Your search keyword '"Assad, Syed M"' showing total 173 results

1. Attainability of quantum state discrimination bounds with collective measurements on finite copies

Author

Conlon, Lorcan, Koh, Jin Ming, Shajilal, Biveen, Sidhu, Jasminder, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

One of the fundamental tenets of quantum mechanics is that non-orthogonal states cannot be distinguished perfectly. When distinguishing multiple copies of a mixed quantum state, a collective measurement, which generates entanglement between the different copies of the unknown state, can achieve a lower error probability than non-entangling measurements. The error probability that can be attained using a collective measurement on a finite number of copies of the unknown state is given by the Helstrom bound. In the limit where we can perform a collective measurement on asymptotically many copies of the quantum state, the quantum Chernoff bound gives the attainable error probability. It is natural to ask at what rate does the error tend to this asymptotic limit, and whether the asymptotic limit can be attained for any finite number of copies. In this paper we address these questions. We find analytic expressions for the Helstrom bound for arbitrarily many copies of the unknown state in several simple qubit examples. Using these analytic expressions, we investigate how the attainable error rate changes as we allow collective measurements on finite numbers of copies of the quantum state. We also investigate the necessary conditions to saturate the M-copy Helstrom bound. It is known that a collective measurement on all M-copies of the unknown state is always sufficient to saturate the M-copy Helstrom bound. However, general conditions for when such a measurement is necessary to saturate the Helstrom bound remain unknown. We investigate specific measurement strategies which involve entangling operations on fewer than all M-copies of the unknown state. For many regimes we find that a collective measurement on all M-copies of the unknown state is necessary to saturate the M-copy Helstrom bound., Comment: Comments very welcome

Published

2024

2. Comparison of estimation limits for quantum two-parameter estimation

Author

Yung, Simon K., Conlon, Lorcan O., Zhao, Jie, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Measurement estimation bounds for local quantum multiparameter estimation, which provide lower bounds on possible measurement uncertainties, have so far been formulated in two ways: by extending the classical Cram\'er--Rao bound (e.g., the quantum Cram\'er--Rao bound and the Nagaoka Cram'er--Rao bound) and by incorporating the parameter estimation framework with the uncertainty principle, as in the Lu--Wang uncertainty relation. In this work, we present a general framework that allows a direct comparison between these different types of estimation limits. Specifically, we compare the attainability of the Nagaoka Cram\'er--Rao bound and the Lu--Wang uncertainty relation, using analytical and numerical techniques. We show that these two limits can provide different information about the physically attainable precision. We present an example where both limits provide the same attainable precision and an example where the Lu--Wang uncertainty relation is not attainable even for pure states. We further demonstrate that the unattainability in the latter case arises because the figure of merit underpinning the Lu--Wang uncertainty relation (the difference between the quantum and classical Fisher information matrices) does not necessarily agree with the conventionally used figure of merit (mean squared error). The results offer insights into the general attainability and applicability of the Lu--Wang uncertainty relation. Furthermore, our proposed framework for comparing bounds of different types may prove useful in other settings., Comment: 13 pages, 7 figures

Published

2024

3. Holevo Cram\'er-Rao bound: How close can we get without entangling measurements?

Author

Das, Aritra, Conlon, Lorcán O., Suzuki, Jun, Yung, Simon K., Lam, Ping K., and Assad, Syed M.

Subjects

Quantum Physics, Mathematical Physics, Physics - Data Analysis, Statistics and Probability

Abstract

In multi-parameter quantum metrology, the resource of entanglement can lead to an increase in efficiency of the estimation process. Entanglement can be used in the state preparation stage, or the measurement stage, or both, to harness this advantage; here we focus on the role of entangling measurements. Specifically, entangling or collective measurements over multiple identical copies of a probe state are known to be superior to measuring each probe individually, but the extent of this improvement is an open problem. It is also known that such entangling measurements, though resource-intensive, are required to attain the ultimate limits in multi-parameter quantum metrology and quantum information processing tasks. In this work we investigate the maximum precision improvement that collective quantum measurements can offer over individual measurements for estimating parameters of qudit states, calling this the 'collective quantum enhancement'. We show that, whereas the maximum enhancement can, in principle, be a factor of $n$ for estimating $n$ parameters, this bound is not tight for large $n$. Instead, our results prove an enhancement linear in dimension of the qudit is possible using collective measurements and lead us to conjecture that this is the maximum collective quantum enhancement in any local estimation scenario., Comment: 22 pages, 9 figures, 10 appendices; presented at AIP Summer Meeting 2023

Published

2024

4. Entanglement swapping via lossy channels using photon-number-encoded states

Author

Zo, Wan, Bilash, Bohdan, Lee, Donghwa, Kim, Yosep, Lim, Hyang-Tag, Oh, Kyunghwan, Assad, Syed M., and Kim, Yong-Su

Subjects

Quantum Physics

Abstract

Entanglement shared between distant parties is a key resource in quantum networks. However, photon losses in quantum channels significantly reduce the success probability of entanglement sharing, which scales quadratically with the channel transmission. Quantum repeaters using entanglement swapping can mitigate this effect, but usually require high-performance photonic quantum memories to synchronize photonic qubits. In this work, we theoretically and experimentally investigate an entanglement swapping protocol using photon-number-encoded states that can effectively alleviate quantum channel losses without requiring photonic quantum memories. We demonstrate that the protocol exhibits a success probability scaling linearly with the channel transmission. Furthermore, we show that while unbalanced channel losses can degrade the shared entanglement, this effect can be compensated by optimally adjusting the initial entangled states. Our results highlight the potential of photon-number encoding for realizing robust entanglement distribution in lossy quantum networks., Comment: 7 pages, 6 figures, 39 references

Published

2024

5. Role of the extended Hilbert space in the attainability of the Quantum Cram\'er-Rao bound for multiparameter estimation

Author

Conlon, Lorcan O., Suzuki, Jun, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

