Related papers: Relating relative R\'enyi entropies and Wigner-Yanase-Dyson skew information to generalized multiple quantum coherences

Relating relative R\'enyi entropies and Wigner-Yanase-Dyson skew information to generalized multiple quantum coherences

URL: http://arxiv.org/abs/2002.11177v2
Date: Mon, 10 Aug 2020 21:42:40 GMT
Title: Relating relative R\'enyi entropies and Wigner-Yanase-Dyson skew information to generalized multiple quantum coherences
Authors: Diego Paiva Pires, Augusto Smerzi, Tommaso Macr\`i
Abstract summary: We investigate the $alpha$-MQCs, a novel class of multiple quantum coherences based on $alpha$-relative purity. Our framework enables linking $alpha$-MQCs to Wigner-Yanase-Dyson skew information. We illustrate these ideas for quantum systems described by single-qubit states, two-qubit Bell-diagonal states, and a wide class of multiparticle mixed states.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum coherence is a crucial resource for quantum information processing. By employing the language of coherence orders largely applied in NMR systems, quantum coherence has been currently addressed in terms of multiple quantum coherences (MQCs). Here we investigate the $\alpha$-MQCs, a novel class of multiple quantum coherences which is based on $\alpha$-relative purity, an information-theoretic quantifier analogous to quantum fidelity and closely related to R\'{e}nyi relative entropy of order $\alpha$. Our framework enables linking $\alpha$-MQCs to Wigner-Yanase-Dyson skew information (WYDSI), an asymmetry monotone finding applications in quantum thermodynamics and quantum metrology. Furthermore, we derive a family of bounds on $\alpha$-MQCs, particularly showing that $\alpha$-MQC define a lower bound to quantum Fisher information (QFI). We illustrate these ideas for quantum systems described by single-qubit states, two-qubit Bell-diagonal states, and a wide class of multiparticle mixed states. Finally, we investigate the time evolution of the $\alpha$-MQC spectrum and the overall signal of relative purity, by simulating the time reversal dynamics of a many-body all-to-all Ising Hamiltonian and comment on applications to physical platforms such as NMR systems, trapped ions, and ultracold atoms.

Related papers

Simultaneous estimations of quantum state and detector through multiple quantum processes [4.782967012381978]
We introduce a framework, in two different bases, that utilizes multiple quantum processes to simultaneously identify a quantum state and a detector. We prove that the mean squared error (MSE) scales as $O(1/N) $ for both QST and QDT, where $N $ denotes the total number of state copies.
arXiv Detail & Related papers (2025-02-17T13:02:36Z)
Quantum Homogenization as a Quantum Steady State Protocol on NISQ Hardware [42.52549987351643]
Quantum homogenization is a reservoir-based quantum state approximation protocol. We extend the standard quantum homogenization protocol to the dynamically-equivalent ($mathttSWAP$)$alpha$ formulation. We show that our proposed protocol yields a completely positive, trace preserving (CPTP) map under which the code subspace is correctable.
arXiv Detail & Related papers (2024-12-19T05:50:54Z)
A new fidelity of quantum channel evolution and its geometric interpretation [2.7381317964853737]
We define an $alpha$-$z$-fidelity as a significant quantity in quantum information theory. We propose a limit formula for the maximum and the minimum of the fidelity. We offer a geometric interpretation for measuring the distance between quantum states.
arXiv Detail & Related papers (2024-12-04T16:32:59Z)
Extending Quantum Perceptrons: Rydberg Devices, Multi-Class Classification, and Error Tolerance [67.77677387243135]
Quantum Neuromorphic Computing (QNC) merges quantum computation with neural computation to create scalable, noise-resilient algorithms for quantum machine learning (QML) At the core of QNC is the quantum perceptron (QP), which leverages the analog dynamics of interacting qubits to enable universal quantum computation.
arXiv Detail & Related papers (2024-11-13T23:56:20Z)
Quantum State Transfer in Interacting, Multiple-Excitation Systems [41.94295877935867]
Quantum state transfer (QST) describes the coherent passage of quantum information from one node to another. We describe Monte Carlo techniques which enable the discovery of a Hamiltonian that gives high-fidelity QST. The resulting Jaynes-Cummings-Hubbard and periodic Anderson models can, in principle, be engineered in appropriate hardware to give efficient QST.
arXiv Detail & Related papers (2024-05-10T23:46:35Z)
Spin coupling is all you need: Encoding strong electron correlation in molecules on quantum computers [0.0]
We show that quantum computers can efficiently simulate strongly correlated molecular systems by directly encoding the dominant entanglement structure in the form of spin-coupled initial states. Our work provides a crucial component for enabling scalable quantum simulation of classically challenging electronic systems.
arXiv Detail & Related papers (2024-04-29T17:14:21Z)
The Power of Unentangled Quantum Proofs with Non-negative Amplitudes [55.90795112399611]
We study the power of unentangled quantum proofs with non-negative amplitudes, a class which we denote $textQMA+(2)$. In particular, we design global protocols for small set expansion, unique games, and PCP verification. We show that QMA(2) is equal to $textQMA+(2)$ provided the gap of the latter is a sufficiently large constant.
arXiv Detail & Related papers (2024-02-29T01:35:46Z)
Quantifying High-Order Interdependencies in Entangled Quantum States [43.70611649100949]
We introduce the Q-information: an information-theoretic measure capable of distinguishing quantum states dominated by synergy or redundancy. We show that quantum systems need at least four variables to exhibit high-order properties. Overall, the Q-information sheds light on novel aspects of the internal organisation of quantum systems and their time evolution.
arXiv Detail & Related papers (2023-10-05T17:00:13Z)
Mixed Quantum-Semiclassical Simulation [0.0]
We study the quantum simulation of mixed quantum-semiclassical (MQS) systems, of fundamental interest in many areas of physics. A basic question for these systems is whether quantum algorithms of MQS systems would be valuable at all, when one could instead study the full quantum-quantum system.
arXiv Detail & Related papers (2023-08-30T17:02:33Z)
Quantum Merlin-Arthur proof systems for synthesizing quantum states [0.0]
We investigate a state synthesizing counterpart of the class NP-synthesizing. We establish that the family of UQMA witnesses, considered as one of the most natural candidates, is in stateQMA. We demonstrate that stateQCMA achieves perfect completeness.
arXiv Detail & Related papers (2023-03-03T12:14:07Z)
Theory of Quantum Generative Learning Models with Maximum Mean Discrepancy [67.02951777522547]
We study learnability of quantum circuit Born machines (QCBMs) and quantum generative adversarial networks (QGANs) We first analyze the generalization ability of QCBMs and identify their superiorities when the quantum devices can directly access the target distribution. Next, we prove how the generalization error bound of QGANs depends on the employed Ansatz, the number of qudits, and input states.
arXiv Detail & Related papers (2022-05-10T08:05:59Z)

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