Dynamics of bow-tie shaped bursting: Forced pendulum with dynamic feedback

A detailed study is performed on the parameter space of the mechanical system of a driven pendulum with damping and constant torque under feedback control. We report an interesting bow-tie shaped bursting oscillatory behaviour, which is exhibited for small driving frequencies, in a certain parameter regime, which has not been reported earlier in this forced system with dynamic feedback. We show that the bursting oscillations are caused because of a transition of the quiescent state to the spiking state by a saddle-focus bifurcation, and because of another saddle-focus bifurcation, which leads to cessation of spiking, bringing the system back to the quiescent state. The resting period between two successive bursts (Trest) is estimated analytically

Oscillatory dynamics of a charged microbubble under ultrasound

Nonlinear oscillations of a bubble carrying a constant charge and suspended in a fluid, undergoing periodic forcing due to incident ultrasound are studied. The system exhibits period-doubling route to chaos and the presence of charge has the effect of advancing these bifurcations. The minimum magnitude of the charge Qmin above which the bubble's radial oscillations can occur above a certain velocity c1 is found to be related by a simple power law to the driving frequency omega of the acoustic wave. We find the existence of a critical frequency omega_H above which uncharged bubbles necessarily have to oscillate at velocities below c1. We further find that this critical frequency crucially depends upon the amplitude Ps of the driving acoustic pressure wave. The temperature of the gas within the bubble is calculated. A critical value P_{tr} of Ps equalling the upper transient threshold pressure demarcates two distinct regions of omega dependence of the maximal radial bubble velocity v_{max} and maximal internal temperature T_{max}. Above this pressure, T_{max} and v_{max} decrease with increasing omega while below P_{tr}, they increase with omega. The dynamical effects of the charge and of the driving pressure and frequency of ultrasound on the bubble are discussed

Oscillatory dynamics of a charged microbubble under ultrasound

Nonlinear oscillations of a bubble carrying a constant charge and suspended in a fluid, undergoing periodic forcing due to incident ultrasound are studied. The system exhibits period-doubling route to chaos and the presence of charge has the effect of advancing these bifurcations. The minimum magnitude of the charge Qmin above which the bubble’s radial oscillations can occur above a certain velocity c1 is found to be related by a simple power law to the driving frequency ! of the acoustic wave. We find the existence of a critical frequency !H above which uncharged bubbles necessarily have to oscillate at velocities below c1. We further find that this critical frequency crucially depends upon the amplitude Ps of the driving acoustic pressure wave. The temperature of the gas within the bubble is calculated. A critical value Ptr of Ps equalling the upper transient threshold pressure demarcates two distinct regions of ! dependence of the maximal radial bubble velocity vmax and maximal internal temperature Tmax. Above this pressure, Tmax and vmax decrease with increasing ! while below Ptr, they increase with !. The dynamical effects of the charge and of the driving pressure and frequency of ultrasound on the bubble are discussed

Bursting behaviour in coupled Josephson junctions

We report an interesting bow-tie shaped bursting behaviour in a certain parameter regime of two resistive-capacitative shunted Josephson junctions, one in the oscillatory and the other in the excitable mode and coupled together resistively. The burst emerges in both the junctions and they show near-complete synchronization for strong enough couplings. We discuss a possible bifurcation scenario to explain the origin of the burst. An exhaustive study on the parameter space of the system is performed, demarcating the regions of bursting from other solution

Effect of charge on the dynamics of an acoustically forced bubble

The effect of charge on the dynamics of a gas bubble undergoing forced oscillations in a liquid due to incidence of an ultrasonic wave is theoretically investigated. The limiting values of the possible charge a bubble may physically carry are obtained. The presence of charge influences the regime in which the bubble’s radial oscillations fall. The extremal compressive and expansive dimensions of the bubble are also studied as a function of the amplitude of the driving pressure. It is shown that the limiting value of the bubble charge is dictated both by the minimal value reachable of the bubble radius as well as the amplitude of the driving ultrasound pressure wave. A non-dimensional ratio � is defined that is a comparative measure of the extremal values the bubble can expand or contract to and find the existence of an unstable regime for � as a function of the driving pressure amplitude, Ps. This unstable regime is gradually suppressed with increasing bubble size. The Blake and the upper transient pressure thresholds for the system are then discussed