The symmetric logarithmic derivative Cram\'er-Rao bound (SLDCRB) provides a fundamental limit to the minimum variance with which a set of unknown parameters can be estimated in an unbiased manner. It is known that the SLDCRB can be saturated provided the optimal measurements for the individual parameters commute with one another. However, when this is not the case the SLDCRB cannot be attained in general. In the experimentally relevant setting, where quantum states are measured individually, necessary and sufficient conditions for when the SLDCRB can be saturated are not known. In this setting the SLDCRB is attainable provided the SLD operators can be chosen to commute on an extended Hilbert space. However, beyond this relatively little is known about when the SLD operators can be chosen in this manner. In this paper we present explicit examples which demonstrate novel aspects of this condition. Our examples demonstrate that the SLD operators commuting on any two of the following three spaces: support space, support-kernel space and kernel space, is neither a necessary nor sufficient condition for commutativity on the extended space. We present a simple analytic example showing that the Nagaoka-Hayashi Cram\'er-Rao bound is not always attainable. Finally, we provide necessary and sufficient conditions for the attainability of the SLDCRB in the case when the kernel space is one-dimensional. These results provide new information on the necessary and sufficient conditions for the attainability of the SLDCRB., Comment: Comments very welcome

Published

2024

6. The relative entropy of coherence quantifies performance in Bayesian metrology

Author

Lecamwasam, Ruvi, Assad, Syed M, Hope, Joseph J, Lam, Ping Koy, Thompson, Jayne, and Gu, Mile

Subjects

Quantum Physics

Abstract

The ability of quantum states to be in superposition is one of the key features that sets them apart from the classical world. This `coherence' is rigorously quantified by resource theories, which aim to understand how such properties may be exploited in quantum technologies. There has been much research on what the resource theory of coherence can reveal about quantum metrology, almost all of which has been from the viewpoint of Fisher information. We prove however that the relative entropy of coherence, and its recent generalisation to POVMs, naturally quantify the performance of Bayesian metrology. In particular, we show how a coherence measure can be applied to an ensemble of states. We then prove that during parameter estimation, the ensemble relative entropy of coherence is equal to the difference between the information gained, and the optimal Holevo information. We call this relation the CXI equality. The ensemble coherence lets us visualise how much information is locked away in superposition inaccessible with a given measurement scheme, and quantify the advantage that would be gained by using a joint measurement on multiple states. Our results hold regardless of how the parameter is encoded in the state, encompassing unitary, dissipative, and discrete settings. We consider both projective measurements, and general POVMs. This work suggests new directions for research in quantum resource theories, provides a novel operational interpretation for the relative entropy of coherence and its POVM generalisation, and introduces a new tool to study the role of quantum features in metrology., Comment: 10 pages main + 4 pages supplementary

Published

2024

7. Verifying the security of a continuous variable quantum communication protocol via quantum metrology

Author

Conlon, Lorcan O., Shajilal, Biveen, Walsh, Angus, Zhao, Jie, Janousek, Jiri, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Quantum mechanics offers the possibility of unconditionally secure communication between multiple remote parties. Security proofs for such protocols typically rely on bounding the capacity of the quantum channel in use. In a similar manner, Cram\'er-Rao bounds in quantum metrology place limits on how much information can be extracted from a given quantum state about some unknown parameters of interest. In this work we establish a connection between these two areas. We first demonstrate a three-party sensing protocol, where the attainable precision is dependent on how many parties work together. This protocol is then mapped to a secure access protocol, where only by working together can the parties gain access to some high security asset. Finally, we map the same task to a communication protocol where we demonstrate that a higher mutual information can be achieved when the parties work collaboratively compared to any party working in isolation., Comment: Close to published version: npj Quantum Inf 10, 35 (2024)

Published

2023

8. Testing the postulates of quantum mechanics with coherent states of light and homodyne detection

Author

Conlon, Lorcan O., Walsh, Angus, Hua, Yuhan, Thearle, Oliver, Vogl, Tobias, Eilenberger, Falk, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Quantum mechanics has withstood every experimental test thus far. However, it relies on ad-hoc postulates which require experimental verification. Over the past decade there has been a great deal of research testing these postulates, with numerous tests of Born's rule for determining probabilities and the complex nature of the Hilbert space being carried out. Although these tests are yet to reveal any significant deviation from textbook quantum theory, it remains important to conduct such tests in different configurations and using different quantum states. Here we perform the first such test using coherent states of light in a three-arm interferometer combined with homodyne detection. Our proposed configuration requires additional assumptions, but allows us to use quantum states which exist in a larger Hilbert space compared to previous tests. For testing Born's rule, we find that the third order interference is bounded to be $\kappa$ = 0.002 $\pm$ 0.004 and for testing whether quantum mechanics is complex or not we find a Peres parameter of F = 1.0000 $\pm$ 0.0003 (F = 1 corresponds to the expected complex quantum mechanics). We also use our experiment to test Glauber's theory of optical coherence., Comment: 11 pages, comments very welcome

Published

2023

9. Multiparameter estimation with two qubit probes in noisy channels

Author

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

Subjects

Quantum Physics

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 Cram\'er-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 which 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-style nature of this paper will make it easily accessible., Comment: Tutorial-type case study for multiparameter estimation,27 pages and 10 pages supplementary

Published

2023

10. On the equivalence between squeezing and entanglement potential for two-mode Gaussian states

Author

Li, Bohan, Das, Aritra, Tserkis, Spyros, Narang, Prineha, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics, Physics - Optics

Abstract

The maximum amount of entanglement achievable under passive transformations by continuous-variable states is called the entanglement potential. Recent work has demonstrated that the entanglement potential is upper-bounded by a simple function of the squeezing of formation, and that certain classes of two-mode Gaussian states can indeed saturate this bound, though saturability in the general case remains an open problem. In this study, we introduce a larger class of states that we prove saturates the bound, and we conjecture that all two-mode Gaussian states can be passively transformed into this class, meaning that for all two-mode Gaussian states, entanglement potential is equivalent to squeezing of formation. We provide an explicit algorithm for the passive transformations and perform extensive numerical testing of our claim, which seeks to unite the resource theories of two characteristic quantum properties of continuous-variable systems., Comment: 10 pages, 2 figures

