The optimal design and analysis of wideband second-order microwave integrator

Gautam, Usha; Rawat, Tarun Kumar

doi:10.1017/s1759078719000047

Cited by 3 publications

(2 citation statements)

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“…2,3 Previously, few authors have designed the first-order and second-order microwave integrators using different techniques in the z-domain and frequency domain. [4][5][6][7][8][9] Recently, fractional order integrators and differentiators using chain-scattering matrix have designed by Gautam et al 10,11 This paper demonstrates the new design of microwave integrator leading to the wide bandwidth and eligible for Ku-band applications. Ku-band has a frequency range of 12-18 GHz.…”

Section: Introductionmentioning

confidence: 99%

Compact design of first‐order microwave integrator for Ku band applications

Gautam

Rawat

2022

Micro & Optical Tech Letters

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This article demonstrates the design and implementation of a stable wideband first‐order microwave integrator. The proposed design is attained by the cascading of eight equal‐length serial transmission lines. The meta‐heuristic optimization algorithms namely real‐coded genetic algorithm, particle swarm optimization, and sine–cosine algorithm are applied to attain the characteristic impedance of serial lines. Further, the proposed integrator, fabricated on RT/Duroid 5880 substrate with permittivity (ϵ r ${\epsilon }_{r}$) = 2.2 and height ( t ) $(t)$ = 0.762 mm. The results are measured using a vector network analyzer, show its conformity with the simulated and ideal result within the frequency range of 4–18 GHz in MATLAB environment, and confirm its eligibility for Ku‐band application, which is compact in size.

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Section: Introductionmentioning

confidence: 99%

Compact design of first‐order microwave integrator for Ku band applications

Gautam

Rawat

2022

Micro & Optical Tech Letters

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“…SOMI was designed by Gupta et al in the z-domain over the 1.5-5.5 GHz frequency range [11]. Another SOMI was designed by Gautam et al in the z-domain over the frequency range 3-15 GHz [12]. Nowadays, analyzers are gravitating towards the use of population-based metaheuristic algorithms to optimize system coefficients in order to design complex or multi -modal systems [13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Wideband Second-Order Microwave Integrators

Gautam¹,

Rawat²

2021

Innovations in Ultra-Wideband Technologies

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This chapter presents the implementation of stable, accurate, and wideband second-order microwave integrators (SOMIs). These SOMI designs are obtained by the use of various cascading combinations of transmission line sections and shunt stubs. In order to obtain the optimal values of the characteristic impedances of these line elements, the particle swarm optimization (PSO), cuckoo search algorithm (CSA) and gravitational search algorithm (GSA) are used to approximate the magnitude response of the ideal second-order integrator (SOI). Based on magnitude response, absolute magnitude error, phase response, convergence rate, pole-zero plot, and improvement graph, the performance measure criteria for the proposed SOMIs are performed. The results of the simulation and statistical analysis reveal that GSA exceeds the PSO and CSA in order to approximate the ideal SOI in all state-of-the-art eligible for wide-band microwave integrator. The designed SOMI is compact and suitable for applications covering ultra-wideband (UWB). The designed SOMI structure is also simulated on Advanced Design Software (ADS) in the form of a microstrip line on a dielectric constant 2.2 RT/Duroid substrate with a height of 0.762 mm. In the 3–15 GHz frequency range, the simulated magnitude result agrees well with the ideal one.

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