Your search keyword '"quantum metrology"' showing total 32 results

1. Multiparameter Estimation with Two-Qubit Probes in Noisy Channels.

Author

Conlon, Lorcán O., Lam, Ping Koy, and Assad, Syed M.

Subjects

*QUANTUM noise, *QUANTUM computing, *CHANNEL estimation, *QUANTUM mechanics, *PARAMETER estimation, *JOB performance

Abstract

This work compares the performance of single- and two-qubit probes for estimating several phase rotations simultaneously under the action of different noisy channels. We compute the quantum limits for this simultaneous estimation using collective and individual measurements by evaluating the Holevo and Nagaoka–Hayashi Cramér-Rao bounds, respectively. Several quantum noise channels are considered, namely the decohering channel, the amplitude damping channel, and the phase damping channel. For each channel, we find the optimal single- and two-qubit probes. Where possible we demonstrate an explicit measurement strategy that saturates the appropriate bound and we investigate how closely the Holevo bound can be approached through collective measurements on multiple copies of the same probe. We find that under the action of the considered channels, two-qubit probes show enhanced parameter estimation capabilities over single-qubit probes for almost all non-identity channels, i.e., the achievable precision with a single-qubit probe degrades faster with increasing exposure to the noisy environment than that of the two-qubit probe. However, in sufficiently noisy channels, we show that it is possible for single-qubit probes to outperform maximally entangled two-qubit probes. This work shows that, in order to reach the ultimate precision limits allowed by quantum mechanics, entanglement is required in both the state preparation and state measurement stages. It is hoped the tutorial-esque nature of this paper will make it easily accessible. [ABSTRACT FROM AUTHOR]

Published

2023

2. Optomechanics-Based Quantum Estimation Theory for Collapse Models.

Author

Marchese, Marta Maria, Belenchia, Alessio, and Paternostro, Mauro

Subjects

*ESTIMATION theory, *QUANTUM theory, *MODEL theory, *QUANTUM correlations, *PARAMETER estimation, *BUILDING failures

Abstract

We make use of the powerful formalism of quantum parameter estimation to assess the characteristic rates of a continuous spontaneous localization (CSL) model affecting the motion of a massive mechanical system. We show that a study performed in non-equilibrium conditions unveils the advantages provided by the use of genuinely quantum resources—such as quantum correlations—in estimating the CSL-induced diffusion rate. In stationary conditions, instead, the gap between quantum performance and a classical scheme disappears. Our investigation contributes to the ongoing effort aimed at identifying suitable conditions for the experimental assessment of collapse models. [ABSTRACT FROM AUTHOR]

Published

2023

3. Multiparameter Estimation with Two-Qubit Probes in Noisy Channels

Author

Lorcán O. Conlon, Ping Koy Lam, and Syed M. Assad

Subjects

quantum metrology, collective measurements, entanglement, Cramér-Rao bound, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

This work compares the performance of single- and two-qubit probes for estimating several phase rotations simultaneously under the action of different noisy channels. We compute the quantum limits for this simultaneous estimation using collective and individual measurements by evaluating the Holevo and Nagaoka–Hayashi Cramér-Rao bounds, respectively. Several quantum noise channels are considered, namely the decohering channel, the amplitude damping channel, and the phase damping channel. For each channel, we find the optimal single- and two-qubit probes. Where possible we demonstrate an explicit measurement strategy that saturates the appropriate bound and we investigate how closely the Holevo bound can be approached through collective measurements on multiple copies of the same probe. We find that under the action of the considered channels, two-qubit probes show enhanced parameter estimation capabilities over single-qubit probes for almost all non-identity channels, i.e., the achievable precision with a single-qubit probe degrades faster with increasing exposure to the noisy environment than that of the two-qubit probe. However, in sufficiently noisy channels, we show that it is possible for single-qubit probes to outperform maximally entangled two-qubit probes. This work shows that, in order to reach the ultimate precision limits allowed by quantum mechanics, entanglement is required in both the state preparation and state measurement stages. It is hoped the tutorial-esque nature of this paper will make it easily accessible.