Published

2023

11. Quantifying total correlations in quantum systems through the Pearson correlation coefficient

Author

Tserkis, Spyros, Assad, Syed M., Lam, Ping Koy, and Narang, Prineha

Subjects

Quantum Physics

Abstract

Conventionally, the total correlations within a quantum system are quantified through distance-based expressions such as the relative entropy or the square-norm. Those expressions imply that a quantum state can contain both classical and quantum correlations. In this work, we provide an alternative method to quantify the total correlations through the Pearson correlation coefficient. Using this method, we argue that a quantum state can be correlated in either a classical or a quantum way, i.e., the two cases are mutually exclusive. We also illustrate that, at least for the case of two-qubit systems, the distribution of the correlations among certain locally incompatible pairs of observables provides insight in regards to whether a system contains classical or quantum correlations. Finally, we show how correlations in quantum systems are connected to the general entropic uncertainty principle., Comment: 8 pages, 3 figures

Published

2023

12. Verifying the security of a continuous variable quantum communication protocol via quantum metrology

Author

Conlon, Lorcán O., Shajilal, Biveen, Walsh, Angus, Zhao, Jie, Janousek, Jiri, Lam, Ping Koy, and Assad, Syed M.

Published

2024

13. Discriminating mixed qubit states with collective measurements

Author

Conlon, Lorcan O., Eilenberger, Falk, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

It is a central fact in quantum mechanics that non-orthogonal states cannot be distinguished perfectly. This property ensures the security of quantum key distribution. It is therefore an important task in quantum communication to design and implement strategies to optimally distinguish quantum states. In general, when we have access to multiple copies of quantum states the optimal measurement will be a collective measurement. However, to date, collective measurements have not been used to enhance quantum state discrimination. One of the main reasons for this is the fact that, in the usual state discrimination setting with equal prior probabilities, at least three copies of a quantum state are required to be measured collectively to outperform separable measurements. This is very challenging experimentally. In this work, by considering unequal prior probabilities, we propose and experimentally demonstrate a protocol for distinguishing two copies of single qubit states using collective measurements which achieves a lower probability of error than can be achieved by any non-entangling measurement. We implement our measurements on an IBM Q System One device, a superconducting quantum processor. Additionally, we implemented collective measurements on three and four copies of the unknown state and found they performed poorly., Comment: Close to published version, published in Nature Communications Physics

Published

2023

14. Optimal Single Qubit Tomography: Realization of Locally Optimal Measurements on a Quantum Computer

Author

Li, Bacui, Conlon, Lorcan O., Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Quantum bits, or qubits, are the fundamental building blocks of present quantum computers. Hence, it is important to be able to characterize the state of a qubit as accurately as possible. By evaluating the qubit characterization problem from the viewpoint of quantum metrology, we are able to find optimal measurements under the assumption of good prior knowledge. We implement these measurements on a superconducting quantum computer. Our experiment produces sufficiently low error to allow the saturation of the theoretical limits, given by the Nagaoka--Hayashi bound. We also present simulations of adaptive measurement schemes utilizing the proposed method. The results of the simulations show the robustness of the method in characterizing arbitrary qubit states with different amounts of prior knowledge.

Published

2023

15. An Expressive Ansatz for Low-Depth Quantum Approximate Optimisation

Author

Vijendran, V., Das, Aritra, Koh, Dax Enshan, Assad, Syed M., and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

The quantum approximate optimisation algorithm (QAOA) is a hybrid quantum-classical algorithm used to approximately solve combinatorial optimisation problems. It involves multiple iterations of a parameterised ansatz comprising a problem and mixer Hamiltonian, with the parameters being classically optimised. While QAOA can be implemented on NISQ devices, physical limitations can limit circuit depth and decrease performance. To address these limitations, this work introduces the eXpressive QAOA (XQAOA), an overparameterised variant of QAOA that assigns more classical parameters to the ansatz to improve its performance at low depths. XQAOA also introduces an additional Pauli-Y component in the mixer Hamiltonian, allowing the mixer to implement arbitrary unitary transformations on each qubit. To benchmark the performance of XQAOA at unit depth, we derive its closed-form expression for the MaxCut problem and compare it to QAOA, Multi-Angle QAOA (MA-QAOA), a classical-relaxed algorithm, and the state-of-the-art Goemans-Williamson algorithm on a set of unweighted regular graphs with 128 and 256 nodes for degrees ranging from 3 to 10. Our results indicate that at unit depth, XQAOA has benign loss landscapes, allowing it to consistently outperform QAOA, MA-QAOA, and the classical-relaxed algorithm on all graph instances and the Goemans-Williamson algorithm on graph instances with degrees greater than 4. Small-scale simulations also reveal that unit-depth XQAOA surpasses both QAOA and MA-QAOA on all tested depths up to five. Additionally, we find an infinite family of graphs for which XQAOA solves MaxCut exactly and analytically show that for some graphs in this family, XQAOA achieves a much larger approximation ratio than QAOA. Overall, XQAOA is a more viable choice for variational quantum optimisation on NISQ devices, offering competitive performance at low depths., Comment: 28 pages, 9 figures

Published

2023

16. Sichere Zufallszahlengenerierung in Systemen mit kontinuierlichen Variablen

Author

Haw, Jing Yan, Assad, Syed M., Lam, Ping Koy, Kollmitzer, Christian, editor, Schauer, Stefan, editor, Rass, Stefan, editor, and Rainer, Benjamin, editor

Published

2024

17. Satellite-to-Ground Continuous Variable Quantum Key Distribution: The Gaussian and Discrete Modulated Protocols in Low Earth Orbit

Author

Sayat, Mikhael, Shajilal, Biveen, Kish, Sebastian P., Assad, Syed M., Symul, Thomas, Lam, Ping Koy, Rattenbury, Nicholas, and Cater, John

