applications 
 

Surendra Kumar Bitra 

Department of Electronics and Communication Engineering 
Koneru Lakshamaiah Education Foundation 

Vaddeswaram, Guntur District, Andhra Pradesh, India 

bitrasurendrakumar@gmail.com 

Sridhar Miriyala 

Department of Electronics and Communication Engineering 
Koneru Lakshamaiah Education Foundation 

Vaddeswaram, Guntur District, Andhra Pradesh, India  

Sridhar.m@kluniversity.in

Abstract-A T-stub Square Ring Resonator (SRR) based Ultra-

Wide Band (UWB) Band Pass Filter (BPF) is studied and 

investigated in this paper. The proposed filter is based on coupled 

feed line connected to the T-stub SRR. Ultra-wideband 

characteristics can be realized by adjusting the T-stub lengths 
and coupling the gaps between both sides of waveguides and 

SRR. The characteristics of the T-stub SRR show that the 

miniaturized UWB BPF can be operated at THz frequencies. The 

proposed UWB filter is simulated and analyzed using the Finite 

Differential Time Domain (FDTD) solver-based Computer 

Simulation Technology (CST) studio suite. The resonance 

conditions are explained and the transmission performance of the 

filter agrees with the simulated and theoretical calculations. The 

proposed filter is best suitable for Electronic-Plasmonic 
Integrated Circuits (EPICs). 

Keywords-Metal-Insulator-Metal (MIM); ring resonator; 

coupled lines; Finite Differential Time Domain (FDTD); Ultra-

Wide Band (UWB); T-stub 

I. INTRODUCTION  

The light incident on a metal-insulator region produces a 
high-speed electromagnetic (EM) wave called Surface Plasmon 
Polarity (SPP) [1]. SPPs are known for overcoming the 
diffraction limit of the light at nanoscale wavelengths. Due to 
the low loss and high confinement of light at nanoscale range 
the Metal-Insulator-Metal (MIM) waveguide has been 
proposed by several researchers [2-4]. The subwavelength 
optical components that have been proposed when using MIM 
waveguide are reported in [5-9]. Several researchers worked on 
theories and experimentations of stub resonators like disk 
resonators [10], teeth-shaped resonators [11], rectangular [12], 
triangular [13], square [14], and circular [15] ring resonators. A 
Band Pass Filter (BPF) with symmetric side couple nano-disk 
resonators is analyzed for 1310nm and 1550nm in [16]. A 
concurrent dual band BPF is designed using slot waveguides 
and the performance is carried out at the resonant frequencies 
of 1300nm and 1600nm respectively in [17]. A tunable stepped 
impedance ring resonator for dual band BPF is designed and 
analysed at O and L bands in [18]. However, most of the 
investigations are carried out in single-, dual- and triple-band of 
operation for BPF. A limited work is carried out in Ultra-Wide 

Band (UWB) BPF where the bandwidth is limited, and the size 
of UWB filters is more. The optical bands used for 
transmission are O-band (1260-1360nm), E-band (1360-
1460nm), S-band (1460-1530nm), C-band (1530-1565nm), and 
the L-band (1565-1625nm). The ring resonators are a 
fundamental component used in the Electronic-Photonic 
Integrated Circuits (EPICs). MIM and Insulator Metal-Insulator 
(IMI) are important geometries used in plasmonic waveguides. 
IMI waveguides carry light in longer propagation distances 
than MIM waveguides due to their cladding layers, but the 
MIM structures have higher confinement. Due to the high 
confinement and moderate propagation lengths, the MIM 
structures are efficiently used by EPICs. Authors in [19] 
designed a two-dimensional structure consisting of a MIM 
waveguide with a ring resonator, and two resonant peaks 
observed. This work is a further extension of the SRR for 
UWB applications.  

Most of the existing resonators have symmetrical shapes. In 
this work, a nanoplasmonic T-stub loaded Square Ring 
Resonator (SRR) at optical bands is proposed. Most of the 
existing work was carried out on the design of single and dual- 
operating bands. In our proposed work, more than one band of 
frequencies are considered simultaneously (Ultra-Wide Band-
UWB). 

