Energy evolution in the time-dependent harmonic oscillator with arbitrary external forcing

Kuzminav, Andrei V.; Robnik, Marko

doi:10.1016/s0034-4877(07)80099-1

Cited by 7 publications

(11 citation statements)

References 21 publications

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“…Describing P (E 1 ) in general is a difficult problem, but for the 1D general time-dependent harmonic oscillator, the problem can be solved [8][9][10]12]. We do not consider the external forcing any further, but the details can be found in [11]. The system is described by the Newton equation q + ω 2 (t)q = 0, (1) and we work out rigorously P (E 1 ).…”

Section: The Phase Flow and General Considerationsmentioning

confidence: 99%

“…where we have denoted δ = (α − β)/2. It follows from ( 9) and ( 10) that we can write (11) also in the form…”

Section: The Phase Flow and General Considerationsmentioning

confidence: 99%

“…But aperiodic time variation of the system (control) parameters is also interesting and important, especially in the case of sufficiently slow variation, in the so-called adiabatic limit, even in the 1D systems. The questions of the energy evolution of a microcanonical ensemble of initial conditions and the preservation of the adiabatic invariants are very closely related, and they have been addressed for the entirely general 1D time-dependent linear oscillator in a series of papers by Robnik and Romanovski [8][9][10][11][12]. A remarkable theorem has been found there: in full generality, the adiabatic invariant at the mean energy of an initial microcanonical ensemble never decreases.…”

Section: Introductionmentioning

confidence: 99%

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Statistical properties of 1D time-dependent Hamiltonian systems: from the adiabatic limit to the parametrically kicked systems

Papamikos¹,

Robnik²

2011

J. Phys. A: Math. Theor.

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We consider 1D time-dependent Hamiltonian systems and their statistical properties, namely the time evolution of microcanonical distributions, whose properties are very closely related to the existence and preservation of the adiabatic invariants. We review the elements of the recent developments by Robnik and Romanovski (during 2006–2008) for the entirely general 1D time-dependent linear oscillator and try to generalize the results to the 1D nonlinear Hamilton oscillators, in particular the power-law potentials like e.g. the quartic oscillator. Furthermore, we consider the limit opposite to the adiabatic limit, namely parametrically kicked 1D Hamiltonian systems. Even for the linear oscillator, interesting properties are revealed: an initial kick disperses the microcanonical distribution to a spread one, but an anti-kick at an appropriate moment of time can annihilate it, kicking it back to the microcanonical distribution. The case of periodic parametric kicking is also interesting. Finally, we propose that in the parametric kicking of a general 1D Hamilton system, the average value of the adiabatic invariant always increases, which we prove for the power-law potentials. We find that the approximation of kicking is good for quite long times of the parameter variation, up to the order of not much less than one period of the oscillator. We also look at the behavior of the quartic oscillator for the case of the kick and anti-kick, and also the periodic kicking.

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Section: The Phase Flow and General Considerationsmentioning

confidence: 99%

“…where we have denoted δ = (α − β)/2. It follows from ( 9) and ( 10) that we can write (11) also in the form…”

Section: The Phase Flow and General Considerationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Statistical properties of 1D time-dependent Hamiltonian systems: from the adiabatic limit to the parametrically kicked systems

Papamikos¹,

Robnik²

2011

J. Phys. A: Math. Theor.

Self Cite

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show abstract

“…Recently, Robnik and Romanovski managed to solve explicitly and rigorously the discrete WKB recurrence formula to all orders [2] and then applied the method to solvable 1D potentials in the context of quantum mechanics to all orders, showing that in this way we can get exact energy spectra for all solvable 1D potentials with discrete energy spectrum [3][4][5][6][7][8]. Later on, in a series of papers, they successfully applied the method to all orders of the time-dependent linear oscillator with arbitrary time dependence of the oscillator frequency [9][10][11][12][13][14] and discussed in detail the question of the preservation of the adiabatic invariants and its relationship with the statistical properties of such systems, such as the evolution of the energy distribution, starting from an initial microcanonical ensemble of initial conditions. Time-dependent Hamiltonian systems are very interesting and important dynamical models, where many important questions about their dynamical statistical behavior can be studied [15][16][17][18][19].…”

Section: Introductionmentioning

confidence: 99%

“…But non-periodic time variation of the system (control) parameters is also interesting and important, especially in the case of sufficiently slow variation, in the so-called adiabatic limit, even in the 1D systems. The problems of the energy evolution of a microcanonical ensemble of initial conditions and the preservation of the adiabatic invariants are very closely related, and they have been studied for the entirely general 1D time-dependent linear oscillator in the above-mentioned series of papers by Robnik and Romanovski [9][10][11][12][13][14]. An interesting and important theorem has been found and proved there; in full generality, the adiabatic invariant at the mean final energy of an initially microcanonical ensemble never decreases.…”

Section: Introductionmentioning

confidence: 99%