Subjects

Quantum Physics, Physics - Space Physics

Abstract

The Gaussian modulated continuous variable quantum key distribution (GM-CVQKD) protocol is known to maximise the mutual information between two parties during quantum key distribution (QKD). An alternative modulation scheme is the discrete modulated CVQKD (DM-CVQKD) protocol. In this paper, we study the Phase Shift Keying (M-PSK) and Quadrature Amplitude Modulation (M QAM) DM-CVQKD protocols along with the GM-CVQKD protocol over a satellite-to-ground link in the low SNR regime. We use a satellite-to-ground link model which takes into account geometric losses, scintillation, and scattering losses from the link distance, atmospheric turbulence, and atmospheric aerosols, respectively. In addition, recent multidimensional (MD) and multilevel coding and multistage decoding (MLC-MSD) reconciliation method models in combination with multiedge-type low-density parity-check (MET-LDPC) code models have been used to determine the reconciliation efficiency. The results show that GM-CVQKD outperforms DM-CVQKD. In addition, GM-CVQKD with MD reconciliation outperforms GM-CVQKD with MLC-MSD reconciliation in the finite size limit by producing positive secret key rates at larger link distances and lower elevation angles., Comment: Submitted to IEEE Transactions on Communications. 29 pages, 8 figures

Published

2022

18. Surpassing the repeaterless bound with a photon-number encoded measurement-device-independent quantum key distribution protocol

Author

Erkilic, Ozlem, Conlon, Lorcan, Shajilal, Biveen, Kish, Sebastian, Tserkis, Spyros, Kim, Yong-Su, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Decoherence is detrimental to quantum key distribution (QKD) over large distances. One of the proposed solutions is to use quantum repeaters, which divide the total distance between the users into smaller segments to minimise the effects of the losses in the channel. However, the secret key rates that repeater protocols can achieve are fundamentally bounded by the separation between each neighbouring node. Here we introduce a measurement-device-independent protocol which uses high-dimensional states prepared by two distant trusted parties and a coherent total photon number detection for the entanglement swapping measurement at the repeater station. We present an experimentally feasible protocol that can be implemented with current technology as the required states reduce down to the single-photon level over large distances. This protocol outperforms the existing measurement-device-independent and twin-field QKD protocols by surpassing the fundamental limit of the repeaterless bound for the pure-loss channel at a shorter distance and achieves a higher transmission distance in total when experimental imperfections are considered.

Published

2022

19. The gap persistence theorem for quantum multiparameter estimation

Author

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

Subjects

Quantum Physics, Mathematical Physics

Abstract

One key aspect of quantum metrology, measurement incompatibility, is evident only through the simultaneous estimation of multiple parameters. The symmetric logarithmic derivative Cram\'er-Rao bound (SLDCRB), gives the attainable precision, if the optimal measurements for estimating each individual parameter commute. When the optimal measurements do not commute, the SLDCRB is not necessarily attainable. In this regard, the Holevo Cram\'er-Rao bound (HCRB) plays a fundamental role, providing the ultimate attainable precisions when one allows simultaneous measurements on infinitely many copies of a quantum state. For practical purposes, the Nagaoka Cram\'er-Rao bound (NCRB) is more relevant, applying when restricted to measuring quantum states individually. The interplay between these three bounds dictates how rapidly the ultimate metrological precisions can be approached through collective measurements on finite copies of the probe state. We first consider two parameter estimation and prove that if the HCRB cannot be saturated with a single copy of the probe state, then it cannot be saturated for any finite number of copies of the probe state. With this, we show that it is impossible to saturate the HCRB for several physically motivated problems. For estimating any number of parameters, we provide necessary and sufficient conditions for the attainability of the SLDCRB with separable measurements. We further prove that if the SLDCRB cannot be reached with a single copy of the probe state, it cannot be reached with collective measurements on any finite number of copies of the probe state. These results together provide necessary and sufficient conditions for the attainability of the SLDCRB for any finite number of copies of the probe state. This solves a significant generalisation of one of the five problems recently highlighted by [P.Horodecki et al, Phys. Rev. X Quantum 3, 010101 (2022)]., Comment: 11 pages, comments welcome. Corrected error in one proof

Published

2022

20. Comparison of Discrete Variable and Continuous Variable Quantum Key Distribution Protocols with Phase Noise in the Thermal-Loss Channel

Author

Kish, Sebastian P., Gleeson, Patrick J., Walsh, Angus, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Discrete-variable (DV) quantum key distribution (QKD) based on single-photon detectors and sources have been successfully deployed for long-range secure key distribution. On the other hand, continuous-variable (CV) quantum key distribution (QKD) based on coherent detectors and sources is currently lagging behind in terms of loss and noise tolerance. An important discerning factor between DV-QKD and CV-QKD is the effect of phase noise, which is known to be more relevant in CV-QKD. In this article, we investigate the effect of phase noise on DV-QKD and CV-QKD protocols, including the six-state protocol and squeezed-state protocol, in a thermal-loss channel but with the assumed availability of perfect sources and detectors. We find that in the low phase noise regime but high thermal noise regime, CV-QKD can tolerate more loss compared to DV-QKD. We also compare the secret key rate as an additional metric for the performance of QKD. Requirements for this quantity to be high vastly extend the regions at which CV-QKD performs better than DV-QKD. Our analysis addresses the questions of how phase noise affects DV-QKD and CV-QKD and why the former has historically performed better in a thermal-loss channel., Comment: 18 pages + Appendices, 10 figures, Accepted in Quantum 2024-06-17

Published

2022

21. Approaching optimal entangling collective measurements on quantum computing platforms

Author

Conlon, Lorcan O., Vogl, Tobias, Marciniak, Christian D., Pogorelov, Ivan, Yung, Simon K., Eilenberger, Falk, Berry, Dominic W., Santana, Fabiana S., Blatt, Rainer, Monz, Thomas, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Entanglement is a fundamental feature of quantum mechanics and holds great promise for enhancing metrology and communications. Much of the focus of quantum metrology so far has been on generating highly entangled quantum states that offer better sensitivity, per resource, than what can be achieved classically. However, to reach the ultimate limits in multi-parameter quantum metrology and quantum information processing tasks, collective measurements, which generate entanglement between multiple copies of the quantum state, are necessary. Here, we experimentally demonstrate theoretically optimal single- and two-copy collective measurements for simultaneously estimating two non-commuting qubit rotations. This allows us to implement quantum-enhanced sensing, for which the metrological gain persists for high levels of decoherence, and to draw fundamental insights about the interpretation of the uncertainty principle. We implement our optimal measurements on superconducting, trapped-ion and photonic systems, providing an indication of how future quantum-enhanced sensing networks may look., Comment: 6.5 pages, published version