Published

2023

4. Critical Quantum Metrology in the Non-Linear Quantum Rabi Model.

Author

Ying, Zu-Jian, Felicetti, Simone, Liu, Gang, and Braak, Daniel

Subjects

*PHASE transitions, *METROLOGY, *CRITICAL point (Thermodynamics), *QUBITS, *MAGNETOMETERS

Abstract

The quantum Rabi model (QRM) with linear coupling between light mode and qubit exhibits the analog of a second-order phase transition for vanishing mode frequency which allows for criticality-enhanced quantum metrology in a few-body system. We show that the QRM including a nonlinear coupling term exhibits much higher measurement precisions due to its first-order-like phase transition at finite frequency, avoiding the detrimental slowing-down effect close to the critical point of the linear QRM. When a bias term is added to the Hamiltonian, the system can be used as a fluxmeter or magnetometer if implemented in circuit QED platforms. [ABSTRACT FROM AUTHOR]

Published

2022

5. Optomechanics-Based Quantum Estimation Theory for Collapse Models

Author

Marta Maria Marchese, Alessio Belenchia, and Mauro Paternostro

Subjects

quantum metrology, quantum optomechaincs, collapse models, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We make use of the powerful formalism of quantum parameter estimation to assess the characteristic rates of a continuous spontaneous localization (CSL) model affecting the motion of a massive mechanical system. We show that a study performed in non-equilibrium conditions unveils the advantages provided by the use of genuinely quantum resources—such as quantum correlations—in estimating the CSL-induced diffusion rate. In stationary conditions, instead, the gap between quantum performance and a classical scheme disappears. Our investigation contributes to the ongoing effort aimed at identifying suitable conditions for the experimental assessment of collapse models.

Published

2023

6. Better Heisenberg Limits, Coherence Bounds, and Energy-Time Tradeoffs via Quantum Rényi Information

Author

Michael J. W. Hall

Subjects

uncertainty relations, Rényi entropy, Heisenberg limit, quantum metrology, asymmetry, coherence, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

An uncertainty relation for the Rényi entropies of conjugate quantum observables is used to obtain a strong Heisenberg limit of the form RMSE≥f(α)/(⟨N⟩+12), bounding the root mean square error of any estimate of a random optical phase shift in terms of average photon number, where f(α) is maximised for non-Shannon entropies. Related simple yet strong uncertainty relations linking phase uncertainty to the photon number distribution, such as ΔΦ≥maxnpn, are also obtained. These results are significantly strengthened via upper and lower bounds on the Rényi mutual information of quantum communication channels, related to asymmetry and convolution, and applied to the estimation (with prior information) of unitary shift parameters such as rotation angle and time, and to obtain strong bounds on measures of coherence. Sharper Rényi entropic uncertainty relations are also obtained, including time-energy uncertainty relations for Hamiltonians with discrete spectra. In the latter case almost-periodic Rényi entropies are introduced for nonperiodic systems.

Published

2022

7. Critical Quantum Metrology in the Non-Linear Quantum Rabi Model

Author

Zu-Jian Ying, Simone Felicetti, Gang Liu, and Daniel Braak

Subjects

finite component phase transition, quantum metrology, quantum Rabi model, nonlinear coupling, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

The quantum Rabi model (QRM) with linear coupling between light mode and qubit exhibits the analog of a second-order phase transition for vanishing mode frequency which allows for criticality-enhanced quantum metrology in a few-body system. We show that the QRM including a nonlinear coupling term exhibits much higher measurement precisions due to its first-order-like phase transition at finite frequency, avoiding the detrimental slowing-down effect close to the critical point of the linear QRM. When a bias term is added to the Hamiltonian, the system can be used as a fluxmeter or magnetometer if implemented in circuit QED platforms.

Published

2022

8. Quantum Probes for the Characterization of Nonlinear Media

Author

Alessandro Candeloro, Sholeh Razavian, Matteo Piccolini, Berihu Teklu, Stefano Olivares, and Matteo G. A. Paris

Subjects

quantum sensing, quantum metrology, quantum probes, multiparameter estimation, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Active optical media leading to interaction Hamiltonians of the form H=λ˜(a+a†)ζ represent a crucial resource for quantum optical technology. In this paper, we address the characterization of those nonlinear media using quantum probes, as opposed to semiclassical ones. In particular, we investigate how squeezed probes may improve individual and joint estimation of the nonlinear coupling λ˜ and of the nonlinearity order ζ. Upon using tools from quantum estimation, we show that: (i) the two parameters are compatible, i.e., the may be jointly estimated without additional quantum noise; (ii) the use of squeezed probes improves precision at fixed overall energy of the probe; (iii) for low energy probes, squeezed vacuum represent the most convenient choice, whereas for increasing energy an optimal squeezing fraction may be determined; (iv) using optimized quantum probes, the scaling of the corresponding precision with energy improves, both for individual and joint estimation of the two parameters, compared to semiclassical coherent probes. We conclude that quantum probes represent a resource to enhance precision in the characterization of nonlinear media, and foresee potential applications with current technology.

