PDM damped-driven oscillators: exact solvability, classical states crossings, and self-crossings

Abstract

Within the standard Lagrangian and Hamiltonian setting, we consider a position-dependent mass (PDM) classical particle performing a damped driven oscillatory (DDO) motion under the influence of a conservative harmonic oscillator force field V( x) =12ω 2Q( x) x2 and subjected to a Rayleigh dissipative force field R( x,x) =12b\,m( x) x2 in the presence of an external periodic (non-autonomous) force F( t) =F \, ( t) . Where, the correlation between the coordinate deformation Q(x) and the velocity deformation m(x) is governed by a point canonical transformation q( x) =∫ m( x) dx=% Q( x) x. Two illustrative examples are used: a non-singular PDM-DDO, and a power-law PDM-DDO models. Classical-states \x(t),p(t)\ crossings are analysed and reported. Yet, we observed/reported that as a classical state \xi(t),pi(t)\ evolves in time it may cross itself at an earlier and/or a latter time/s.