Published

2022

22. Enhancing the precision limits of interferometric satellite geodesy missions

Author

Conlon, Lorcan, Michel, Thibault, Guccione, Giovanni, McKenzie, Kirk, Assad, Syed M., and Lam, Ping Koy

Subjects

Physics - Optics, Physics - Geophysics, Physics - Space Physics, Quantum Physics

Abstract

Satellite geodesy uses the measurement of the motion of one or more satellites to infer precise information about the Earth's gravitational field. In this work, we consider the achievable precision limits on such measurements by examining approximate models for the three main noise sources in the measurement process of the current Gravitational Recovery and Climate Experiment (GRACE) Follow-On mission: laser phase noise, accelerometer noise and quantum noise. We show that, through time-delay interferometry, it is possible to remove the laser phase noise from the measurement, allowing for almost three orders of magnitude improvement in the signal-to-noise ratio. Several differential mass satellite formations are presented which can further enhance the signal-to-noise ratio through the removal of accelerometer noise. Finally, techniques from quantum optics have been studied, and found to have great promise for reducing quantum noise in other alternative mission configurations. We model the spectral noise performance using an intuitive 1D model and verify that our proposals have the potential to greatly enhance the performance of near-future satellite geodesy missions., Comment: Published in NPJ Microgravity

Published

2021

23. Enhancing quantum teleportation efficacy with noiseless linear amplification

Author

Zhao, Jie, Jeng, Hao, Conlon, Lorcán O., Tserkis, Spyros, Shajilal, Biveen, Liu, Kui, Ralph, Timothy C., Assad, Syed M., and Lam, Ping Koy

Published

2023

24. Surpassing the repeaterless bound with a photon-number encoded measurement-device-independent quantum key distribution protocol

Author

Erkılıç, Özlem, Conlon, Lorcán, Shajilal, Biveen, Kish, Sebastian, Tserkis, Spyros, Kim, Yong-Su, Lam, Ping Koy, and Assad, Syed M.

Published

2023

25. Approaching optimal entangling collective measurements on quantum computing platforms

Author

Conlon, Lorcán O., Vogl, Tobias, Marciniak, Christian D., Pogorelov, Ivan, Yung, Simon K., Eilenberger, Falk, Berry, Dominic W., Santana, Fabiana S., Blatt, Rainer, Monz, Thomas, Lam, Ping Koy, and Assad, Syed M.

Published

2023

26. Optimal probes for continuous variable quantum illumination

Author

Bradshaw, Mark, Conlon, Lorcan O., Tserkis, Spyros, Gu, Mile, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Quantum illumination is the task of determining the presence of an object in a noisy environment. We determine the optimal continuous variable states for quantum illumination in the limit of zero object reflectivity. We prove that the optimal single mode state is a coherent state, while the optimal two mode state is the two-mode squeezed-vacuum state. We find that these probes are not optimal at non-zero reflectivity, but remain near optimal. This demonstrates the viability of the continuous variable platform for an experimentally accessible, near optimal quantum illumination implementation., Comment: 7 pages, 3 figures

Published

2020

27. Efficient computation of the Nagaoka--Hayashi bound for multi-parameter estimation with separable measurements

Author

Conlon, Lorcán, Suzuki, Jun, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Finding the optimal attainable precisions in quantum multiparameter metrology is a non trivial problem. One approach to tackling this problem involves the computation of bounds which impose limits on how accurately we can estimate certain physical quantities. One such bound is the Holevo Cramer Rao bound on the trace of the mean squared error matrix. The Holevo bound is an asymptotically achievable bound when one allows for any measurement strategy, including collective measurements on many copies of the probe. In this work we introduce a tighter bound for estimating multiple parameters simultaneously when performing separable measurements on finite copies of the probe. This makes it more relevant in terms of experimental accessibility. We show that this bound can be efficiently computed by casting it as a semidefinite program. We illustrate our bound with several examples of collective measurements on finite copies of the probe. These results have implications for the necessary requirements to saturate the Holevo bound., Comment: Published in npjqi

Published

2020

28. Maximum entanglement of formation for a two-mode Gaussian state over passive operations

Author

Tserkis, Spyros, Thompson, Jayne, Lund, Austin P., Ralph, Timothy C., Lam, Ping Koy, Gu, Mile, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

We quantify the maximum amount of entanglement of formation (EoF) that can be achieved by continuous-variable states under passive operations, which we refer to as EoF-potential. Focusing, in particular, on two-mode Gaussian states we derive analytical expressions for the EoF-potential for specific classes of states. For more general states, we demonstrate that this quantity can be upper-bounded by the minimum amount of squeezing needed to synthesize the Gaussian modes, a quantity called squeezing of formation. Our work, thus, provides a new link between non-classicality of quantum states and the non-classicality of correlations., Comment: Revised version

Published

2020

29. Decoupling Cross-Quadrature Correlations using Passive Operations

Author

Assad, Syed M., Gu, Mile, Li, Xiaoying, and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

Quadrature correlations between subsystems of a Gaussian quantum state are fully characterised by its covariance matrix. For example, the covariance matrix determines the amount of entanglement or decoherence of the state. Here, we establish when it is possible to remove correlations between conjugate quadratures using only passive operations. Such correlations are usually undesired and arise due to experimental cross-quadrature contamination. Using the Autonne--Takagi factorisation, we present necessary and sufficient conditions to determine when such removal is possible. Our proof is constructive, and whenever it is possible we obtain an explicit expression for the required passive operation.

Published

2020

30. Accessible precisions for estimating two conjugate parameters using Gaussian probes

Author

Assad, Syed M., Li, Jiamin, Liu, Yuhong, Zhao, Ningbo, Zhao, Wen, Lam, Ping Koy, Ou, Z. Y., and Li, Xiaoying

Subjects

Quantum Physics

Abstract

We analyse the precision limits for simultaneous estimation of a pair of conjugate parameters in a displacement channel using Gaussian probes. Having a set of squeezed states as an initial resource, we compute the Holevo Cram\'er-Rao bound to investigate the best achievable estimation precisions if only passive linear operations are allowed to be performed on the resource prior to probing the channel. The analysis reveals the optimal measurement scheme and allows us to quantify the best precision for one parameter when the precision of the second conjugate parameter is fixed. To estimate the conjugate parameter pair with equal precision, our analysis shows that the optimal probe is obtained by combining two squeezed states with orthogonal squeezing quadratures on a 50:50 beam splitter. If different importance are attached to each parameter, then the optimal mixing ratio is no longer 50:50. Instead it follows a simple function of the available squeezing and the relative importance between the two parameters.