Published

2021

9. Strategies for Positive Partial Transpose (PPT) States in Quantum Metrologies with Noise

Author

Arunava Majumder, Harshank Shrotriya, and Leong-Chuan Kwek

Subjects

PPT, quantum metrology, entanglement, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Quantum metrology overcomes standard precision limits and has the potential to play a key role in quantum sensing. Quantum mechanics, through the Heisenberg uncertainty principle, imposes limits on the precision of measurements. Conventional bounds to the measurement precision such as the shot noise limit are not as fundamental as the Heisenberg limits, and can be beaten with quantum strategies that employ ‘quantum tricks’ such as squeezing and entanglement. Bipartite entangled quantum states with a positive partial transpose (PPT), i.e., PPT entangled states, are usually considered to be too weakly entangled for applications. Since no pure entanglement can be distilled from them, they are also called bound entangled states. We provide strategies, using which multipartite quantum states that have a positive partial transpose with respect to all bi-partitions of the particles can still outperform separable states in linear interferometers.

Published

2021

10. Entanglement and Non-Locality in Quantum Protocols with Identical Particles

Author

Fabio Benatti, Roberto Floreanini, and Ugo Marzolino

Subjects

entanglement theory, identical particles, quantum metrology, interferometry, quantum teleportation, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We study the role of entanglement and non-locality in quantum protocols that make use of systems of identical particles. Unlike in the case of distinguishable particles, the notions of entanglement and non-locality for systems whose constituents cannot be distinguished and singly addressed are still debated. We clarify why the only approach that avoids incongruities and paradoxes is the one based on the second quantization formalism, whereby it is the entanglement of the modes that can be populated by the particles that really matters and not the particles themselves. Indeed, by means of a metrological and of a teleportation protocol, we show that inconsistencies arise in formulations that force entanglement and non-locality to be properties of the identical particles rather than of the modes they can occupy. The reason resides in the fact that orthogonal modes can always be addressed while identical particles cannot.

Published

2021

11. From Rényi Entropy Power to Information Scan of Quantum States

Author

Petr Jizba, Jacob Dunningham, and Martin Prokš

Subjects

Rényi entropy, Tsallis entropy, entropic uncertainty relations, quantum metrology, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

In this paper, we generalize the notion of Shannon’s entropy power to the Rényi-entropy setting. With this, we propose generalizations of the de Bruijn identity, isoperimetric inequality, or Stam inequality. This framework not only allows for finding new estimation inequalities, but it also provides a convenient technical framework for the derivation of a one-parameter family of Rényi-entropy-power-based quantum-mechanical uncertainty relations. To illustrate the usefulness of the Rényi entropy power obtained, we show how the information probability distribution associated with a quantum state can be reconstructed in a process that is akin to quantum-state tomography. We illustrate the inner workings of this with the so-called “cat states”, which are of fundamental interest and practical use in schemes such as quantum metrology. Salient issues, including the extension of the notion of entropy power to Tsallis entropy and ensuing implications in estimation theory, are also briefly discussed.

Published

2021

12. Shortcut-to-Adiabaticity-Like Techniques for Parameter Estimation in Quantum Metrology

Author

Marina Cabedo-Olaya, Juan Gonzalo Muga, and Sofía Martínez-Garaot

Subjects

shortcuts to adiabaticity, quantum metrology, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Quantum metrology makes use of quantum mechanics to improve precision measurements and measurement sensitivities. It is usually formulated for time-independent Hamiltonians, but time-dependent Hamiltonians may offer advantages, such as a T4 time dependence of the Fisher information which cannot be reached with a time-independent Hamiltonian. In Optimal adaptive control for quantum metrology with time-dependent Hamiltonians (Nature Communications 8, 2017), Shengshi Pang and Andrew N. Jordan put forward a Shortcut-to-adiabaticity (STA)-like method, specifically an approach formally similar to the “counterdiabatic approach”, adding a control term to the original Hamiltonian to reach the upper bound of the Fisher information. We revisit this work from the point of view of STA to set the relations and differences between STA-like methods in metrology and ordinary STA. This analysis paves the way for the application of other STA-like techniques in parameter estimation. In particular we explore the use of physical unitary transformations to propose alternative time-dependent Hamiltonians which may be easier to implement in the laboratory.

