One-Way Quantum Key Distribution System Based on Planar Lightwave Circuits

Nambu, Yasusada; Yoshino, K.; Tomita, Akira

doi:10.1143/jjap.45.5344

Cited by 11 publications

(14 citation statements)

References 45 publications

(103 reference statements)

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“…These results suggest that our PLC-based interferometer allows us to implement a QKD system insensitive to polarization effects that may occur in the transmission fiber, since the same balancing condition is sufficient to achieve polarization insensitivity [38]. The polarization-insensitive operation of a time-division interferometer based on our PLC AMZI has actually been proven by the authors using the experimental setup shown in Figure 7 [35,36]. Two PLC AMZIs and a polarization scrambler were connected in series using a single-mode fiber patch cable, and relatively intense optical pulses were introduced into the first AMZI.…”

supporting

confidence: 56%

“…The key to our proposal is the use of planar lightwave circuit (PLC) technology [32][33][34][35][36], which enables us to implement a reliable interferometric optical system that is robust to change in ambient conditions [37]. By using PLC technology, we developed compact and easy-to-use passive interferometric devices to manipulate a photonic time-bin qubit with increased stability, reliability, and flexibility.…”

Section: Introductionmentioning

confidence: 99%

“…unit) 10 15 1959 This clearly shows that our PLC-based interferometer is sufficient to implement a polarization-insensitive QKD system. The most promising features of the PLC-based interferometer are that it is robust to change in ambient conditions and it has been proven [36]. Figure 9 shows the long-term stability of our PLC-based interferometer.…”

mentioning

confidence: 99%

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Quantum encoder and decoder for practical quantum key distribution using a planar lightwave circuit

Nambu¹,

Yoshino²,

Tomita³

2008

J. of Modern Optics

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To launch quantum key distribution (QKD) into the commercial market, it is important to develop a system that is simpler and more reliable using current technology. This report proposes quantum encoders and decoders using a passive planar lightwave circuit (PLC) that is useful for implementing optical-fiber-based QKD systems. Our encoders and decoders are based on an asymmetric Mach-Zehnder interferometer and allow us to prepare and analyze various photonic time-bin qubits reliably. The system can be stable and polarization-insensitive merely by stabilizing and controlling the device temperature. Our PLC-based devices enables us to simplify the QKD system and increase its reliability.

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supporting

confidence: 56%

Section: Introductionmentioning

confidence: 99%

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Quantum encoder and decoder for practical quantum key distribution using a planar lightwave circuit

Nambu¹,

Yoshino²,

Tomita³

2008

J. of Modern Optics

Self Cite

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show abstract

“…Interferometers made of low thermal factor materials [13] or integrated planar silica waveguide with thermal and mechanical isolation can be used in passive compensation [14,15] . Another improved way to passively compensate for phase drift is to find the environment temperature of interferometers, at which the difference between the modal phase shifts in the long and short arms of the AMZI (ș L ș S ) is multiples of 2ʌ [16] . Although these measures can suppress the harmful temperature disturbance of environment, there must be accurate temperature controller with precision of 0.01 in the system.…”

Section: Quantum Informationmentioning

confidence: 99%

Active phase compensation of quantum key distribution system

Chen

Han

et al. 2008

Sci. Bull.

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“…An experimental metropolitan-area QKD network has been developed and deployed in the Boston area [18], and similar efforts are underway in Japan [19] and Europe [20]. Efforts to extend these networks to wider areas are constrained by loss in the communication channel, which results in exponential decay in throughput as distance increases.…”

Section: Introductionmentioning

confidence: 99%

System Design for a Long-Line Quantum Repeater

Meter

Ladd

Munro

et al. 2009

IEEE/ACM Trans. Networking

130

194

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Abstract-We present a new control algorithm and system design for a network of quantum repeaters, and outline the endto-end protocol architecture. Such a network will create longdistance quantum states, supporting quantum key distribution as well as distributed quantum computation. Quantum repeaters improve the reduction of quantum-communication throughput with distance from exponential to polynomial. Because a quantum state cannot be copied, a quantum repeater is not a signal amplifier. Rather, it executes algorithms for quantum teleportation in conjunction with a specialized type of quantum error correction called purification to raise the fidelity of the quantum states. We introduce our banded purification scheme, which is especially effective when the fidelity of coupled qubits is low, improving the prospects for experimental realization of such systems. The resulting throughput is calculated via detailed simulations of a long line composed of shorter hops. Our algorithmic improvements increase throughput by a factor of up to fifty compared to earlier approaches, for a broad range of physical characteristics.

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One-Way Quantum Key Distribution System Based on Planar Lightwave Circuits

Cited by 11 publications

References 45 publications

Quantum encoder and decoder for practical quantum key distribution using a planar lightwave circuit

Quantum encoder and decoder for practical quantum key distribution using a planar lightwave circuit

Active phase compensation of quantum key distribution system

System Design for a Long-Line Quantum Repeater

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