Abstract

We consider the evolution of a quantum simple harmonic oscillator in a general Gaussian state under simultaneous time-continuous weak position and momentum measurements. We deduce the stochastic evolution equations for position and momentum expectation values and the covariance-matrix elements from the characteristic function of the system. By generalizing the Chantasri-Dressel-Jordan (CDJ) formalism Action extremization gives us the equations for the most likely readout paths and quantum trajectories. For steady states of the covariance-matrix elements, the analytical solutions for these most likely paths are obtained. Using the CDJ formalism, we calculate final-state probability densities exactly starting from any initial state. We also demonstrate the agreement between the optimal-path solutions and the averages of simulated clustered stochastic trajectories. Our results provide insights into the time dependence of the mechanical energy of the system during the measurement process, motivating their importance for quantum measurement-engine or refrigerator experiments. Although quantum mechanics fundamentally limits our ability to extract information via simultaneous measurements of noncommuting observables, insights into the dynamics of the system during such a process can lead to a deeper understanding of the physics of measurement.