II. T-STUB SRR FILTER DESIGN 

SRR filter for dual band and SRR with stubs for triple band 
applications have been designed and their performance was 
investigated in our previous work [20]. In this paper, a T-stub 
SRR filter is designed which is suitable for UWB applications 
with compact dimensions. The methodology of the proposed 
filter design is illustrated with the flowchart shown in Figure 1. 
Firstly, the T-Stub SRR is designed using the Computer 
Simulation Technology (CST) studio suite. Simulations are 
carried out under Perfect Magnetic Layer (PML) boundary 
conditions for getting suitable transmission and reflection 
parameters. Figure 2 represents the proposed UWB filter 
designed using SRR. Four T-stubs are included at the four sides 
of the square ring representing the proposed T-stub SRR. The 
blue color in Figure 2 represents the metal and the gray color 

Corresponding author: Sridhar Miriyala 



Engineering, Technology & Applied Science Research Vol. 11, No. 3, 2021, 7247-7250 7248 
 

www.etasr.com Bitra & Miriyala: An Ultra-Wideband Band Pass Filter using Metal Insulator Metal Waveguide … 

 

indicates the insulator. Silver is used as metal and silica is used 
as an insulator. The silver metal permittivity is calculated using 

the Drude model [21], i.e. ( ) ( )2 2ε m = 1 - ω ω ω+iγp p , where 
ωp (=1.38×10

16
) is the plasma frequency and γ p (=2.73×10

13
) 

is the collision frequency. SiO2 ( 2.5iε = ) is used as an 

insulator and its permittivity is considered constant [21].  

 

Design the T-Stub Ring Resonator using 

CST Studio suite

Start

Optimize the ring resonator 

parameters for appropriate 

Transmission and reflection 

Parameters

End

Simulation for Field distribution plots at the 

resonating wavelengths

 
Fig. 1.  Methodology of proposed T-stub ring resonator. 

 
Fig. 2.  SRR based UWB filter. 

Two waveguides are situated on both sides of the T-stub 
SRR filter. The dimensions of the waveguide, T-stubs and SRR 
are tabulated in Table I. The basic properties of MIM 
waveguide like refractive index (Neff), propagation length (PL) 
of SPP and calculated dispersion relation are defined in [17]. 
The proposed T-stub SRR filter is designed and analyzed using 
a commercially available Finite Differential Time Domain 

(FDTD) solver-based CST studio suite. PML boundary 
conditions with mesh size of 5nm×5nm were used in 
simulations. Two power monitors were included at the two 
ports of the filter (port 1 and port 2) to measure the incident 
power (Pin) and transmitted power (Pout). At port 1 (input port), 
part of the EM waves is reflected at the interface of the MIM 
waveguide and the remaining part of the EM waves is coupled 
to the SRR cavity with a small gap (g). The transmitting and 
reflecting EM waves in the SRR form standing waves and 
these are again coupled to the output port (port 2). The 
rectangular ring resonance condition is given by [12]: 

( )
0 1 2

0

m

g

l l

m

λ
λ

β β

+
= =     (1) 

where m=0,1,2,3…, (βg/β0) is the normalized propagation 
constant, and λ0 is the fundamental wavelength. The overall 
length of the SRR can be calculated from

( )( )0 Reg effL N N nλ λ= = where N=1,2,3…., gλ is the guided 
wavelength and 

eff
n is the effective refractive index of the MIM 

waveguide.  

TABLE I. DIMENSIONS OF SRR BASED UWB FILTER 

S. No Parameter Dimensions (nm) 

1 L 100 

2 W 60 

3 L1 1100 

4 d 60 

5 L2 295 

6 W2 50 

7 L3 275 

8 W3 55 

9 g 3 

 

Simulations were carried out for rectangular ring resonator 
observed the dual band operation [11]. Including the T-stubs on 
the four sides of the SRR forms the proposed UWB structure 
and operated O, E, S, and C bands simultaneously. The 
proposed filter is very useful for EPICs. The fabrication of 
MIM waveguide can be done by film deposition and 
photolithography techniques. 

