Related papers: Covariant operator bases for continuous variables

Covariant operator bases for continuous variables

URL: http://arxiv.org/abs/2309.10042v2
Date: Sun, 26 May 2024 19:32:49 GMT
Title: Covariant operator bases for continuous variables
Authors: A. Z. Goldberg, A. B. Klimov, G. Leuchs, L. L. Sanchez-Soto,
Abstract summary: We work out an alternative basis consisting of monomials on the basic observables, with the crucial property of behaving well under symplectic transformations. Given the density matrix of a state, the expansion coefficients in that basis constitute the multipoles, which describe the state in a canonically covariant form that is both concise and explicit.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Coherent-state representations are a standard tool to deal with continuous-variable systems, as they allow one to efficiently visualize quantum states in phase space. Here, we work out an alternative basis consisting of monomials on the basic observables, with the crucial property of behaving well under symplectic transformations. This basis is the analogue of the irreducible tensors widely used in the context of SU(2) symmetry. Given the density matrix of a state, the expansion coefficients in that basis constitute the multipoles, which describe the state in a canonically covariant form that is both concise and explicit. We use these quantities to assess properties such as quantumness or Gaussianity and to furnish direct connections between tomographic measurements and quasiprobability distribution reconstructions.

Related papers

Quantum Random Walks and Quantum Oscillator in an Infinite-Dimensional Phase Space [45.9982965995401]
We consider quantum random walks in an infinite-dimensional phase space constructed using Weyl representation of the coordinate and momentum operators. We find conditions for their strong continuity and establish properties of their generators.
arXiv Detail & Related papers (2024-06-15T17:39:32Z)
Studying Stabilizer de Finetti Theorems and Possible Applications in Quantum Information Processing [0.0]
In quantum information theory, if a quantum state is invariant under permutations of its subsystems, its marginal can be approximated by a mixture of powers of a state on a single subsystem. Recently, it has been discovered that a similar observation can be made for a larger symmetry group than permutations. This naturally raises the question if similar improvements could be found for applications where this symmetry appears.
arXiv Detail & Related papers (2024-03-15T17:55:12Z)
On reconstruction of states from evolution induced by quantum dynamical semigroups perturbed by covariant measures [50.24983453990065]
We show the ability to restore states of quantum systems from evolution induced by quantum dynamical semigroups perturbed by covariant measures. Our procedure describes reconstruction of quantum states transmitted via quantum channels and as a particular example can be applied to reconstruction of photonic states transmitted via optical fibers.
arXiv Detail & Related papers (2023-12-02T09:56:00Z)
A new class of exact coherent states: enhanced quantization of motion on the half-line [0.16385815610837165]
We find a class of dynamically stable coherent states for motion on the half-line. The regularization of the half-line boundary and the consequent quantum motion are expounded within the framework of covariant affine quantization. Our discovery holds significant relevance in the field of quantum cosmology.
arXiv Detail & Related papers (2023-10-25T13:19:24Z)
Discrete dynamics in the set of quantum measurements [0.0]
A quantum measurement, often referred to as positive operator-valued measurement (POVM), is a set of positive operators $P_i=P_idaggeq 0$ summing to identity. We analyze dynamics induced by blockwise bistochastic matrices, in which both columns and rows sum to the identity.
arXiv Detail & Related papers (2023-08-10T19:34:04Z)
Third quantization of open quantum systems: new dissipative symmetries and connections to phase-space and Keldysh field theory formulations [77.34726150561087]
We reformulate the technique of third quantization in a way that explicitly connects all three methods. We first show that our formulation reveals a fundamental dissipative symmetry present in all quadratic bosonic or fermionic Lindbladians. For bosons, we then show that the Wigner function and the characteristic function can be thought of as ''wavefunctions'' of the density matrix.
arXiv Detail & Related papers (2023-02-27T18:56:40Z)
Standard symmetrized variance with applications to coherence, uncertainty and entanglement [3.7298088649201353]
We consider the averaged variances of a fixed diagonal observable in a pure state under all possible permutations on the components of the pure state. We show that the standard symmetrized variance is also an entanglement measure for bipartite systems.
arXiv Detail & Related papers (2022-07-13T08:43:59Z)
Equivariant relative submajorization [0.0]
We study a generalization of relative submajorization that compares pairs of positive operators on representation spaces of some fixed group. We find a sufficient condition for the existence of catalytic transformations and a characterization of an symmetric relaxation of the relation.
arXiv Detail & Related papers (2021-08-30T13:13:21Z)
Gaussian Process States: A data-driven representation of quantum many-body physics [59.7232780552418]
We present a novel, non-parametric form for compactly representing entangled many-body quantum states. The state is found to be highly compact, systematically improvable and efficient to sample. It is also proven to be a universal approximator' for quantum states, able to capture any entangled many-body state with increasing data set size.
arXiv Detail & Related papers (2020-02-27T15:54:44Z)
Inverse Learning of Symmetries [71.62109774068064]
We learn the symmetry transformation with a model consisting of two latent subspaces. Our approach is based on the deep information bottleneck in combination with a continuous mutual information regulariser. Our model outperforms state-of-the-art methods on artificial and molecular datasets.
arXiv Detail & Related papers (2020-02-07T13:48:52Z)
Bulk detection of time-dependent topological transitions in quenched chiral models [48.7576911714538]
We show that the winding number of the Hamiltonian eigenstates can be read-out by measuring the mean chiral displacement of a single-particle wavefunction. This implies that the mean chiral displacement can detect the winding number even when the underlying Hamiltonian is quenched between different topological phases.
arXiv Detail & Related papers (2020-01-16T17:44:52Z)

This list is automatically generated from the titles and abstracts of the papers in this site.