Characterizing resources for multiparameter estimation of SU(2) and SU(1,1) unitaries

Abstract

We analyze the task of estimating a multi-parameter unitary belonging to the SU(2) or SU(1,1) groups, in a two-bosonic-mode scenario and investigate the scaling of the precision in terms of the total particle number. For the SU(2) case, the total particle number is conserved by the evolution and we discuss optimal states in fixed-n subspaces, identifying eigenstates of Jz2 as useful resources, even allowing simultaneous Heisenberg precision scaling for all three parameters. In the SU(1,1) case instead, the conserved quantity is the particle number difference between the two modes, and we identify useful probe states in the sector with an equal number of particles in the two modes. These states are analogous to the SU(2) case and would also allow simultaneous Heisenberg precision scaling for all three parameters. We then consider the more pragmatic scenario of an estimation via expectation values of time-evolved observables, which we restrict to be the first two moments of the generators. We analyze the maximal precision achievable in this setting and we find that the twin-Fock state emerges in both the SU(2) and the SU(1,1) cases as the only one potentially allowing Heisenberg scaling for the estimation of two out of the three parameters. As a complement, we also consider other probe states with fluctuating number of particles, with measurements restricted to quadratic expressions in the mode operators. In this scenario, simultaneous Heisenberg scaling in multiple parameters seems mostly forbidden, with the only exception being an input two-mode squeezed state for the estimation of a two-parameter SU(2). This extends to the multiparameter scenario the well-established intuition that the performance of a SU(2) interferometer can be enhanced by a prior SU(1,1) operation.