III. RESULTS AND DISCUSSION 

The reflection and transmission characteristics of the T-stub 
SRR are represented in Figure 3. The simulations were carried 
in the FDTD solver-based CST microwave studio suite under 
PML boundary conditions and mesh settings of 5nm×5nm. The 
simulation results of Figure 3(a)-(b) clearly show the filter 
operating in the O, E, S, and C bands simultaneously. The 
transmission characteristics of the proposed T-stub SRR 
depends on the electromagnetic resonance of the SRR. The 
transmission and reflection characteristics are represented in 
Figure 3(a) for varying L3, from 290 to 300 with a step size of 
5nm. For increasing L3 the covering UWB is moved right as 
shown in Figure 3(a). The optimum length L3 is 295nm. The 
bandwidth observed is ~300nm by the T-stub SRR. By varying 
the optimum width W3 of the T-slot from 50nm to 60nm with a 
step size of 5nm, the UWB spectrum covers higher 
wavelengths i.e from 1240nm to 1570nm. However, the 



Engineering, Technology & Applied Science Research Vol. 11, No. 3, 2021, 7247-7250 7249 
 

www.etasr.com Bitra & Miriyala: An Ultra-Wideband Band Pass Filter using Metal Insulator Metal Waveguide … 

 

reflection coefficient is near to the -10dB range bound. The 
optimimum width for the T-stub is 55nm. The other parameters 
L, W, W2, d, and L2 have negligible effect on the UWB 
spectrum. The varied W3 reflection and Transmission 
coefficient is represented in the Figure 3(b). By varying the gap 
g between the coupled waveguide and SRR, the operating 
UWB band shifts to the right (Figure 3(c)). The value of g 
varies from 2 to 4nm with a step size of 1nm. For the 2nm gap, 
the reflection coefficient is above -10dB for wavelengths from 
1360nm to 1450nm, for 3nm the RC is less than -10dB 
throughout the bands, and for 4nm gap the bands are 
decreasing. Due to that, 3nm is considered the optimum gap of 
the proposed UWB filter. The bandwidth of the proposed UWB 
observed from the simulation results is ~300nm. The 
symmetrical MIM waveguides are located on both sides of the 
T-stub SRR, the electromagnetic wave in the T-stub SRR will 
form the stable resonance observed at three wavelengths shown 
in Figure 3. 

 

(a) 

 

(b) 

 

(c) 

 

Fig. 3.  Reflection and transmission coefficients for: (a) varying L3,(b) 

varying W3, and (c) varying gap g between the coupled feed and the SRR. 

The proposed UWB filter is compared with existing filter 
models in terms of parameters like operating wavelength, 

Extinction Ratio (ER), Bandwidth (BW), Area (L×W) occupied 
by the filter, and application bands. The proposed filter 
provides an improved bandwidth of 310nm when compared 
with the bandwidth (150nm) of the filter presented in [23]. 
Even though the bandwidth is low for the proposed filter in 
comparison with the filter of [4] (320nm), it operates in four 
operating bands (O, S, C, and E).  

 

(a) 

 

(b) 

 

(c) 

 

Fig. 4.  Field distributions: (a) 1264.94nm (237THz), (b) 1362.69nm 

(220THz), and (c) 1495.9nm (200.4THz). 

The proposed UWB T-stub SRR is giving better 
performance in terms of BW, filter size, and application bands 
as can be seen in Table II. 

TABLE II. COMPARISON OF THE PROPOSED FILTER WITH EXISTING 
MODELS 

Filter 

models 

Operating 

wavelength (nm) 
ER 

BW 

(nm) 

L×W 

(nm
2
) 

Application 

bands 

BPF based on 

ARR [4] 
1190–1510 ~38 320 1100×1620 

O, S, C and 

partial E 

BPF based on 

U-shaped RR 

[23] 

1280–1440 
~26.

5 
150 1120×3232 O, S 

Proposed 

filter based 

on SRR 

1240–1550 
~28.

1 
310 1200×1506 O, S, C, and E 



Engineering, Technology & Applied Science Research Vol. 11, No. 3, 2021, 7247-7250 7250 
 

www.etasr.com Bitra & Miriyala: An Ultra-Wideband Band Pass Filter using Metal Insulator Metal Waveguide … 

 

The energy of the SPP wave at UWB wavelengths shows 
the stronger coupling of the T-stub SRR filter at 1264.94nm 
(237THz), 1362.69nm (220THz), and 1495.9nm (200.4THz) 
wavelengths as shown in Figure 3. According to the simulation, 
the odd mode analysis has given better results than the even 
mode analysis of the T-stub SRR filter. 

