classical oscillator 
Dynamics and infrared absorption of a classical oscillator moving in an energy dependent double well potential


We have modelled the shaking term by a classical oscillator which interacts with the tunnelling particle.


Reflectance spectra as a function of the temperature have been analysed by means of the classical oscillator model, in order to obtain the temperature dependence of the band gap energy.


Dispersion parameters are calculated by using the classical oscillator model.


Equilibrium fluctuations around the classical oscillator trajectory are shown to include Guerra and Loffredo's coherent states and Skagerstam's result on dissipative diffusion.


The "classical" oscillator behavior is defined as type A.


The "classical" oscillator behavior is defined as type A.


The displaced wave packet for CaldirolaKanai oscillator in coherent state oscillates back and forth with time about the center as for a classical oscillator.


The tomographicprobability distribution of the classical oscillator is studied.


Twophonon relaxation of a classical oscillator interacting with a condensed medium


EPR and NMR detection by the nonlinear classical oscillator operating far from sinusoidal region


However, the line profile will continue to have the characteristic Lorentzian shape that we found for the classical oscillator.


In what follows, we develop a theory of the switching rates Wnm for a classical oscillator.


To our knowledge there is as yet no model that would resolve the difficulties the data point to in the conventional classical oscillator models.


The dielectric constant, absorption coefficient are fitted with classical oscillator model.


The first drawback of the classical oscillator method of additive synthesis is the computation X.