Published

2020

13. Scattering as a Quantum Metrology Problem: A Quantum Walk Approach

Author

Francesco Zatelli, Claudia Benedetti, and Matteo G. A. Paris

Subjects

quantum walks, scattering, quantum metrology, quantum Fisher information, optimal measurement, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

We address the scattering of a quantum particle by a one-dimensional barrier potential over a set of discrete positions. We formalize the problem as a continuous-time quantum walk on a lattice with an impurity and use the quantum Fisher information as a means to quantify the maximal possible accuracy in the estimation of the height of the barrier. We introduce suitable initial states of the walker and derive the reflection and transmission probabilities of the scattered state. We show that while the quantum Fisher information is affected by the width and central momentum of the initial wave packet, this dependency is weaker for the quantum signal-to-noise ratio. We also show that a dichotomic position measurement provides a nearly optimal detection scheme.

Published

2020

14. On the Quantumness of Multiparameter Estimation Problems for Qubit Systems

Author

Sholeh Razavian, Matteo G. A. Paris, and Marco G. Genoni

Subjects

quantum sensing, quantum metrology, quantum probes, multiparameter estimation, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

The estimation of more than one parameter in quantum mechanics is a fundamental problem with relevant practical applications. In fact, the ultimate limits in the achievable estimation precision are ultimately linked with the non-commutativity of different observables, a peculiar property of quantum mechanics. We here consider several estimation problems for qubit systems and evaluate the corresponding quantumnessR, a measure that has been recently introduced in order to quantify how incompatible the parameters to be estimated are. In particular, R is an upper bound for the renormalized difference between the (asymptotically achievable) Holevo bound and the SLD Cramér-Rao bound (i.e., the matrix generalization of the single-parameter quantum Cramér-Rao bound). For all the estimation problems considered, we evaluate the quantumness R and, in order to better understand its usefulness in characterizing a multiparameter quantum statistical model, we compare it with the renormalized difference between the Holevo and the SLD-bound. Our results give evidence that R is a useful quantity to characterize multiparameter estimation problems, as for several quantum statistical model, it is equal to the difference between the bounds and, in general, their behavior qualitatively coincide. On the other hand, we also find evidence that, for certain quantum statistical models, the bound is not in tight, and thus R may overestimate the degree of quantum incompatibility between parameters.

Published

2020

15. Witnessing Multipartite Entanglement by Detecting Asymmetry.

Author

Girolami, Davide and Yadin, Benjamin

Subjects

*QUANTUM entanglement, *QUANTUM coherence, *QUANTUM states, *QUBITS, *QUANTUM information theory

Abstract

The characterization of quantum coherence in the context of quantum information theory and its interplay with quantum correlations is currently subject of intense study. Coherence in a Hamiltonian eigenbasis yields asymmetry, the ability of a quantum system to break a dynamical symmetry generated by the Hamiltonian. We here propose an experimental strategy to witness multipartite entanglement in many-body systems by evaluating the asymmetry with respect to an additive Hamiltonian. We test our scheme by simulating asymmetry and entanglement detection in a three-qubit Greenberger-Horne-Zeilinger (GHZ) diagonal state. [ABSTRACT FROM AUTHOR]

Published

2017

16. Frequentist and Bayesian Quantum Phase Estimation

Author

Yan Li, Luca Pezzè, Manuel Gessner, Zhihong Ren, Weidong Li, and Augusto Smerzi

Subjects

quantum metrology, Bayesian estimation, parameter estimation, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Frequentist and Bayesian phase estimation strategies lead to conceptually different results on the state of knowledge about the true value of an unknown parameter. We compare the two frameworks and their sensitivity bounds to the estimation of an interferometric phase shift limited by quantum noise, considering both the cases of a fixed and a fluctuating parameter. We point out that frequentist precision bounds, such as the Cramér–Rao bound, for instance, do not apply to Bayesian strategies and vice versa. In particular, we show that the Bayesian variance can overcome the frequentist Cramér–Rao bound, which appears to be a paradoxical result if the conceptual difference between the two approaches are overlooked. Similarly, bounds for fluctuating parameters make no statement about the estimation of a fixed parameter.

Published

2018

17. Symmetric Logarithmic Derivative of Fermionic Gaussian States

Author

Angelo Carollo, Bernardo Spagnolo, and Davide Valenti

Subjects

quantum metrology, Fermionic Gaussian state, quantum geometric information, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

In this article, we derive a closed form expression for the symmetric logarithmic derivative of Fermionic Gaussian states. This provides a direct way of computing the quantum Fisher Information for Fermionic Gaussian states. Applications range from quantum Metrology with thermal states to non-equilibrium steady states with Fermionic many-body systems.

