Dr. Ross J. Donaldson Profile

Dr. Ross J. Donaldson

Research Fellow at Heriot-Watt Univ

SPIE Involvement:

Author

Publications (21)

Proceedings Article | 22 November 2024 Presentation

Impact of wind conditions on free space satellite to ground quantum communications link

Elizabeth Eso, Cameron Simmons, Ross Donaldson

Proceedings Volume 13194, 131940S (2024) https://doi.org/10.1117/12.3034953

KEYWORDS: Free space, Satellites, Satellite to ground quantum key distribution, Satellite communications, Quantum based satellite communication, Free space optics, Quantum light, Turbulence, Rain, Quantum systems

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Proceedings Article | 15 November 2024 Presentation + Paper

Reducing the hardware requirements while mitigating side-channels in polarisation-based decoy-state BB84 quantum key distribution

R. Donaldson, C. Simmons, A. Tello Castillo

Proceedings Volume 13202, 132020F (2024) https://doi.org/10.1117/12.3031477

KEYWORDS: Quantum key distribution, Polarization, Quantum hardware, Quantum receivers, Quantum channels, Quantum transmitters, Quantum photonics, Single photon avalanche diodes

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Proceedings Article | 30 November 2023 Paper

Beamshaping beacon light for satellite quantum key distribution: spatial separation and point ahead angle

Cameron Simmons, Ross Donaldson

Proceedings Volume 12795, 1279508 (2023) https://doi.org/10.1117/12.2688757

KEYWORDS: Telescopes, Quantum key distribution, Satellites, Photons, Multicore fiber, Satellite communications, Receivers, Beam divergence, Quantum receivers

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Proceedings Article | 30 November 2023 Paper

Investigation on the electromagnetic radiated emissions of a single-photon avalanche diode

John Pantoja, Alfonso Tello, Dimitris Anagnostou, James Kirrane, Mark Stonehouse, Alex Koehler-Sidki, Michele Natrella, Ross Donaldson

Proceedings Volume 12795, 1279509 (2023) https://doi.org/10.1117/12.2689901

KEYWORDS: Single photon avalanche diodes, Quantum receivers, Quantum key distribution, Electromagnetism, Quantum detection, Pulse signals, Antennas, Electromagnetic radiation

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Proceedings Article | 6 June 2023 Presentation + Paper

Multimode fiber influence on single-photon avalanche diode timing jitter

Alexandra Lee, Ross Donaldson, Craig Whitehill, Alfonso Tello Castillo

Proceedings Volume 12570, 1257007 (2023) https://doi.org/10.1117/12.2664836

KEYWORDS: Single photon avalanche diodes, Multimode fibers, Quantum key distribution, Single mode fibers, Tolerancing, Dispersion

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Proceedings Article | 11 January 2023 Presentation + Paper

An investigation of jamming in free-space quantum key distribution

Cameron Simmons, Yoann Noblet, Alfonso Tello Castillo, Ross Donaldson

Proceedings Volume 12335, 123350C (2023) https://doi.org/10.1117/12.2644866

KEYWORDS: Satellites, Quantum key distribution, Receivers, Photons, Signal detection, Satellite communications, Telescopes, Telecommunications, Reflectivity, Quantum communications

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Proceedings Article | 11 January 2023 Presentation + Paper

Multiprotocol quantum key distribution receiver for free space

Alfonso Tello Castillo, Ugo Zanforlin, Gerald Buller, Ross Donaldson

Proceedings Volume 12335, 123350B (2023) https://doi.org/10.1117/12.2646456

KEYWORDS: Quantum key distribution, Receivers, Interferometers, Visibility, Polarization, Design and modelling, Free space, Signal to noise ratio, Technology, Double positive medium

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Proceedings Article | 11 January 2023 Presentation

Hollow-core fiber for near-infrared quantum communication

Umberto Nasti, Ian Davidson, Hesham Sakr, Francesco Poletti, Ross Donaldson

Proceedings Volume PC12335, PC123350E (2023) https://doi.org/10.1117/12.2644693

KEYWORDS: Quantum communications, Signal attenuation, Optical communications, Channel projecting optics, Waveguides, Raman spectroscopy, Raman scattering, Quantum key distribution, Optical networks, Optical fibers

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Proceedings Article | 11 January 2023 Presentation

Utilizing the UK’s quantum optical ground station infrastructure for advanced satellite-based quantum communication demonstrations

