Your search keyword '"Thearle, Oliver"' showing total 6 results

1. Mapping Guaranteed Positive Secret Key Rates for Continuous Variable Quantum Key Distribution.

Author

Sayat, Mikhael T., Thearle, Oliver, Shajilal, Biveen, Kish, Sebastian P., Lam, Ping Koy, Rattenbury, Nicholas J., and Cater, John E.

Subjects

*COHERENT states, *NUMERICAL analysis, *NOISE

Abstract

The standard way to measure the performance of existing continuous variable quantum key distribution (CVQKD) protocols is by using the achievable secret key rate (SKR) with respect to one parameter while keeping all other parameters constant. However, this atomistic method requires many individual parameter analyses while overlooking the co-dependence of other parameters. In this work, a numerical tool is developed for comparing different CVQKD protocols while taking into account the simultaneous effects of multiple CVQKD parameters on the capability of protocols to produce positive SKRs. Using the transmittance, excess noise, and modulation amplitude parameter space, regions of positive SKR are identified to compare three discrete modulated (DM) CVQKD protocols. The results show that the M-QAM protocol outperforms the M-APSK and M-PSK protocols and that there is a non-linear increase in the capability to produce positive SKRs as the number of coherent states used for a protocol increases. The tool developed is beneficial for choosing the optimum protocol in unstable channels, such as free space, where the transmittance and excess noise fluctuate, providing a more holistic assessment of a protocol's capability to produce positive SKRs. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

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

Subjects

HOMODYNE detection, QUANTUM mechanics, COHERENCE (Optics), HILBERT space, QUANTUM theory, OPTICAL interferometers, COHERENT states

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 importantly 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 κ = 0.002 ± 0.004 and for testing whether quantum mechanics is complex or not we find a Peres parameter of F = 1.0000 ± 0.0003 (F = 1 corresponds to the expected complex quantum mechanics). We also design and implement a test of Glauber's theory of optical coherence. [ABSTRACT FROM AUTHOR]

Published

2024

3. Violation of Bell's Inequality Using Continuous Variable Measurements.

Author

Thearle, Oliver, Janousek, Jiri, Armstrong, Seiji, Hosseini, Sara, Schünemann (Mraz), Melanie, Assad, Syed, Symul, Thomas, James, Matthew R., Huntington, Elanor, Ralph, Timothy C., and Lam, Ping Koy

Subjects

*BELL'S theorem, *HOMODYNE detection

Abstract

A Bell inequality is a fundamental test to rule out local hidden variable model descriptions of correlations between two physically separated systems. There have been a number of experiments in which a Bell inequality has been violated using discrete-variable systems. We demonstrate a violation of Bell's inequality using continuous variable quadrature measurements. By creating a four-mode entangled state with homodyne detection, we recorded a clear violation with a Bell value of B=2.31±0.02. This opens new possibilities for using continuous variable states for device independent quantum protocols. [ABSTRACT FROM AUTHOR]

Published

2018

4. Integrated photonic platform for quantum information with continuous variables.

Author

Villa, Matteo, Haylock, Ben, Kasture, Sachin, Lenzini, Francesco, Lobino, Mirko, Huntington, Elanor H., Janousek, Jiri, Thearle, Oliver, Ping Koy Lam, Liang Cui, Hoang-Phuong Phan, Dzung Viet Dao, and Hidehiro Yonezawa

Subjects

*QUANTUM information science, *PHOTONICS, *HOMODYNE detection, *QUANTUM states, *SQUEEZED light

Abstract

The article discusses the application of integrated quantum photonics in quantum information processing by manipulating and detecting optical quantum states. According to the author integrated single device generates and manipulates the homodyne detection of nonclassical light. Topics include the use of lithium niobate waveguide network to measure squeezed light and entangled states, and the use of reverse proton exchange technique to fabricate device.

Published

2018

5. 12.6 dB squeezed light at 1550 nm from a bow-tie cavity for long-term high duty cycle operation.

Author

Shajilal B, Thearle O, Tranter A, Lu Y, Huntington E, Assad S, Lam PK, and Janousek J

Abstract

Squeezed states are an interesting class of quantum states that have numerous applications. This work presents the design, characterization, and operation of a bow-tie optical parametric amplifier (OPA) for squeezed vacuum generation. We report the high duty cycle operation and long-term stability of the system that makes it suitable for post-selection based continuous-variable quantum information protocols, cluster-state quantum computing, quantum metrology, and potentially gravitational wave detectors. Over a 50 hour continuous operation, the measured squeezing levels were greater than 10 dB with a duty cycle of 96.6%. Alternatively, in a different mode of operation, the squeezer can also operate 10 dB below the quantum noise limit over a 12 hour period with no relocks, with an average squeezing of 11.9 dB. We also measured a maximum squeezing level of 12.6 dB at 1550 nm. This represents one of the best reported squeezing results at 1550 nm to date for a bow-tie cavity. We discuss the design aspects of the experiment that contribute to the overall stability, reliability, and longevity of the OPA, along with the automated locking schemes and different modes of operation.

Published

2022

6. Integrated photonic platform for quantum information with continuous variables.

Author

Lenzini F, Janousek J, Thearle O, Villa M, Haylock B, Kasture S, Cui L, Phan HP, Dao DV, Yonezawa H, Lam PK, Huntington EH, and Lobino M

Abstract

Integrated quantum photonics provides a scalable platform for the generation, manipulation, and detection of optical quantum states by confining light inside miniaturized waveguide circuits. Here, we show the generation, manipulation, and interferometric stage of homodyne detection of nonclassical light on a single device, a key step toward a fully integrated approach to quantum information with continuous variables. We use a dynamically reconfigurable lithium niobate waveguide network to generate and characterize squeezed vacuum and two-mode entangled states, key resources for several quantum communication and computing protocols. We measure a squeezing level of - 1.38 ± 0.04 dB and demonstrate entanglement by verifying an inseparability criterion I = 0.77 ± 0.02 < 1. Our platform can implement all the processes required for optical quantum technology, and its high nonlinearity and fast reconfigurability make it ideal for the realization of quantum computation with time encoded continuous-variable cluster states.

Published

2018