Published

2018

18. Quantum Probes for the Characterization of Nonlinear Media

Author

Stefano Olivares, Matteo G. A. Paris, Berihu Teklu, Matteo Piccolini, Alessandro Candeloro, and Sholeh Razavian

Subjects

Science, QC1-999, Optical engineering, FOS: Physical sciences, General Physics and Astronomy, Semiclassical physics, Astrophysics, quantum probes, Computer Science::Digital Libraries, Article, Quantum metrology, Statistical physics, quantum sensing, Quantum, Physics, Quantum Physics, Quantum noise, Quantum sensor, quantum metrology, QB460-466, Nonlinear system, multiparameter estimation, Computer Science::Programming Languages, Quantum Physics (quant-ph), Energy (signal processing)

Abstract

Active optical media leading to interaction Hamiltonians of the form H=λ˜(a+a†)ζ represent a crucial resource for quantum optical technology. In this paper, we address the characterization of those nonlinear media using quantum probes, as opposed to semiclassical ones. In particular, we investigate how squeezed probes may improve individual and joint estimation of the nonlinear coupling λ˜ and of the nonlinearity order ζ. Upon using tools from quantum estimation, we show that: (i) the two parameters are compatible, i.e., the may be jointly estimated without additional quantum noise, (ii) the use of squeezed probes improves precision at fixed overall energy of the probe, (iii) for low energy probes, squeezed vacuum represent the most convenient choice, whereas for increasing energy an optimal squeezing fraction may be determined, (iv) using optimized quantum probes, the scaling of the corresponding precision with energy improves, both for individual and joint estimation of the two parameters, compared to semiclassical coherent probes. We conclude that quantum probes represent a resource to enhance precision in the characterization of nonlinear media, and foresee potential applications with current technology.

Published

2021

19. Witnessing Multipartite Entanglement by Detecting Asymmetry

Author

Davide Girolami and Benjamin Yadin

Subjects

quantum information, quantum coherence, entanglement, quantum metrology, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

The characterization of quantum coherence in the context of quantum information theory and its interplay with quantum correlations is currently subject of intense study. Coherence in a Hamiltonian eigenbasis yields asymmetry, the ability of a quantum system to break a dynamical symmetry generated by the Hamiltonian. We here propose an experimental strategy to witness multipartite entanglement in many-body systems by evaluating the asymmetry with respect to an additive Hamiltonian. We test our scheme by simulating asymmetry and entanglement detection in a three-qubit Greenberger–Horne–Zeilinger (GHZ) diagonal state.

Published

2017

20. From Rényi Entropy Power to Information Scan of Quantum States

Author

Jacob Dunningham, Martin Prokš, and Petr Jizba

Subjects

Computer science, Tsallis entropy, General Physics and Astronomy, lcsh:Astrophysics, 02 engineering and technology, 01 natural sciences, Article, Rényi entropy, Quantum state, 0103 physical sciences, lcsh:QB460-466, 0202 electrical engineering, electronic engineering, information engineering, Quantum metrology, Entropy (information theory), Statistical physics, 010306 general physics, lcsh:Science, Mathematical Physics, De Bruijn sequence, Quantum Physics, quantum metrology, 020206 networking & telecommunications, lcsh:QC1-999, entropic uncertainty relations, Probability distribution, lcsh:Q, Isoperimetric inequality, lcsh:Physics

Abstract

In the estimation theory context, we generalize the notion of Shannon's entropy power to the R\'{e}nyi-entropy setting. This not only allows to find new estimation inequalities, such as the R\'{e}nyi-entropy based De Bruijn identity, isoperimetric inequality or Stam inequality, but it also provides a convenient technical framework for the derivation of a one-parameter family of R\'{e}nyi-entropy-power-based quantum-mechanical uncertainty relations. To put more flesh on the bones, we use the R\'{e}nyi entropy power obtained to show how the information probability distribution associated with a quantum state can be reconstructed in a process that is akin to quantum-state tomography. We illustrate the inner workings of this with the so-called "cat states", which are of fundamental interest and practical use in schemes such as quantum metrology. Salient issues, including the extension of the notion of entropy power to Tsallis entropy and ensuing implications in estimation theory are also briefly discussed., Comment: 28 pages, 2 figures

Published

2021

21. Quantum Probes for the Characterization of Nonlinear Media.

Author

Candeloro, Alessandro, Razavian, Sholeh, Piccolini, Matteo, Teklu, Berihu, Olivares, Stefano, and Paris, Matteo G. A.

