227 research outputs found
A high-speed multi-protocol quantum key distribution transmitter based on a dual-drive modulator
We propose a novel source based on a dual-drive modulator that is adaptable
and allows Alice to choose between various practical quantum key distribution
(QKD) protocols depending on what receiver she is communicating with.
Experimental results show that the proposed transmitter is suitable for
implementation of the Bennett and Brassard 1984 (BB84), coherent one-way (COW)
and differential phase shift (DPS) protocols with stable and low quantum bit
error rate. This could become a useful component in network QKD, where
multi-protocol capability is highly desirable.Comment: 15 pages, 7 figure
Intrinsically stable light source at telecom wavelengths
We present a highly stable light source at telecom wavelengths, based on a
short erbium doped fiber. The high stability arises from the high inversion of
the Er3+ion population. This source is developed to work as a stable reference
in radiometric applications and is useful in any application where high
stability and/or a large bandwidth are necessary. The achieved long-term
stability is 10 ppm
Practical fast gate rate InGaAs/InP single-photon avalanche photodiodes
We present a practical and easy-to-implement method for high-speed near
infrared single-photon detection based on InGaAs/InP single-photon avalanche
photodiodes (SPADs), combining aspects of both sine gating and
self-differencing techniques. At a gating frequency of 921 MHz and temperature
of -30 C we achieve: a detection efficiency of 9.3 %, a dark count
probability of 2.8 ns, while the afterpulse probability
is 1.6 ns, with a 10 ns "count-off time" setting. In
principle, the maximum count rate of the SPAD can approach 100 MHz, which can
significantly improve the performance for diverse applications.Comment: 3 pages and a few lines, 5 figures, 1 table. Accepted by Applied
Physics Letter
Quantum random number generation on a mobile phone
Quantum random number generators (QRNGs) can significantly improve the
security of cryptographic protocols, by ensuring that generated keys cannot be
predicted. However, the cost, size, and power requirements of current QRNGs has
prevented them from becoming widespread. In the meantime, the quality of the
cameras integrated in mobile telephones has improved significantly, so that now
they are sensitive to light at the few-photon level. We demonstrate how these
can be used to generate random numbers of a quantum origin
Absolute calibration of fiber-coupled single-photon detector
We show a setup for characterising the efficiency of a single-photon-detector
absolutely and with a precision better of 1%. Since the setup does not rely on
calibrated devices and can be implemented with standard-optic components, it
can be realised in any laboratory. Our approach is based on an
Erbium-Doped-Fiber-Amplifier (EDFA) radiometer as a primary measurement
standard for optical power, and on an ultra-stable source of spontaneous
emission. As a proof of principle, we characterise the efficiency of an
InGaAs/InP single-photon detector. We verified the correctness of the
characterisation with independent measurements. In particular, the measurement
of the optical power made with the EDFA radiometer has been compared to that of
the Swiss Federal Office of Metrology using a transfer power meter. Our
approach is suitable for frequent characterisations of high-efficient
single-photon detectors.Comment: 14 pages, 4 figure
Creating high dimensional time-bin entanglement using mode-locked lasers
We present a new scheme to generate high dimensional entanglement between two
photonic systems. The idea is based on parametric down conversion with a
sequence of pump pulses generated by a mode-locked laser. We prove
experimentally the feasibility of this scheme by performing a Franson-type Bell
test using a 2-way interferometer with path-length difference equal to the
distance between 2 pump pulses. With this experiment, we can demonstrate
entanglement for a two-photon state of at least dimension D=11. Finally, we
propose a feasible experiment to show a Fabry-Perot like effect for a high
dimensional two-photon state.Comment: 5 pages, 5 figure
What are single photons good for?
In a long-held preconception, photons play a central role in present-day
quantum technologies. But what are sources producing photons one by one good
for precisely? Well, in opposition to what many suggest, we show that
single-photon sources are not helpful for point to point quantum key
distribution because faint laser pulses do the job comfortably. However, there
is no doubt about the usefulness of sources producing single photons for future
quantum technologies. In particular, we show how single-photon sources could
become the seed of a revolution in the framework of quantum communication,
making the security of quantum key distribution device independent or extending
quantum communication over many hundreds of kilometers. Hopefully, these
promising applications will provide a guideline for researchers to develop more
and more efficient sources, producing narrowband, pure and indistinguishable
photons at appropriate wavelengths.Comment: 6 pages, 5 figures, submitted to the special issue of the Journal of
Modern Optics on the Single-Photon Workshop 201
Finite-key analysis on the 1-decoy state QKD protocol
It has been shown that in the asymptotic case of infinite-key length the
2-decoy state QKD protocol outperforms the 1-decoy state protocol. Here, we
present a finite-key analysis of the 1-decoy method. Interestingly, we find
that for practical block sizes of up to bits, the 1-decoy protocol
achieves for almost all experimental settings higher secret key rates than the
2-decoy protocol. Since using only one decoy is also easier to implement, we
conclude that it is the best choice for practical QKD.Comment: 6 pages, 7 figures, Pape
Quantum Cloning for Absolute Radiometry
In the quantum regime information can be copied with only a finite fidelity.
This fidelity gradually increases to 1 as the system becomes classical. In this
article we show how this fact can be used to directly measure the amount of
radiated power. We demonstrate how these principles could be used to build a
practical primary standard
Fast and User-friendly Quantum Key Distribution
Some guidelines for the comparison of different quantum key distribution
experiments are proposed. An improved 'plug & play' interferometric system
allowing fast key exchange is then introduced. Self-alignment and compensation
of birefringence remain. Original electronics implementing the BB84 protocol
and allowing user-friendly operation is presented. Key creation with 0.1 photon
per pulse at a rate of 486 Hz with a 5.4% QBER - corresponding to a net rate of
210Hz - over a 23 Km installed cable was performed.Comment: 21 pages, 6 figures, added referenc
- …