Final year presentation on Advanced design system

CONTENTS
WORK DONE
06
01 AIM
02 OBJECTIVE
03
INTRODUCTION
04
LITERATURE REVIEW
05
INFERENCE DRAWN OUT
08 REFERENCES
FLOW CHART
07

AIM
To design a Compact Microwave strip filter using
resonators of smaller sizes with better performance

OBJECTIVE
Design of novel resonator structures
with additional structure.
Improved passband and stopband
performance.
Optimum locations for transmission
zeroes.
Compact resonator filter.

W1
FLOW CHART
W2 W4
W3
W1:Software learning(3 months)
W2:Challenges in designing of
resonators(3 months)
W3: Communication of first design
(3 months)
W4:Worked on resonators and
improved Structure(3 months)
W5:Will work on last chapter of
thesis writing(3 months)
W6:Thesis writing and
submission(3 months)
W5 W6

INTRODUCTION
• Bandpass filters are a vital part of the communication system.
• Microwave filters with compact, miniaturized size and high performance
left a remarkable impact on wireless communication systems.
• The filters composed of the fed lines connected to the two ports with the parallel
coupled lines between them are called Microstrip bandpass filters.
• This paper demonstrates a Narrow Band Bandpass filter with a compact
microwave communication system.
structure and applicability to AMSR- E instrument at the aqua platform in

Usage of Bandpass filter
• Communication systems
• Radar systems
• Microwave links
• Medical Devices
• RF Testing and measurements
• IoT Devices
• Antenna Systems

Resonators
The structure that is able to enclose at least one oscillating electromagnetic field is
called a Microstrip resonator.

Usage of resonators
• Oscillators
• Filters
• Antennas
• RF filters
• Sensors
• Sonar and Radar systems
• Quantum Computing
• Medical devices

Technology used
• This filter was designed using the Keysight ADS software.
• The physical implementation was done using the substrate Rogers_R03010,
two ports and a lab with facility for meandering the microstrip filter.

• Better performance
What does Our Filter offers?
• Improved Passband and stopband performance.
• Compact and miniaturized structure
• Controllable central frequency.
• Easy to fabricate.

Literature Review
• Bandpass filters are a vital part of the communication system. Compact and miniaturized design aspects of
filters play an important role in a fast data transmission system. Microwave filter with small sizes and high
performance has left a remarkable impact on the wireless communication system. Resonators are being a
necessity in the construction of microstrip filters [1-7].
• The small size of the resonator will result in the compactness of the filter. By reducing the size of the filter, we can
modify the resonator structure or the traditional resonator, from this we can create additional modes with better
performance and small area. [8-10].
• Modified resonators can be handled as multiple resonators. Compact size multimode resonator has relatively low
attenuation within the filter designing process. coupling among the degenerate modes is quite a difficult process for
filter designing with high performance using a single multimode resonator when compared with multiple multimode
resonators. In most of the designed multiple multimode resonators, the parasitic resonance operates close to
fundamental modes [11- 16].

• In Ala'a [17], a non-uniform bandpass filter with a defected ground structure (DGS) is presented. The width of the
presented filter was obtained using an improved operation with a U shape and non-uniform form. Moreover, a DGS is
employed to acquire multiple bands. The proposed design was implemented using high-frequency software such as
HFSS and CST-Studio.
• Another methodology for designing harmonics was a suppressed microstrip ultra-wideband (UWB) BPF proposed in Bi
[18].
• In Chakravorty [19], a collaborative split-ring resonator technique is adopted to anticipate the center frequency
and design of microstrip bandpass filters that are generally below the class of heuristic structures. Bent
transmission lines are often needed to minimize channel structures physically; however, in the hypothetical
(planned) prediction of complete or focal frequencies for the bandpass channel plan, ebb-and-flow effects may
cause errors. Previous suggestions on bend corrections were accurate, but continuing structure standards require
an improvement in accuracy.

INFERENCE
DRAWN
OUT
• The interdigital structure is a combination of
stubs and it can be modified .
• Bandpass filters can be designed for any frequency
range.
• Notch can be created for any desired frequency.
• Filter performance can be improved by using
resonators with defective microstrip structures
• The size of the filter can be reduced by using
defective microstrip structures (DMS) in micro-strip
resonator.
• Transmission zero can be adjusted.