Ross Donaldson, Cameron Simmons, Peter Barrow, Elizabeth Eso, Rebecca Harwin, Stuart Robertson, Hannah Robarts, Alex Pickston, David Pearson, Alessandro Fedrizzi, Andy Vick, Gerald Buller

Proceedings Volume PC12335, PC123350A (2023) https://doi.org/10.1117/12.2647354

KEYWORDS: Quantum communications, Satellites, Satellite communications, Quantum optics, Quantum key distribution

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Proceedings Article | 11 January 2023 Presentation

BB84 quantum key distribution transmitter utilising broadband sources and a narrow spectral filter

Yoann Noblet, Ross Donaldson

Proceedings Volume PC12335, PC123350F (2023) https://doi.org/10.1117/12.2647391

KEYWORDS: Quantum key distribution, Transmitters, Optical filters, Polarization, Bandpass filters, Quantum wells, Quantum communications, Photon polarization, Diodes

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Proceedings Article | 4 October 2022 Presentation + Paper

Time bin quantum key distribution protocols for free space communications

Alfonso Tello Castillo, Elizabeth Eso, Ross Donaldson

Proceedings Volume 12238, 122380E (2022) https://doi.org/10.1117/12.2632286

KEYWORDS: Quantum key distribution, Relays, Interferometers, Satellites, Visibility, Polarization, Lenses, Turbulence

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Proceedings Article | 6 October 2021 Presentation + Paper

Towards free-space quantum key distribution with a 2D single-photon sensor

Alfonso Tello Castillo, Ross Donaldson

Proceedings Volume 11881, 1188109 (2021) https://doi.org/10.1117/12.2601232

KEYWORDS: Quantum key distribution, Receivers, Sensors, Photons, Transmitters, Visibility, Signal to noise ratio, Interferometers, Interferometry, Detector arrays

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Proceedings Article | 20 September 2020 Presentation + Paper

Prospects of time-bin quantum key distribution in turbulent free-space channels

Alfonso Tello Castillo, Catarina Novo, Ross Donaldson

Proceedings Volume 11540, 1154006 (2020) https://doi.org/10.1117/12.2573479

KEYWORDS: Quantum key distribution, Quantum communications, Transmitters, Error analysis, Free space optics, Polarization, Turbulence, Interferometers, Optical fibers, Receivers

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Proceedings Article | 20 September 2020 Presentation + Paper

Link loss analysis for a satellite quantum communication down-link

Chunmei Zhang, Alfonso Tello, Ugo Zanforlin, Gerald Buller, Ross Donaldson

Proceedings Volume 11540, 1154007 (2020) https://doi.org/10.1117/12.2573489

KEYWORDS: Quantum communications, Satellites, Satellite communications, Signal attenuation, Telecommunications, Optical fibers, Telescopes, Error analysis, Singular optics, Computer programming

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Proceedings Article | 10 September 2019 Presentation

Satellite-based quantum communications (Conference Presentation)

Ross Donaldson, Gerald Buller, Alessandro Fedrizzi

Proceedings Volume 11134, 1113404 (2019) https://doi.org/10.1117/12.2529122

KEYWORDS: Satellites, Quantum communications, Satellite communications, Quantum key distribution, Data transmission, Data storage, Optical fibers, Detector arrays, Receivers

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Proceedings Article | 11 October 2018 Presentation

A learning scheme with coherent state receiver (Conference Presentation)

Luca Mazzarella, Ross Donaldson, Robert Collins, Ugo Zanforlin, David Canning, Gioan Tatsi, Gerald Buller, John Jeffers

Proceedings Volume 10803, 108030Q (2018) https://doi.org/10.1117/12.2325728

KEYWORDS: Sensors, Amplifiers, Beam splitters, Avalanche photodetectors, Laser optics, Atmospheric propagation, Quantum mechanics, Destructive interference, Optical amplifiers, Switches

