Arun Kanti Guin scite author profile

Abstract-The dynamics of the onset of oscillations in a wave guide cavity based Gunn Oscillator (GO) has been critically examined through numerical simulations and experimental studies.The transition of the GO from a non-oscillatory to an oscillatory state and the same in the reverse direction occurs at different critical values of the dc bias voltage applied to the GO. In presence of a weak RF field in GO cavity, oscillations with broad band continuous spectrum and multiple discrete line spectrum are observed at the GO output for different values of dc bias below the above mentioned critical values. Analysing the numerically obtained time series data, chaos quantifiers have been obtained to prove the occurrence of the chaotic oscillations in the GO. Experimental results and observations of numerical simulation show good qualitative agreement.

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Effects of Unilateral Coupling Between Two Chaotic X-Band Gunn Oscillators

Sarkar

Koley

et al. 2013

Int. J. Bifurcation Chaos

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Two X-band microwave Gunn oscillators have been separately operated with "below threshold" dc bias voltages under the influence of an injected weak RF field in their respective cavities to generate chaotic oscillations. The output of one such chaotic Gunn oscillator is injected into the other through a controllable coupling network to explore the possibility of synchronization between two oscillators. We establish through numerical simulation that (i) two oscillators with identical design parameters attain a state of complete synchronization and (ii) two oscillators with slightly different design parameters attain a state of generalized synchronization for reasonable value of coupling strengths. The occurrence of generalized synchronization has been proved through the "auxiliary" slave system approach of nonlinear analysis. Results of hardware experiments are incorporated to qualitatively support the observations made through numerical simulation.

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Birth of oscillation in coupled non-oscillatory Rayleigh–Duffing oscillators

Guin

Dandapathak²,

Sarkar

et al. 2017

Communications in Nonlinear Science and Numerical Simulation

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Studies on the Dynamics of a System of Bilaterally Coupled Chaotic Gunn Oscillators

Sarkar¹,

Koley²,

Guin³

et al. 2012

PIER B

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Abstract-The dynamics of a system of two bilaterally coupled chaotically oscillating X-band Gunn oscillators (GOs) has been studied by numerical simulation and by hardware experiment. The effect of variation of the coupling strengths between two oscillators in two paths has been explored. The chaotic oscillations in two GOs have become synchronized in most of the cases when coupling factors (CFs) are around 20% or more. However, the transformation of chaotic states of the GOs to quasi-periodic ones has been observed for some values of CFs. A detailed numerical analysis on the instantaneous error parameters of the GO state variables is presented to identify different steady state dynamical conditions of the system. Experimental observations of the GO output frequency power spectra and the averaged product of the two GO outputs in the coupled mode confirm the occurrence of synchronization as well as quenching of chaotic oscillations for different values of CFs.

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Experimental and Numerical Studies on the Dynamics of X-Band Gunn Oscillator Based Angle Modulator–Demodulator System with Chaotic Modulating Signal

Sarkar

Guin

et al. 2015

Int. J. Bifurcation Chaos

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We have studied the performance of a Gunn oscillator (GO) based angle modulator-demodulator system in transmitting chaotic signals in the X-band microwave frequency channel. The principle of bias tuning of a GO is employed to implement the angle modulator used in the transmitter. The said GO is operated in a free running condition and then in a frequency synchronized condition to an external microwave signal, thus generating frequency modulated (FM) and phase modulated (PM) signals, respectively. The demodulator circuit is implemented with a GO phase synchronized to the incoming modulated signal, followed by a microwave mixer multiplying the input and the output signals of the GO and a low pass filter. The response of the system is analytically established, numerically examined and experimentally verified. The obtained results confirm that in the limit of low modulation index and in the linear range of operation of the bias tuned modulator and the phase synchronized detector, a chaos signal can be transmitted and recovered through a microwave channel using the technique of angle modulation.

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Arun Kanti Guin

Some Numerical and Experimental Observations on the Growth of Oscillations in an X-Band Gunn Oscillator

Effects of Unilateral Coupling Between Two Chaotic X-Band Gunn Oscillators

Birth of oscillation in coupled non-oscillatory Rayleigh–Duffing oscillators

Studies on the Dynamics of a System of Bilaterally Coupled Chaotic Gunn Oscillators

Experimental and Numerical Studies on the Dynamics of X-Band Gunn Oscillator Based Angle Modulator–Demodulator System with Chaotic Modulating Signal

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