Simplified Modal-Cancellation Approach for Substrate-Integrated-Waveguide Narrow-Band Filter Design

Current substrate-integrated-waveguide (SIW) filter design methodologies can be extremely computational and time-inefficient when a narrow-band filter is required. A new approach to designing compact, highly selective narrow-band filters based on smartly positioned obstacles is thus presented here. The proposed modal-cancellation approach is achieved by translating or eliminating undesired modes within the frequency of interest. This is performed by introducing smartly located obstacles in the maxima and nulls of the modes of interest. This approach is different from the traditional inverter technique, where a periodic number of inductive irises are coupled in a ladder configuration to implement the desired response of an nth-order filter, and significantly reduces the complexity of the resulting filter structure. Indeed, the proposed method may be used to design different filters for several frequency bands and various applications. The methodology was experimentally verified through fabricated prototypes.

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A Simple Nanometeric Plasmonic Narrow-Band Filter Structure Based on Metal–Insulator–Metal Waveguide

IEEE Transactions on Nanotechnology ◽

10.1109/tnano.2011.2147330 ◽

2011 ◽

Vol 10 (6) ◽

pp. 1371-1376 ◽

Cited By ~ 14

Author(s):

Jia Hu Zhu ◽

Qi Jie Wang ◽

Ping Shum ◽

Xu Guang Huang

Keyword(s):

Narrow Band ◽

Metal Insulator ◽

Filter Structure ◽

Band Filter ◽

Metal Waveguide ◽

Metal Insulator Metal ◽

Narrow Band Filter

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Narrow-band filter design of phononic crystals with periodic point defects via topology optimization

International Journal of Mechanical Sciences ◽

10.1016/j.ijmecsci.2021.106829 ◽

2021 ◽

Vol 212 ◽

pp. 106829

Author(s):

Xiaopeng Zhang ◽

Yan Li ◽

Yaguang Wang ◽

Zhiyuan Jia ◽

Yangjun Luo

Keyword(s):

Topology Optimization ◽

Periodic Point ◽

Point Defects ◽

Filter Design ◽

Narrow Band ◽

Phononic Crystals ◽

Band Filter ◽

Narrow Band Filter

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Narrowband Bandpass Microstrip Filter Design

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.945-949.2338 ◽

2014 ◽

Vol 945-949 ◽

pp. 2338-2341

Author(s):

Yang Li

Keyword(s):

Filter Design ◽

Narrow Band ◽

Simulation Software ◽

Center Frequency ◽

Band Pass Filter ◽

Pass Filter ◽

Band Filter ◽

Prototype Structure ◽

Narrow Band Filter ◽

Band Pass

This paper analyzes the basic theory of the microstrip narrow-band filter design and accomplishes the design of narrow band-pass filter whose center frequency is on L-band with the help of the Agilent ADS simulation software. The filter adopts Chebyshev’s prototype structure and consists of coupled microstrip line. Its fluctuation is less than 0.5dB and attenuation is less than 1.5dB between 1.9GHZ and 2.1GHZ .Its port Reflection coefficient less than-15dB and attenuation is greater than 20dB at 1.72GHZ and 2.3GHZ. Layout simulation meets the requirement of filter design.

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New Design of Integrated 2D Photonic Crystal Narrow Band Filters Using the FDTD-2D Method

Frequenz ◽

10.1515/freq-2014-0043 ◽

2014 ◽

Vol 68 (11-12) ◽

Cited By ~ 2

Author(s):

Hadjira Abri Badaoui ◽

Mehadji Abri

Keyword(s):

Photonic Crystal ◽

Incident Wave ◽

Filter Design ◽

Narrow Band ◽

Transmission Spectra ◽

Spectral Bandwidth ◽

Effective Technique ◽

Band Filter ◽

Narrow Band Filter ◽

Maximum Transmission

AbstractIn this paper, integrated 2D photonic crystal narrow band filter design is achieved based on transmission spectra shift. The presented effective technique for the design of narrow band resonant filters obtained by one-missing-row and by choosing proper radii of air holes of the waveguide is proposed. The 2D photonic crystals are designed by utilizing cascaded waveguides with different radii of air holes. The results are presented for normal incident wave with TE polarizations with a narrow spectral bandwidth centered at λ = 1.55 μm. We also discuss the filtering process and its necessary modifications to achieve efficient filtering. A final synthesized filter topology is presented and a band from 1.53 μm to 1.57 μm around 1.55 μm is transmitted with a maximum transmission of about 77% with better performances is achieved.

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