Published

2020

31. Real-Time Source Independent Quantum Random Number Generator with Squeezed States

Author

Michel, Thibault, Haw, Jing Yan, Marangon, Davide G., Thearle, Oliver, Vallone, Giuseppe, Villoresi, Paolo, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Random numbers are a fundamental ingredient for many applications including simulation, modelling and cryptography. Sound random numbers should be independent and uniformly distributed. Moreover, for cryptographic applications they should also be unpredictable. We demonstrate a real-time self-testing source independent quantum random number generator (QRNG) that uses squeezed light as source. We generate secure random numbers by measuring the quadratures of the electromagnetic field without making any assumptions on the source; only the detection device is trusted. We use a homodyne detection to alternatively measure the Q and P conjugate quadratures of our source. Using the entropic uncertainty relation, measurements on P allow us to estimate a bound on the min-entropy of Q conditioned on any classical or quantum side information that a malicious eavesdropper may detain. This bound gives the minimum number of secure bits we can extract from the Q measurement. We discuss the performance of different estimators for this bound. We operate this QRNG with a squeezed state and we compare its performance with a QRNG using thermal states. The real-time bit rate was 8.2 kb/s when using the squeezed source and between 5.2-7.2 kb/s when the thermal state source was used., Comment: 11 pages, 9 figures

Published

2019

32. Entanglement criterion and strengthened Bell inequalities based on the Pearson correlation

Author

Tserkis, Spyros, primary, Assad, Syed M., additional, Conti, Andrea, additional, and Win, Moe Z., additional

Published

2024

33. Entanglement properties of a measurement-based entanglement distillation experiment

Author

Jeng, Hao, Tserkis, Spyros, Haw, Jing Yan, Chrzanowski, Helen M., Janousek, Jiri, Ralph, Timothy C., Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Measures of entanglement can be employed for the analysis of numerous quantum information protocols. Due to computational convenience, logarithmic negativity is often the choice in the case of continuous variable systems. In this work, we analyse a continuous variable measurement-based entanglement distillation experiment using a collection of entanglement measures. This includes: logarithmic negativity, entanglement of formation, distillable entanglement, relative entropy of entanglement, and squashed entanglement. By considering the distilled entanglement as a function of the success probability of the distillation protocol, we show that the logarithmic negativity surpasses the bound on deterministic entanglement distribution at a relatively large probability of success. This is in contrast to the other measures which would only be able to do so at much lower probabilities, hence demonstrating that logarithmic negativity alone is inadequate for assessing the performance of the distillation protocol. In addition to this result, we also observed an increase in the distillable entanglement by making use of upper and lower bounds to estimate this quantity. We thus demonstrate the utility of these theoretical tools in an experimental setting., Comment: 12 pages, 8 figures, submitted

Published

2018

34. Gaussian multipartite quantum discord from classical mutual information

Author

Bradshaw, Mark, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

Quantum discord is a measure of non-classical correlations, which are excess correlations inherent in quantum states that cannot be accessed by classical measurements. For multipartite states, the classically accessible correlations can be defined by the mutual information of the multipartite measurement outcomes. In general the quantum discord of an arbitrary quantum state involves an optimisation of over the classical measurements which is hard to compute. In this paper, we examine the quantum discord in the experimentally relevant case when the quantum states are Gaussian and the measurements are restricted to Gaussian measurements. We perform the optimisation over the measurements to find the Gaussian discord of the bipartite EPR state and tripartite GHZ state in the presence of different types of noise: uncorrelated noise, multiplicative noise and correlated noise. We find that by adding uncorrelated noise and multiplicative noise, the quantum discord always decreases. However, correlated noise can either increase or decrease the quantum discord. We also find that for low noise, the optimal classical measurements are single quadrature measurements. As the noise increases, a dual quadrature measurement becomes optimal., Comment: 10 pages, 5 figures

Published

2018

35. Quantum enhancement of signal-to-noise ratio with a heralded linear amplifier

Author

Zhao, Jie, Dias, Josephine, Haw, Jing Yan, Bradshaw, Mark, Blandino, Remi, Symul, Thomas, Ralph, Timothy C., Assad, Syed M., and Lam, Ping Koy

Subjects

Physics - Optics, Quantum Physics

Abstract

Due to the pervasive nature of decoherence, protection of quantum information during transmission is of critical importance for any quantum network. A linear amplifier that can enhance quantum signals stronger than their associated noise while preserving quantum coherence is therefore of great use. This seemingly unphysical amplifier property is achievable for a class of probabilistic amplifiers that does not work deterministically. Here we present a linear amplification scheme that realises this property for coherent states by combining a heralded measurement-based noiseless linear amplifier and a deterministic linear amplifier. The concatenation of two amplifiers introduces the flexibility that allows one to tune between the regimes of high-gain or high noise-reduction, and control the trade-off of these performances against a finite heralding probability. We demonstrate an amplification signal transfer coefficient of $\mathcal{T}_s > 1$ with no statistical distortion of the output state. By partially relaxing the demand of output Gaussianity, we can obtain further improvement to achieve a $\mathcal{T}_s = 2.55 \pm 0.08$. Our amplification scheme only relies on linear optics and post-selection algorithm. We discuss the potential of using this amplifier as a building block in extending the distance of quantum communication.

Published

2018

36. Quantum enhanced joint measurement of multiple non-commuting observables with SU(1,1) interferometer

Author

Liu, Yuhong, Li, Jiamin, Cui, Liang, Huo, Nan, Assad, Syed M, Li, Xiaoying, and Ou, Z. Y.

