Software-defined network abstractions and configuration interfaces for building programmable quantum networks

Venkat R. Dasari; Ronald J. Sadlier; Billy E. Geerhart; Nikolai A. Snow; Brian P. Williams; Travis S. Humble

doi:10.1117/12.2263191

Software-defined network abstractions and configuration interfaces for building programmable quantum networks

Venkat R. Dasari, Ronald J. Sadlier, Billy E. Geerhart, Nikolai A. Snow, Brian P. Williams, Travis S. Humble

Research output: Contribution to journal › Conference article › peer-review

4 Scopus citations

Abstract

Well-defined and stable quantum networks are essential to realize functional quantum communication applications. Quantum networks are complex and must use both quantum and classical channels to support quantum applications like QKD, teleportation, and superdense coding. In particular, the no-cloning theorem prevents the reliable copying of quantum signals such that the quantum and classical channels must be highly coordinated using robust and extensible methods. In this paper, we describe new network abstractions and interfaces for building programmable quantum networks. Our approach leverages new OpenFlow data structures and table type patterns to build programmable quantum networks and to support quantum applications.

Original language	English
Article number	2263191
Journal	Proceedings of SPIE - The International Society for Optical Engineering
Volume	10212
DOIs	https://doi.org/10.1117/12.2263191
State	Published - 2017
Event	Advanced Photon Counting Techniques XI 2017 - Anaheim, United States Duration: Apr 12 2017 → Apr 13 2017

Keywords

Controller
OpenFlow
Programmable networks
Quantum networks

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10.1117/12.2263191

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title = "Software-defined network abstractions and configuration interfaces for building programmable quantum networks",

abstract = "Well-defined and stable quantum networks are essential to realize functional quantum communication applications. Quantum networks are complex and must use both quantum and classical channels to support quantum applications like QKD, teleportation, and superdense coding. In particular, the no-cloning theorem prevents the reliable copying of quantum signals such that the quantum and classical channels must be highly coordinated using robust and extensible methods. In this paper, we describe new network abstractions and interfaces for building programmable quantum networks. Our approach leverages new OpenFlow data structures and table type patterns to build programmable quantum networks and to support quantum applications.",

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AU - Sadlier, Ronald J.

AU - Geerhart, Billy E.

AU - Snow, Nikolai A.

AU - Williams, Brian P.

AU - Humble, Travis S.

PY - 2017

Y1 - 2017

N2 - Well-defined and stable quantum networks are essential to realize functional quantum communication applications. Quantum networks are complex and must use both quantum and classical channels to support quantum applications like QKD, teleportation, and superdense coding. In particular, the no-cloning theorem prevents the reliable copying of quantum signals such that the quantum and classical channels must be highly coordinated using robust and extensible methods. In this paper, we describe new network abstractions and interfaces for building programmable quantum networks. Our approach leverages new OpenFlow data structures and table type patterns to build programmable quantum networks and to support quantum applications.

AB - Well-defined and stable quantum networks are essential to realize functional quantum communication applications. Quantum networks are complex and must use both quantum and classical channels to support quantum applications like QKD, teleportation, and superdense coding. In particular, the no-cloning theorem prevents the reliable copying of quantum signals such that the quantum and classical channels must be highly coordinated using robust and extensible methods. In this paper, we describe new network abstractions and interfaces for building programmable quantum networks. Our approach leverages new OpenFlow data structures and table type patterns to build programmable quantum networks and to support quantum applications.

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JO - Proceedings of SPIE - The International Society for Optical Engineering

JF - Proceedings of SPIE - The International Society for Optical Engineering

M1 - 2263191

T2 - Advanced Photon Counting Techniques XI 2017

Y2 - 12 April 2017 through 13 April 2017

ER -

Software-defined network abstractions and configuration interfaces for building programmable quantum networks

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Keywords

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