IV. CONCLUSION 

In this paper, the T-stub SRR filter for ultra-wide band 
applications based on transmission characteristics was studied. 
The coupled line MIM plasmonic structure is composed of two 
straight waveguides and the T-stub SRR. Simulations were 
carried out using the FDTD based CST studio suite. The 
simulation results show that the T-stub SRR filter gives better 
performance in O, E, S, and C optical bands. The transmission 
is slightly smaller at bigger wavelengths when comparing with 
the transmission at smaller wavelengths. The proposed T-stub 
SRR is optimized for the parameters of L3 (length of the stub) 
and gap g between the MIM waveguide and SRR. The ER for 
the proposed T-Stub UWB filter is ~28.1 at 1252nm and ~17.5 
at 1492nm respectively. The bandwidth for the UWB band is 
310nm. The optimized parameters also show that the proposed 
filter is best suitable for optical UWB applications. A strong EM 
coupling was observed at the MIM waveguides and SRR 
throughout the UWB range. The proposed UWB is best suitable 
for EPICs for transmitting high speed data. These structures are 
fabricated using lithographic techniques.   

REFERENCES 

[1] W. Mu and J. B. Ketterson, "Long-range surface plasmon polaritons 

propagating on a dielectric waveguide support," Optics Letters, vol. 36, 
no. 23, pp. 4713–4715, Dec. 2011, https://doi.org/10.1364/OL.36. 

004713. 

[2] W. Liu, R. Zhong, J. Zhou, Y. Zhang, M. Hu, and S. Liu, "Investigations 
on a nano-scale periodical waveguide structure taking surface plasmon 

polaritons into consideration," Journal of Physics D-applied Physics - J 
PHYS-D-APPL PHYS, vol. 45, May 2012, https://doi.org/10.1088/0022-

3727/45/20/205104. 

[3] K. M. Krishna, M. Z. U. Rahman, and S. Y. Fathima, "A New Plasmonic 
Broadband Branch-Line Coupler for Nanoscale Wireless Links," IEEE 

Photonics Technology Letters, vol. 29, no. 18, pp. 1568–1571, Sep. 
2017, https://doi.org/10.1109/LPT.2017.2737036. 

[4] M. Z. U. Rahman, K. M. Krishna, K. K. Reddy, M. V. Babu, S. S. 

Mirza, and S. Y. Fathima, "Ultra-Wide-Band Band-Pass Filters Using 
Plasmonic MIM Waveguide-Based Ring Resonators," IEEE Photonics 

Technology Letters, vol. 30, no. 19, pp. 1715–1718, Oct. 2018, 
https://doi.org/10.1109/LPT.2018.2866966. 

[5] M. Vishwanath, H. Khan, and K. Thirupathaiah, "Concurrent dual band 

filters using plasmonic MIM waveguide ring resonator," ARPN Journal 
of Engineering and Applied Sciences, vol. 13, no. 5, pp. 1813–1818, 

Mar. 2018. 

[6] M. Vishwanath and H. Khan, "Systematic analysis of T-junctions using 
plasmonic MIM waveguide," Journal of Advanced Research in 

Dynamical and Control Systems, vol. 9, no. 14, pp. 1862–1868, Dec. 
2017. 

[7] G. Veronis and S. Fan, "Modes of Subwavelength Plasmonic Slot 
Waveguides," Journal of Lightwave Technology, vol. 25, no. 9, pp. 

2511–2521, Sep. 2007, https://doi.org/10.1109/JLT.2007.903544. 

[8] V. Mittapalli and H. Khan, "Excitation Schemes of Plasmonic Angular 
Ring Resonator-Based Band-Pass Filters Using a MIM Waveguide," 

Photonics, vol. 6, no. 2, Jun. 2019, Art. no. 41, https://doi.org/10.3390/ 
photonics6020041. 

[9] M. Vishwanath and D. Habibullakhan, "Design and Simulation of 

Compact Band-Pass Filter Using Stub Loaded Plasmonic Mim 

Waveguide," International Journal of Engineering & Technology, vol. 7, 
no. 3.3, pp. 41–43, Jun. 2018, https://doi.org/10.14419/ijet.v7i3. 

3.14482. 

[10] H. Lu, X. Liu, D. Mao, L. Wang, and Y. Gong, "Tunable band-pass 
plasmonic waveguide filters with nanodisk resonators," Optics Express, 

vol. 18, no. 17, pp. 17922–17927, Aug. 2010, https://doi.org/10.1364/ 
OE.18.017922. 