Subjects

Quantum Physics

Abstract

Heisenberg uncertainty relation in quantum mechanics sets the limit on the measurement precision of non-commuting observables, which prevents us from measuring them accurately at the same time. In some applications, however, the information are embedded in two or more non-commuting observables. On the other hand, quantum entanglement allows us to infer through Einstein-Podolsky-Rosen correlations two conjugate observables with precision better than what is allowed by Heisenberg uncertainty relation. With the help of the newly developed SU(1,1) interferometer, we implement a scheme to measure jointly information encoded in multiple non-commuting observables of an optical field with a signal-to-noise ratio improvement of about 20 % over the standard quantum limit on all measured quantities simultaneously. This scheme can be generalized to the joint measurement of information in arbitrary number of non-commuting observables., Comment: 6 pages, 6 figures

Published

2017

37. Enhancing the precision limits of interferometric satellite geodesy missions

Author

Conlon, Lorcán O., Michel, Thibault, Guccione, Giovanni, McKenzie, Kirk, Assad, Syed M., and Lam, Ping Koy

Published

2022

38. Joint Multi-Parameter Measurement

Author

Li, Jiamin, Liu, Yuhong, Cui, Liang, Huo, Nan, Assad, Syed M, Li, Xiaoying, and Ou, Z. Y.

Subjects

Quantum Physics

Abstract

Although quantum metrology allows us to make precision measurement beyond the standard quantum limit, it mostly works on the measurement of only one observable due to Heisenberg uncertainty relation on the measurement precision of non-commuting observables for one system. In this paper, we study the schemes of joint measurement of multiple observables which do not commute with each other by using the quantum entanglement between two systems. We focus on analyzing the performance of newly developed SU(1,1) interferometer on fulfilling the task of joint measurement. The results show that the information encoded in multiple non-commuting observables on an optical field can be simultaneously measured with a signal-to-noise ratio higher than the standard quantum limit, and the ultimate limit of each observable is still the Heisenberg limit. Moreover, we find a resource conservation rule for the joint measurement.

Published

2017

39. Ultimate precision of joint quadrature parameter estimation with a Gaussian probe

Author

Bradshaw, Mark, Lam, Ping Koy, and Assad, Syed M.

Subjects

Quantum Physics

Abstract

The Holevo Cram\'er Rao bound is a lower bound on the sum of the mean square error of estimates for parameters of a state. We provide a method for calculating the Holevo Cram\'er-Rao bound for estimation of quadrature mean parameters of a Gaussian state by formulating the problem as a semidefinite program. In this case, the bound is tight; it is attained by purely Guassian measurements. We consider the example of a symmetric two-mode squeezed thermal state undergoing an unknown displacement on one mode. We calculate the Holevo Cram\'er-Rao bound for joint estimation of the conjugate parameters for this displacement. The optimal measurement is different depending on whether the state is entangled or separable., Comment: 12 pages, 2 figures

Published

2017

40. A tight Cram\'er-Rao bound for joint parameter estimation with a pure two-mode squeezed probe

Author

Bradshaw, Mark, Assad, Syed M, and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

We calculate the Holevo Cram\'er-Rao bound for estimation of the displacement experienced by one mode of an two-mode squeezed vacuum state with squeezing r and find that it is equal to 4exp(-2r). This equals the sum of the mean squared error obtained from a dual homodyne measurement, indicating that the bound is tight and that the dual homodyne measurement is optimal., Comment: 18 pages, 1 figure

Published

2017

41. Secure Random Number Generation in Continuous Variable Systems

Author

Haw, Jing Yan, Assad, Syed M., Lam, Ping Koy, Laflamme, Raymond, Series Editor, Lenhart, Gaby, Series Editor, Lidar, Daniel, Series Editor, Rauschenbeutel, Arno, Series Editor, Renner, Renato, Series Editor, Schlosshauer, Maximilian, Series Editor, Weinstein, Yaakov S., Series Editor, Wiseman, H. M., Series Editor, Kollmitzer, Christian, editor, Schauer, Stefan, editor, Rass, Stefan, editor, and Rainer, Benjamin, editor

Published

2020

42. Overarching framework between Gaussian quantum discord and Gaussian quantum illumination

Author

Bradshaw, Mark, Assad, Syed M., Haw, Jing Yan, Tan, Si-Hui, Lam, Ping Koy, and Gu, Mile

Subjects

Quantum Physics

Abstract

We cast the problem of illuminating an object in a noisy environment into a communication protocol. A probe is sent into the environment, and the presence or absence of the object constitutes a signal encoded on the probe. The probe is then measured to decode the signal. We calculate the Holevo information and bounds to the accessible information between the encoded and received signal with two different Gaussian probes---an Einstein-Podolsky-Rosen (EPR) state and a coherent state. We also evaluate the Gaussian discord consumed during the encoding process with the EPR probe. We find that the Holevo quantum advantage, defined as the difference between the Holevo information obtained from the EPR and coherent state probes, is approximately equal to the discord consumed. These quantities become exact in the typical illumination regime of low object reflectivity and low probe energy. Hence we show that discord is the resource responsible for the quantum advantage in Gaussian quantum illumination., Comment: 12 pages, 8 figures

Published

2016

43. Surpassing the no-cloning limit with a heralded hybrid linear amplifier for coherent states

Author

Haw, Jing Yan, Zhao, Jie, Dias, Josephine, Assad, Syed M., Bradshaw, Mark, Blandino, Rémi, Symul, Thomas, Ralph, Timothy C., and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

The no-cloning theorem states that an unknown quantum state cannot be cloned exactly and deterministically due to the linearity of quantum mechanics. Associated with this theorem is the quantitative no-cloning limit that sets an upper bound to the quality of the generated clones. However, this limit can be circumvented by abandoning determinism and using probabilistic methods. Here, we report an experimental demonstration of probabilistic cloning of arbitrary coherent states that clearly surpasses the no-cloning limit. Our scheme is based on a hybrid linear amplifier that combines an ideal deterministic linear amplifier with a heralded measurement-based noiseless amplifier. We demonstrate the production of up to five clones with the fidelity of each clone clearly exceeding the corresponding no-cloning limit. Moreover, since successful cloning events are heralded, our scheme has the potential to be adopted in quantum repeater, teleportation and computing applications., Comment: 10 pages, 5 figures, close to published version

Published

2016

44. Maximizing device-independent randomness from a Bell experiment by optimizing the measurement settings

Author

Assad, Syed M, Thearle, Oliver, and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

The rates at which a user can generate device-independent quantum random numbers from a Bell-type experiment depend on the measurements that he performs. By numerically optimising over these measurements, we present lower bounds on the randomness generation rates for a family of two-qubit states composed from a mixture of partially entangled states and the completely mixed state. We also report on the randomness generation rates from a tomographic measurement. Interestingly in this case, the randomness generation rates are not monotonic functions of entanglement.