WORK DONE
S21
S12
Paper Applied in the NIT Delhi conference.
Narrow Band Bandpass filter S-Parameter of simulated proposed model

References
R. Levy, (1970). “Zolotarev functions, a new distribution prototype filter, and the design of mi xed lumped/distributed
components”. IEEE G-MTT Microwave Int. Symp. Dig., Vol.70, pp.71-75.
J. Wang, Y.X Guo, B.Z. Wang, L. C. Ong, and S. Xiao, (2006). “High- selectivity dual-band stepped-impedance bandpass
filter”. Electronics Letters, Vol.42, No.9, pp.538- 540.
S. Sun and L. Zhu, (2005). “Novel design of dual-band microstrip bandpass filters with good in-between isolation”. IEEE
APMC 2005, Suozhou.
L.C. Tsai and C.W. Hsue, (2004). “Dual-band bandpass filters using equallength coupled-serial shunted lines and Z-
transform techniques”. IEEE Trans. Microw. Theory Tech., Vol.52, No.4, pp.1111-1117.
W.H. Tu and K. Chang, (2005). “Miniaturized dualmode bandpass filter with harmonic control”. IEEE Microwave And
Wireless Components Letters, Vol.15, No.12.
C. Lugo and J. Papapolymerou, (2005). “Bandpass filter design using a microstrip triangular loop resonator with dual-
mode operation”.IEEE Microwave and Wireless Components Letters, Vol.15, No.7
J.X. Chen and T. Y. Yum, (2006). “Dual-mode dualband bandpass filter using stacked-loop structure”. IEEE Microwave and
Wireless Components Letters, Vol.16, No.9.
X.W. Dai, C.H. Liang, B. Wu, and J. Fan, (2008). “Novel dual-band bandpass filter design using microstrip open-loop
resonators”. Journal of Electromagnetic Waves and Applications, Vol.22, No.2, pp.219- 225.

J.K. Xiao, S.P. Li, and Y. Li, (2006). “Novel planar bandpass filters using one single patch resonators with corner cuts”.
Journal of Electromagnetic Waves and Applications, Vol.20, No.11, pp.1481- 1493.
J.K. Xiao and Y. Li, (2006). “Novel compact microstrip square ring bandpass filters”. Journal of Electromagnetic Waves
and Applications, Vol.20, No.13, pp.1817-1826.
M. Kazerooni and A. Cheldavi, (2006). “Simulation, analysis, design and applications of array defected microstrip
structure (ADMS) filters using rigorously coupled multi-strip (RCMS) method”. Progress in Electromagnetics Research,
PIER 63, pp.193-207.
M. Khalaj-Amirhosseini, (2006). “Microwave filters using waveguides filled by multi-layer dielectric”. Progress in
Electromagnetics Research, PIER 66, pp.105-110.
Ahmad, B. H., Nornikman, H., & Aziz, M. Z. A. A. (2015). Microstrip patch antenna with 12-N modified double W-
shaped split ring resonator (MDW-SRR) structure. 2015 IEEE International RF and Microwave Conference (RFM).
doi:10.1109/rfm.2015.7587731
Conductor Backed Coplanar Waveguide Bandpass Filter using Vertically Loaded Coupled Open-ended Stubs, Pratik
Mondal; S. K. Parui; V.P. Padhy; T. Mandal; A. Sarkar, 2019 IEEE 5th Global Electromagnetic Compatibility Conference
(GEMCCON) Year: 2019| Conference Paper | Publisher: IEEE
Microstrip Bandpass Filter Using Degenerate Modes of a Novel Meander Loop Resonator J. S. Hong, Member, IEEE, and
M. J. Lancaster, Member, IEEE, EEE MICROWAVE AND GUIDED WAVE LETTERS, VOL. 5, NO. 11, NOVEMBER
1995
Investigation of Microwave Bandpass Filter Based on Three-Mode Resonator Design of UWB bandpass filter with dual
notched bands using E-shaped resonator Xuemei Zheng; Tao Jiang 2016 IEEE/ACES International Conference on
Wireless Information Technology and Systems (ICWITS) and Applied Computational Electromagnetics (ACES) Year:
2016 | Conference Paper | Publisher: IEEEBoris Belyaev; Sergey Khodenkov; Gregory Nazarov; Konstantin Gaipov 2020
International Conference on Actual Problems of Electron Devices Engineering (APEDE) Year: 2020 | Conference Paper |
Publisher: IEEE

Final year presentation on Advanced design system

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