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The laws of quantum mechanics pose stringent constraints on the amplification of a quantum signal. Deterministic amplification of an unknown quantum state always implies the addition of a minimal amount of noise. In principle, linear and noiseless amplification is allowed provided it works only probabilistically [1,2]. The state comparison amplifier [3] is an approximate probabilistic amplifier that amplifies a coherent state chosen at random from a set of coherent states with known mean photon number. The amplification process works as follows: Alice picks uniformly at random an input state and passes it to Bob. He desires to amplify the state so he mixes it with a guess coherent state at a beam splitter in an attempt to achieve destructive interference in one of the output arms. This output is fed into an APD detector. The lack of trigger at the detector is an imperfect indication that Bob’s guess is right and that the output contains the correct amplified state. On the other hand, if the first detector fires Bob knows that his guess was wrong but he can still correct the output by changing the input state for a second amplification stage via a feed-forward loop. In summary, Bob declares success when both the detectors do not fire or when the first detector does fire and state correction is performed. We generalize this mechanism for an arbitrary number of input states and beam splitters, using an on-line learning strategy based on maximum a posteriori probability. The success probability-fidelity product [2] of the SCAMP is the joint probability of success and of passing a measurement test on the output comparing it to right amplified state. Our figures of merit compare favorably with other schemes. The success probability-fidelity product of the SCAMP is always bigger than that of a USD based amplifier [2] that, when inconclusive, delivers a conveniently chosen random output. The SCAMP can be realized with classical resources (i.e., lasers, linear optics and APD detectors), the ability to switch between input states on the fly requires delay lines and fast switching but it can still be achieved with classical resources and the loss introduced by the delay can be offset at the second stage. Similar systems, with no state correction, proved to achieve high-gain, high fidelity and high repetition rates, e.g. [4, 5]. Due to its simplicity, the system we propose might represent an ideal candidate either as a recovery station to counteract quantum signal degradation due to propagation in a lossy fibre or across the turbulent atmosphere or as a quantum receiver to improve the key-rate of continuous-variable quantum key distribution with discrete modulation. The system is also suitable for on-chip implementation. [1] T.C. Ralph & A.P. Lund, Proceedings of the 9th QCMC Conference 2009. [2] S. Pandey, et al., Phys. Rev. A 88, 033852 (2013). [3] E. Eleftheriadou et al., Phys. Rev. Lett. 111, 213601 (2013). [4] R. Donaldson et al., Phys. Rev. Lett. 114, 120505 (2015). [5] R. Donaldson et al., in preparation.

Proceedings Article | 18 September 2018 Presentation + Paper

Progress in experimental quantum digital signatures

Robert Collins, Ross Donaldson, Gerald Buller

Proceedings Volume 10771, 107710F (2018) https://doi.org/10.1117/12.2319015

KEYWORDS: Quantum key distribution, Optical fibers, Quantum information, Receivers, Data communications, Telecommunications, Beam splitters, Binary data, Quantum communications, Phase modulation

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Proceedings Article | 29 May 2018 Presentation + Paper

Quantum optical state comparison amplification of coherent states

Ugo Zanforlin, Ross Donaldson, Luca Mazzarella, Robert Collins, John Jeffers, Gerald Buller

Proceedings Volume 10674, 1067413 (2018) https://doi.org/10.1117/12.2307820

KEYWORDS: Optical amplifiers, Sensors, Visibility, Quantum communications, Tomography, Amplifiers, Signal detection, Optical fibers, Signal attenuation, Quantum efficiency

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Proceedings Article | 21 May 2018 Paper

Quantum state comparison amplifier with feedforward state correction

L. Mazzarella, R. Donaldson, R. Collins, U. Zanforlin, G. Tatsi, G. Buller, J. Jeffers

Proceedings Volume 10674, 106741D (2018) https://doi.org/10.1117/12.2307818

KEYWORDS: Beam splitters, Optical amplifiers, Amplifiers, Destructive interference, Quantum physics, Physical sciences, Quantum communications

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Proceedings Article | 13 October 2014 Paper

An in fiber experimental approach to photonic quantum digital signatures that does not require quantum memory

Robert Collins, Ross Donaldon, Vedran Dunjko, Petros Wallden, Patrick Clarke, Erika Andersson, John Jeffers, Gerald Buller

Proceedings Volume 9254, 92540D (2014) https://doi.org/10.1117/12.2069859

KEYWORDS: Quantum memory, Receivers, Sensors, Beam splitters, Quantum information, Information security, Photons, Computer programming, Vertical cavity surface emitting lasers, Polarization

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Proceedings Article | 29 October 2013 Paper

An approach to experimental photonic quantum digital signatures in fiber

Ross Donaldson, Robert Collins, Vedran Dunjko, Partick Clarke, Erika Andersson, John Jeffers, Gerald Buller

Proceedings Volume 8899, 88990X (2013) https://doi.org/10.1117/12.2028720

KEYWORDS: Receivers, Sensors, Interferometers, Visibility, Polarization, Information security, Quantum computing, Computer programming, Optical fibers, Data communications

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Showing 5 of 21 publications

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