Subjects

*QUANTUM noise, *NONLINEAR estimation, *ACTIVE medium, *PARAMETER estimation, *NONLINEAR oscillators

Abstract

Active optical media leading to interaction Hamiltonians of the form H = λ ˜ (a + a †) ζ represent a crucial resource for quantum optical technology. In this paper, we address the characterization of those nonlinear media using quantum probes, as opposed to semiclassical ones. In particular, we investigate how squeezed probes may improve individual and joint estimation of the nonlinear coupling λ ˜ and of the nonlinearity order ζ. Upon using tools from quantum estimation, we show that: (i) the two parameters are compatible, i.e., the may be jointly estimated without additional quantum noise; (ii) the use of squeezed probes improves precision at fixed overall energy of the probe; (iii) for low energy probes, squeezed vacuum represent the most convenient choice, whereas for increasing energy an optimal squeezing fraction may be determined; (iv) using optimized quantum probes, the scaling of the corresponding precision with energy improves, both for individual and joint estimation of the two parameters, compared to semiclassical coherent probes. We conclude that quantum probes represent a resource to enhance precision in the characterization of nonlinear media, and foresee potential applications with current technology. [ABSTRACT FROM AUTHOR]

Published

2021

22. Strategies for Positive Partial Transpose (PPT) States in Quantum Metrologies with Noise.

Author

Majumder, Arunava, Shrotriya, Harshank, and Kwek, Leong-Chuan

Subjects

*QUANTUM states, *QUANTUM entanglement, *HEISENBERG uncertainty principle, *QUANTUM noise, *QUANTUM mechanics, *BOUND states

Abstract

Quantum metrology overcomes standard precision limits and has the potential to play a key role in quantum sensing. Quantum mechanics, through the Heisenberg uncertainty principle, imposes limits on the precision of measurements. Conventional bounds to the measurement precision such as the shot noise limit are not as fundamental as the Heisenberg limits, and can be beaten with quantum strategies that employ 'quantum tricks' such as squeezing and entanglement. Bipartite entangled quantum states with a positive partial transpose (PPT), i.e., PPT entangled states, are usually considered to be too weakly entangled for applications. Since no pure entanglement can be distilled from them, they are also called bound entangled states. We provide strategies, using which multipartite quantum states that have a positive partial transpose with respect to all bi-partitions of the particles can still outperform separable states in linear interferometers. [ABSTRACT FROM AUTHOR]

Published

2021

23. Frequentist and Bayesian Quantum Phase Estimation

Author

Zhihong Ren, Yan Li, Weidong Li, Manuel Gessner, Augusto Smerzi, and Luca Pezzè

Subjects

Bayesian probability, General Physics and Astronomy, FOS: Physical sciences, lcsh:Astrophysics, 01 natural sciences, Article, 010305 fluids & plasmas, Frequentist inference, 0103 physical sciences, lcsh:QB460-466, Quantum metrology, Applied mathematics, Sensitivity (control systems), 010306 general physics, lcsh:Science, Mathematics, Quantum Physics, Bayes estimator, Estimation theory, Quantum noise, quantum metrology, Variance (accounting), Bayesian estimation, lcsh:QC1-999, Statistics::Computation, lcsh:Q, Quantum Physics (quant-ph), parameter estimation, lcsh:Physics

Abstract

Frequentist and Bayesian phase estimation strategies lead to conceptually different results on the state of knowledge about the true value of an unknown parameter. We compare the two frameworks and their sensitivity bounds to the estimation of an interferometric phase shift limited by quantum noise, considering both the cases of a fixed and a fluctuating parameter. We point out that frequentist precision bounds, such as the Cram&eacute, r&ndash, Rao bound, for instance, do not apply to Bayesian strategies and vice versa. In particular, we show that the Bayesian variance can overcome the frequentist Cram&eacute, Rao bound, which appears to be a paradoxical result if the conceptual difference between the two approaches are overlooked. Similarly, bounds for fluctuating parameters make no statement about the estimation of a fixed parameter.

