Self-oscillation

Jenkins, Alejandro

doi:10.1016/j.physrep.2012.10.007

Cited by 313 publications

(300 citation statements)

References 162 publications

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“…In oscillation theory such a behaviour is known as auto-oscillations, self-sustained oscillations, or simply selfoscillations (Andronov et al 1996;Jenkins 2013). Selfoscillations occur in non-conservative dissipative systems.…”

Section: Self-oscillatory Modelmentioning

confidence: 99%

Undamped transverse oscillations of coronal loops as a self-oscillatory process

Nakariakov

Anfinogentov

Nisticò

et al. 2016

A&A

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Context. Standing transverse oscillations of coronal loops are observed to operate in two regimes: rapidly decaying, large amplitude oscillations and undamped small amplitude oscillations. In the latter regime the damping should be compensated by energy supply, which allows the loop to perform almost monochromatic oscillations with almost constant amplitude and phase. Different loops oscillate with different periods. The oscillation amplitude does not show dependence on the loop length or the oscillation period. Aims. We aim to develop a low-dimensional model explaining the undamped kink oscillations as a self-oscillatory process caused by the effect of negative friction. The source of energy is an external quasi-steady flow, for example, supergranulation motions near the loop footpoints or external flows in the corona. Methods. We demonstrate that the interaction of a quasi-steady flow with a loop can be described by a Rayleigh oscillator equation that is a non-linear ordinary differential equation, with the damping and resonant terms determined empirically. Results. Small-amplitude self-oscillatory solutions to the Rayleigh oscillator equation are harmonic signals of constant amplitude, which is consistent with the observed properties of undamped kink oscillations. The period of self-oscillations is determined by the frequency of the kink mode. The damping by dissipation and mode conversion is compensated by the continuous energy deposition at the frequency of the natural oscillation. Conclusions. We propose that undamped kink oscillations of coronal loops may be caused by the interaction of the loops with quasi-steady flows, and hence are self-oscillations, which is analogous to producing a tune by moving a bow across a violin string.

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Section: Self-oscillatory Modelmentioning

confidence: 99%

Undamped transverse oscillations of coronal loops as a self-oscillatory process

Nakariakov

Anfinogentov

Nisticò

et al. 2016

A&A

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“…The second component of the environment is the source of energy either in the form of heat supplied at the higher temperature T 1 > T, or chemical energy. In this case, the interaction Hamiltonian reads: (4) and describes the interband transitions.…”

Section: Model Hamiltoniansmentioning

confidence: 99%

“…The general framework of the previous section can be applied to the PTF model described by the Hamiltonians Equations (1)- (4). The first element is the MME generator L[0] computed under the absence of modulation.…”

Section: Mme For the Ptfmentioning

confidence: 99%

“…The macroscopic heat motors or turbines contain always periodically moving elements like pistons, flywheels or rotors, which perform periodic motion at the expense of heat or chemical energy provided by the external reservoir. Such self-oscillatory mechanisms that rely on the feedback are an essential part of the operation of heat engines [4,5].…”

Section: Introductionmentioning

confidence: 99%

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Unified Quantum Model of Work Generation in Thermoelectric Generators, Solar and Fuel Cells

Alicki

2016

Entropy

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Abstract:In the previous papers, the idea of "hidden oscillations" has been applied to explain work generation in semiconductor photovoltaic cells and thermoelectric generators. The aim of this paper is firstly to extend this approach to fuel cells and, secondly, to create a unified quantum model for all types of such devices. They are treated as electron pumps powered by heat or chemical engines. The working fluid is electron gas and the necessary oscillating element ("piston") is provided by plasma oscillation. Those oscillations are localized around the junction that also serves as a diode rectifying fast electric charge oscillations and yielding a final output direct current (DC). The dynamics of the devices are governed by the Markovian master equations that can be derived in a rigorous way from the underlying Hamiltonian models and are consistent with the laws of thermodynamics. The new ingredient is the derivation of master equations for systems driven by chemical reactions.

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“…For example by heating a solid into a liquid, all movements have a more constant volume. To justify the oscillations in the brain as entropy, we already know that systems in a state of entropy resolve into self-oscillation in both quantum (Nachtergaele et al, 2012;Puttarprom et al, 2013 ;Campisi, 2008) and classical domains (Shapovalov, 2008;Jenkins, 2011). The self oscillation is natural consequence of internally directed geometrical symmetry resonating with no external rate acting on the system (Jenkins, 2011).…”

Section: Defining the Limbic Systems Oscillations As Primarily Entropicmentioning

confidence: 99%

Causal Mathematical Logic as a guiding framework for the prediction of “Intelligence Signals” in brain simulations

Lanzalaco

Pissanetzky

2013

Journal of Artificial General Intelligence

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A recent theory of physical information based on the fundamental principles of causality and thermodynamics has proposed that a large number of observable life and intelligence signals can be described in terms of the Causal Mathematical Logic (CML), which is proposed to encode the natural principles of intelligence across any physical domain and substrate. We attempt to expound the current definition of CML, the "Action functional" as a theory in terms of its ability to possess a superior explanatory power for the current neuroscientific data we use to measure the mammalian brains "intelligence" processes at its most general biophysical level. Brain simulation projects define their success partly in terms of the emergence of "non-explicitly programmed" complex biophysical signals such as self-oscillation and spreading cortical waves. Here we propose to extend the causal theory to predict and guide the understanding of these more complex emergent "intelligence Signals". To achieve this we review whether causal logic is consistent with, can explain and predict the function of complete perceptual processes associated with intelligence. Primarily those are defined as the range of Event Related Potentials (ERP) which include their primary subcomponents; Event Related Desynchronization (ERD) and Event Related Synchronization (ERS). This approach is aiming for a universal and predictive logic for neurosimulation and AGi. The result of this investigation has produced a general "Information Engine" model from translation of the ERD and ERS. The CML algorithm run in terms of action cost predicts ERP signal contents and is consistent with the fundamental laws of thermodynamics. A working substrate independent natural information logic would be a major asset. An information theory consistent with fundamental physics can be an AGi. It can also operate within genetic information space and provides a roadmap to understand the live biophysical operation of the phenotype.

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Self-oscillation

Cited by 313 publications

References 162 publications

Undamped transverse oscillations of coronal loops as a self-oscillatory process

Undamped transverse oscillations of coronal loops as a self-oscillatory process

Unified Quantum Model of Work Generation in Thermoelectric Generators, Solar and Fuel Cells

Causal Mathematical Logic as a guiding framework for the prediction of “Intelligence Signals” in brain simulations

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