Published

2016

45. Estimation of Output Channel Noise for Continuous Variable Quantum Key Distribution

Author

Thearle, Oliver, Assad, Syed M., and Symul, Thomas

Subjects

Quantum Physics

Abstract

Estimation of channel parameters is important for extending the range and increasing the key rate of continuous variable quantum key distribution protocols. We propose a new estimator for the channel noise parameter based on the method of moments. The method of moments finds an estimator from the moments of the output distribution of the protocol. This estimator has the advantage of being able to use all of the states shared between Alice and Bob. Other estimators are limited to a smaller publicly revealed subset of the states. The proposed estimator has a lower variance for high loss channel than what has previously been proposed. We show that the method of moments estimator increases the key rate by up to an order of magnitude at the maximum transmission of the protocol., Comment: 5 pages, 3 figures

Published

2015

46. Replicating the benefits of closed timelike curves without breaking causality

Author

Yuan, Xiao, Assad, Syed M., Thompson, Jayne, Haw, Jing Yan, Vedral, Vlatko, Ralph, Timothy C., Lam, Ping Koy, Weedbrook, Christian, and Gu, Mile

Subjects

Quantum Physics, General Relativity and Quantum Cosmology

Abstract

In general relativity, closed timelike curves can break causality with remarkable and unsettling consequences. At the classical level, they induce causal paradoxes disturbing enough to motivate conjectures that explicitly prevent their existence. At the quantum level, resolving such paradoxes induce radical benefits - from cloning unknown quantum states to solving problems intractable to quantum computers. Instinctively, one expects these benefits to vanish if causality is respected. Here we show that in harnessing entanglement, we can efficiently solve NP-complete problems and clone arbitrary quantum states - even when all time-travelling systems are completely isolated from the past. Thus, the many defining benefits of closed timelike curves can still be harnessed, even when causality is preserved. Our results unveil the subtle interplay between entanglement and general relativity, and significantly improve the potential of probing the radical effects that may exist at the interface between relativity and quantum theory., Comment: 6 pages, 5 figures. Comments most welcome

Published

2014

47. An expressive ansatz for low-depth quantum approximate optimisation

Author

Vijendran, V, primary, Das, Aritra, additional, Koh, Dax Enshan, additional, Assad, Syed M, additional, and Lam, Ping Koy, additional

Published

2024

48. Measurement-Based Noiseless Linear Amplification for Quantum Communication

Author

Chrzanowski, Helen M., Walk, Nathan, Assad, Syed M., Janousek, Jiri, Hosseini, Sara, Ralph, Timothy C., Symul, Thomas, and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

Entanglement distillation is an indispensable ingredient in extended quantum communication networks. Distillation protocols are necessarily non-deterministic and require advanced experimental techniques such as noiseless amplification. Recently it was shown that the benefits of noiseless amplification could be extracted by performing a post-selective filtering of the measurement record to improve the performance of quantum key distribution. We apply this protocol to entanglement degraded by transmission loss of up to the equivalent of 100km of optical fibre. We measure an effective entangled resource stronger than that achievable by even a maximally entangled resource passively transmitted through the same channel. We also provide a proof-of-principle demonstration of secret key extraction from an otherwise insecure regime. The measurement-based noiseless linear amplifier offers two advantages over its physical counterpart: ease of implementation and near optimal probability of success. It should provide an effective and versatile tool for a broad class of entanglement-based quantum communication protocols., Comment: 7+3 pages, 5+1 figures, close to published version

Published

2014

49. Experimental demonstration of Gaussian protocols for one-sided device-independent quantum key distribution

Author

Walk, Nathan, Hosseni, Sara, Geng, Jiao, Thearle, Oliver, Haw, Jing Yan, Armstrong, Seiji, Assad, Syed M, Janousek, Jiri, Ralph, Timothy C, Symul, Thomas, Wiseman, Howard M, and Lam, Ping Koy

Subjects

Quantum Physics

Abstract

Nonlocal correlations, a longstanding foundational topic in quantum information, have recently found application as a resource for cryptographic tasks where not all devices are trusted, for example in settings with a highly secure central hub, such as a bank or government department, and less secure satellite stations which are inherently more vulnerable to hardware "hacking" attacks. The asymmetric phenomena of Einstein-Podolsky-Rosen steering plays a key role in one-sided device-independent quantum key distribution (1sDI-QKD) protocols. In the context of continuous-variable (CV) QKD schemes utilizing Gaussian states and measurements, we identify all protocols that can be 1sDI and their maximum loss tolerance. Surprisingly, this includes a protocol that uses only coherent states. We also establish a direct link between the relevant EPR steering inequality and the secret key rate, further strengthening the relationship between these asymmetric notions of nonlocality and device independence. We experimentally implement both entanglement-based and coherent-state protocols, and measure the correlations necessary for 1sDI key distribution up to an applied loss equivalent to 7.5 km and 3.5 km of optical fiber transmission respectively. We also engage in detailed modelling to understand the limits of our current experiment and the potential for further improvements. The new protocols we uncover apply the cheap and efficient hardware of CVQKD systems in a significantly more secure setting., Comment: Addition of experimental results and (several) new authors

Published

2014

50. Encoding secret information in measurement settings

Author

Assad, Syed. M. and Kalev, Amir

Subjects

Quantum Physics

Abstract

Secure communication protocols are often formulated in a paradigm where the message is encoded in measurement outcomes. In this work we propose a rather unexplored framework in which the message is encoded in measurement settings rather than in their outcomes. In particular, we study two different variants of such secure communication protocols in which the message alphabet corresponds to measurement settings of mutually unbiased bases., Comment: 4 pages

Published

2014