Published

2018

24. Entanglement and Non-Locality in Quantum Protocols with Identical Particles.

Author

Benatti, Fabio, Floreanini, Roberto, and Marzolino, Ugo

Subjects

*QUANTUM entanglement, *QUANTUM teleportation, *TELEPORTATION

Abstract

We study the role of entanglement and non-locality in quantum protocols that make use of systems of identical particles. Unlike in the case of distinguishable particles, the notions of entanglement and non-locality for systems whose constituents cannot be distinguished and singly addressed are still debated. We clarify why the only approach that avoids incongruities and paradoxes is the one based on the second quantization formalism, whereby it is the entanglement of the modes that can be populated by the particles that really matters and not the particles themselves. Indeed, by means of a metrological and of a teleportation protocol, we show that inconsistencies arise in formulations that force entanglement and non-locality to be properties of the identical particles rather than of the modes they can occupy. The reason resides in the fact that orthogonal modes can always be addressed while identical particles cannot. [ABSTRACT FROM AUTHOR]

Published

2021

25. From Rényi Entropy Power to Information Scan of Quantum States.

Author

Jizba, Petr, Dunningham, Jacob, Prokš, Martin, and Barron, Andrew

Subjects

*ESTIMATION theory, *ENTROPY (Information theory), *QUANTUM information theory, *ISOPERIMETRIC inequalities, *DISTRIBUTION (Probability theory), *ENTROPIC uncertainty, *QUANTUM states

Abstract

In this paper, we generalize the notion of Shannon's entropy power to the Rényi-entropy setting. With this, we propose generalizations of the de Bruijn identity, isoperimetric inequality, or Stam inequality. This framework not only allows for finding new estimation inequalities, but it also provides a convenient technical framework for the derivation of a one-parameter family of Rényi-entropy-power-based quantum-mechanical uncertainty relations. To illustrate the usefulness of the Rényi entropy power obtained, we show how the information probability distribution associated with a quantum state can be reconstructed in a process that is akin to quantum-state tomography. We illustrate the inner workings of this with the so-called "cat states", which are of fundamental interest and practical use in schemes such as quantum metrology. Salient issues, including the extension of the notion of entropy power to Tsallis entropy and ensuing implications in estimation theory, are also briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2021

26. Scattering as a Quantum Metrology Problem: A Quantum Walk Approach.

Author

Zatelli, Francesco, Benedetti, Claudia, and Paris, Matteo G. A.

Subjects

*QUANTUM scattering, *FISHER information, *METROLOGY, *SCATTERING (Physics), *SIGNAL-to-noise ratio, *WAVE packets

Abstract

We address the scattering of a quantum particle by a one-dimensional barrier potential over a set of discrete positions. We formalize the problem as a continuous-time quantum walk on a lattice with an impurity and use the quantum Fisher information as a means to quantify the maximal possible accuracy in the estimation of the height of the barrier. We introduce suitable initial states of the walker and derive the reflection and transmission probabilities of the scattered state. We show that while the quantum Fisher information is affected by the width and central momentum of the initial wave packet, this dependency is weaker for the quantum signal-to-noise ratio. We also show that a dichotomic position measurement provides a nearly optimal detection scheme. [ABSTRACT FROM AUTHOR]

Published

2020

27. Shortcut-to-Adiabaticity-Like Techniques for Parameter Estimation in Quantum Metrology.

Author

Cabedo-Olaya, Marina, Muga, Juan Gonzalo, and Martínez-Garaot, Sofía

Subjects

*METROLOGY, *FISHER information, *UNITARY transformations, *ADAPTIVE control systems, *QUANTUM mechanics

Abstract

Quantum metrology makes use of quantum mechanics to improve precision measurements and measurement sensitivities. It is usually formulated for time-independent Hamiltonians, but time-dependent Hamiltonians may offer advantages, such as a T 4 time dependence of the Fisher information which cannot be reached with a time-independent Hamiltonian. In Optimal adaptive control for quantum metrology with time-dependent Hamiltonians (Nature Communications 8, 2017), Shengshi Pang and Andrew N. Jordan put forward a Shortcut-to-adiabaticity (STA)-like method, specifically an approach formally similar to the "counterdiabatic approach", adding a control term to the original Hamiltonian to reach the upper bound of the Fisher information. We revisit this work from the point of view of STA to set the relations and differences between STA-like methods in metrology and ordinary STA. This analysis paves the way for the application of other STA-like techniques in parameter estimation. In particular we explore the use of physical unitary transformations to propose alternative time-dependent Hamiltonians which may be easier to implement in the laboratory. [ABSTRACT FROM AUTHOR]

Published

2020

28. On the Quantumness of Multiparameter Estimation Problems for Qubit Systems.

Author

Razavian, Sholeh, Paris, Matteo G. A., and Genoni, Marco G.

