Quantum Harmonic Oscillator in a Time Dependent Noncommutative Background

This work explores the behaviour of a noncommutative harmonic oscillator in a time-dependent background, as previously investigated in Dey and Fring (Phys. Rev. D 90, 084005, 2014). Specifically, we examine the system when expressed in terms of commutative variables, utilizing a generalized form of the standard Bopp-shift relations recently introduced in Biswas et al. (Phys. Rev. A 102, 022231, 2020). We solved the time dependent system and obtained the analytical form of the eigenfunction using the method of Lewis invariants, which is associated with the Ermakov-Pinney equation, a non-linear differential equation. We then obtain exact analytical solution set for the Ermakov-Pinney equation. With these solutions in place, we move on to compute the dynamics of the energy expectation value analytically and explore their graphical representations for various solution sets of the Ermakov-Pinney equation, associated with a particular choice of quantum number. Finally, we determined the generalized form of the uncertainty equality relations among the operators for both commutative and noncommutative cases. Expectedly, our study is consistent with the findings in Dey and Fring (Phys. Rev. D 90, 084005, 2014), specifically in a particular limit where the coordinate mapping relations reduce to the standard Bopp-shift relations.