[11] X. Lin and X. Huang, "Numerical modeling of a teeth-shaped 

nanoplasmonic waveguide filter," Journal of the Optical Society of 
America B, vol. 26, no. 7, pp. 1263–1268, Jul. 2009, https://doi.org/ 

10.1364/JOSAB.26.001263. 

[12] B. Yun, G. Hu, and Y. Cui, "Theoretical analysis of a nanoscale 

plasmonic filter based on a rectangular metal–insulator–metal 
waveguide," Journal of Physics D: Applied Physics, vol. 43, no. 38, p. 

385102, Sep. 2010, https://doi.org/10.1088/0022-3727/43/38/385102. 

[13] G.-Y. Oh, D.-G. Kim, S. H. Kim, H. C. Ki, T. U. Kim, and Y.-W. Choi, 
"Integrated Refractometric Sensor Utilizing a Triangular Ring Resonator 

Combined With SPR," IEEE Photonics Technology Letters, vol. 26, no. 
21, pp. 2189–2192, Nov. 2014, https://doi.org/10.1109/LPT.2014. 

2349975. 

[14] J. Liu, G. Fang, H. Zhao, Y. Zhang, and S. Liu, "Plasmon flow control at 
gap waveguide junctions using square ring resonators," Journal of 

Physics D: Applied Physics, vol. 43, no. 5, Jan. 2010, Art. no. 055103, 
https://doi.org/10.1088/0022-3727/43/5/055103. 

[15] A. Setayesh, S. R. Mirnaziry, and M. S. Abrishamian, "Numerical 

Investigation of Tunable Band-pass\band-stop Plasmonic Filters with 
Hollow-core Circular Ring Resonator," Journal of the Optical Society of 

Korea, vol. 15, no. 1, pp. 82–89, Mar. 2011. 

[16] S. Shi et al., "Enhanced plasmonic band-pass filter with symmetric dual 
side-coupled nanodisk resonators," Journal of Applied Physics, vol. 118, 

no. 14, Oct. 2015, Art. no. 143103, https://doi.org/10.1063/1.4932668. 

[17] K. Thirupathaiah, N. P. Pathak, and V. Rastogi, "Concurrent Dual Band 
Filters Using Plasmonic Slot Waveguide," IEEE Photonics Technology 

Letters, vol. 25, no. 22, pp. 2217–2220, Nov. 2013, https://doi.org/ 
10.1109/LPT.2013.2283880. 

[18] H. Lu, G. Wang, and X. Liu, "Manipulation of light in MIM plasmonic 
waveguide systems," Chinese Science Bulletin, vol. 58, no. 30, pp. 

3607–3616, Oct. 2013, https://doi.org/10.1007/s11434-013-5989-6. 

[19] S. Bitra and S. Miriyala, "Concurrent Dual and Triple Band Square Ring 
Resonator Base-Band Filter using Metal-Insulator-Metal for Plasmonic 

Applications," Applied Computational Electromagnetics Society 
Journal, vol. 35, no. 10, Dec. 2020, https://doi.org/10.47037/2020. 

ACES.J.351010. 

[20] S. A. Maier, Plasmonics: Fundamentals and Applications. New York, 
NY, USA: Springer, 2007. 

[21] P. B. Johnson and R. W. Christy, "Optical Constants of the Noble 

Metals," Physical Review B, vol. 6, no. 12, pp. 4370–4379, Dec. 1972, 
https://doi.org/10.1103/PhysRevB.6.4370. 

[22] S. K. Bitra and M. Sridhar, "Design of Nanoscale Square Ring 

Resonator Band-Pass Filter Using Metal–Insulator–Metal," in 
Microelectronics, Electromagnetics and Telecommunications, 

Singapore, 2021, pp. 659–664, https://doi.org/10.1007/978-981-15-
3828-5_68. 

[23] P. Osman, P. V. Sridevi, and K. V. S. N. Raju, "Design of Metal-

Insulator-Metal based Plasmonic Ultra-Wide Band U-Shaped resonators 
based Band-Pass Filter," International Journal for Research in Applied 

Science and Engineering Technology, vol. 7, no. 5, pp. 3737–3719, May 
2019, https://doi.org/10.22214/ijraset.2019.5615.