Subjects

*STATISTICAL models, *QUANTUM mechanics, *GENERALIZATION

Abstract

The estimation of more than one parameter in quantum mechanics is a fundamental problem with relevant practical applications. In fact, the ultimate limits in the achievable estimation precision are ultimately linked with the non-commutativity of different observables, a peculiar property of quantum mechanics. We here consider several estimation problems for qubit systems and evaluate the corresponding quantumness R , a measure that has been recently introduced in order to quantify how incompatible the parameters to be estimated are. In particular, R is an upper bound for the renormalized difference between the (asymptotically achievable) Holevo bound and the SLD Cramér-Rao bound (i.e., the matrix generalization of the single-parameter quantum Cramér-Rao bound). For all the estimation problems considered, we evaluate the quantumness R and, in order to better understand its usefulness in characterizing a multiparameter quantum statistical model, we compare it with the renormalized difference between the Holevo and the SLD-bound. Our results give evidence that R is a useful quantity to characterize multiparameter estimation problems, as for several quantum statistical model, it is equal to the difference between the bounds and, in general, their behavior qualitatively coincide. On the other hand, we also find evidence that, for certain quantum statistical models, the bound is not in tight, and thus R may overestimate the degree of quantum incompatibility between parameters. [ABSTRACT FROM AUTHOR]

Published

2020

29. Time in Quantum Measurement

Author

Andreas E. Schlatter

Subjects

Physics, Measurement, Energy, General Physics and Astronomy, lcsh:Astrophysics, Quantum Entropy, lcsh:QC1-999, Time, Quantum probability, Open quantum system, Quantum error correction, Quantum process, Quantum mechanics, lcsh:QB460-466, Quantum metrology, Quantum operation, lcsh:Q, Quantum algorithm, lcsh:Science, Quantum dissipation, lcsh:Physics

Abstract

Based on a model of quantum measurement we derive an estimate for the external measurement-time. Some interesting consequences will be analyzed.

Published

2006

30. Frequentist and Bayesian Quantum Phase Estimation.

Author

Li, Yan, Pezzè, Luca, Gessner, Manuel, Ren, Zhihong, Li, Weidong, and Smerzi, Augusto

Subjects

*FREQUENTIST statistics, *QUANTUM phase transitions, *PHASE estimation (Electronics), *MATHEMATICAL bounds, *BAYESIAN analysis

Abstract

Frequentist and Bayesian phase estimation strategies lead to conceptually different results on the state of knowledge about the true value of an unknown parameter. We compare the two frameworks and their sensitivity bounds to the estimation of an interferometric phase shift limited by quantum noise, considering both the cases of a fixed and a fluctuating parameter. We point out that frequentist precision bounds, such as the Cramér–Rao bound, for instance, do not apply to Bayesian strategies and vice versa. In particular, we show that the Bayesian variance can overcome the frequentist Cramér–Rao bound, which appears to be a paradoxical result if the conceptual difference between the two approaches are overlooked. Similarly, bounds for fluctuating parameters make no statement about the estimation of a fixed parameter. [ABSTRACT FROM AUTHOR]

Published

2018

31. Symmetric Logarithmic Derivative of Fermionic Gaussian States.

Author

Carollo, Angelo, Spagnolo, Bernardo, and Valenti, Davide

Subjects

*MATHEMATICAL symmetry, *LOGARITHMIC functions, *DERIVATIVES (Mathematics), *GAUSSIAN processes, *QUANTUM theory

Abstract

In this article, we derive a closed form expression for the symmetric logarithmic derivative of Fermionic Gaussian states. This provides a direct way of computing the quantum Fisher Information for Fermionic Gaussian states. Applications range from quantum Metrology with thermal states to non-equilibrium steady states with Fermionic many-body systems. [ABSTRACT FROM AUTHOR]

Published

2018

32. [Untitled]

Subjects

Physics, media_common.quotation_subject, General Physics and Astronomy, Quantum Physics, Quantum entanglement, 01 natural sciences, Asymmetry, Multipartite entanglement, 010305 fluids & plasmas, symbols.namesake, Quantum mechanics, 0103 physical sciences, symbols, Quantum system, Quantum metrology, Quantum information, 010306 general physics, Hamiltonian (quantum mechanics), Quantum, media_common

Abstract

The characterization of quantum coherence in the context of quantum information theory and its interplay with quantum correlations is currently subject of intense study. Coherence in a Hamiltonian eigenbasis yields asymmetry, the ability of a quantum system to break a dynamical symmetry generated by the Hamiltonian. We here propose an experimental strategy to witness multipartite entanglement in many-body systems by evaluating the asymmetry with respect to an additive Hamiltonian. We test our scheme by simulating asymmetry and entanglement detection in a three-qubit Greenberger–Horne–Zeilinger (GHZ) diagonal state.