English

Optimized entanglement for quantum parameter estimation from noisy qubits

Quantum Physics 2019-04-04 v1

Abstract

For parameter estimation from an NN-component composite quantum system, it is known that a separable preparation leads to a mean-squared estimation error scaling as 1/N1/N while an entangled preparation can in some conditions afford a smaller error with 1/N21/N^2 scaling. This quantum superefficiency is however very fragile to noise or decoherence, and typically disappears with any small amount of random noise asymptotically at large NN. To complement this asymptotic characterization, we characterize how the estimation efficiency evolves as a function of the size NN of the entangled system and its degree of entanglement. We address a generic situation of qubit phase estimation, also meaningful for frequency estimation. Decoherence is represented by the broad class of noises commuting with the phase rotation, which includes depolarizing, phase-flip, and thermal quantum noises. In these general conditions, explicit expressions are derived for the quantum Fisher information quantifying the ultimate achievable efficiency for estimation. We confront at any size NN the efficiency of the optimal separable preparation to that of an entangled preparation with arbitrary degree of entanglement. We exhibit the 1/N21/N^2 superefficiency with no noise, and prove its asymptotic disappearance at large NN for any non-vanishing noise configuration. For maximizing the estimation efficiency, we characterize the existence of an optimum NoptN_{\rm opt} of the size of the entangled system along with an optimal degree of entanglement. For nonunital noises, maximum efficiency is usually obtained at partial entanglement. Grouping the NN qubits into independent blocks formed of NoptN_{\rm opt} entangled qubits restores at large NN a nonvanishing efficiency that can improve over that of NN independent qubits optimally prepared. One inactive qubit in the entangled probe sometimes is most efficient for estimation.

Keywords

Cite

@article{arxiv.1904.01904,
  title  = {Optimized entanglement for quantum parameter estimation from noisy qubits},
  author = {Francois Chapeau-Blondeau},
  journal= {arXiv preprint arXiv:1904.01904},
  year   = {2019}
}

Comments

23 pages, 8 figures, 40 references

R2 v1 2026-06-23T08:27:55.550Z