Simulations of Photonic Quantum Networks for Performance Analysis and Experiment Design

This work models metropolitan-scale photonic quantum networks that use time bin encoding for quantum key distribution and quantum state teleportation. We develop and validate theoretical models by comparing them with prior experimental results. We use our newly developed simulator of quantum network communication, called SeQUeNCe, to perform simulations at the individual photon level with picosecond resolution. The simulator integrates accurate models of optical components including light sources, interferometers, detectors, beam splitters, and telecommunication fiber, allowing studies of their complex interactions. Optical quantum networks have been generating significant interest because of their ability to provide secure communication, enable new functionality such as clock synchronization with unprecedented accuracy, and reduce the communication complexity of certain distributed computing problems. In the past few years experimental demonstrations moved from table-top experiments to metropolitan-scale deployments and long-distance repeater network prototypes. As the number of optical components in these experiments increases, simulation tools such as SeQUeNCe will simplify experiment planning and accelerate designs of new network protocols. The modular design of our tool will also allow modeling future technologies such as network nodes with quantum memories and quantum transducers as they become available.

[1]  Marcin Niemiec,et al.  Quantum Cryptography Protocol Simulator , 2011, MCSS.

[2]  Jeffrey H. Shapiro,et al.  Complete physical simulation of the entangling-probe attack on the BB84 protocol , 2007, QELS 2007.

[3]  Christoph Pacher,et al.  Demystifying the information reconciliation protocol cascade , 2014, Quantum Inf. Comput..

[4]  Andrew M. Childs Secure assisted quantum computation , 2001, Quantum Inf. Comput..

[5]  Charles H. Bennett,et al.  Teleporting an unknown quantum state via dual classical and Einstein-Podolsky-Rosen channels. , 1993, Physical review letters.

[6]  Ivan Damgård,et al.  Secure identification and QKD in the bounded-quantum-storage model , 2014, Theor. Comput. Sci..

[7]  Davide Castelvecchi,et al.  The quantum internet has arrived (and it hasn’t) , 2018, Nature.

[8]  Peter W. Shor,et al.  Polynomial-Time Algorithms for Prime Factorization and Discrete Logarithms on a Quantum Computer , 1995, SIAM Rev..

[9]  S. Wehner,et al.  Device-independent two-party cryptography secure against sequential attacks , 2016, 1601.06752.

[10]  T. Wei,et al.  Beating the channel capacity limit for linear photonic superdense coding , 2008 .

[11]  Gilles Brassard,et al.  Secret-Key Reconciliation by Public Discussion , 1994, EUROCRYPT.

[12]  O. Okunev,et al.  Picosecond superconducting single-photon optical detector , 2001 .

[13]  Ekert,et al.  Quantum cryptography based on Bell's theorem. , 1991, Physical review letters.

[14]  Nathan K Langford,et al.  Generation of hyperentangled photon pairs. , 2005, Physical review letters.

[15]  Colin P. Williams,et al.  Quantum clock synchronization based on shared prior entanglement , 2000, Physical review letters.

[16]  Jian-Wei Pan,et al.  Ground-to-satellite quantum teleportation , 2017, Nature.

[17]  M. Siegel,et al.  Demonstration of digital readout circuit for superconducting nanowire single photon detector. , 2011, Optics express.

[18]  Gilles Brassard Quantum communication complexity: a survey , 2004, Proceedings. 34th International Symposium on Multiple-Valued Logic.

[19]  Axel Dahlberg,et al.  SimulaQron—a simulator for developing quantum internet software , 2017, Quantum Science and Technology.

[20]  W Tittel,et al.  Distribution of time-bin entangled qubits over 50 km of optical fiber. , 2004, Physical review letters.

[21]  F. Marsili,et al.  Detecting single infrared photons with 93% system efficiency , 2012, 1209.5774.

[22]  Xiaosong Ma,et al.  Quantum teleportation over 143 kilometres using active feed-forward , 2012, Nature.

[23]  Achim Peters,et al.  Mobile quantum gravity sensor with unprecedented stability , 2015, 1512.05660.

[24]  P Chan,et al.  Efficient Bell state analyzer for time-bin qubits with fast-recovery WSi superconducting single photon detectors. , 2014, Optics express.

[25]  A. Pereszlenyi,et al.  Simulation of quantum key distribution with noisy channels , 2005, Proceedings of the 8th International Conference on Telecommunications, 2005. ConTEL 2005..

[26]  Lin Kang,et al.  Counting rate enhancements in superconducting nanowire single-photon detectors with improved readout circuits. , 2014, Optics letters.

[27]  N. Gisin,et al.  Pulsed Energy-Time Entangled Twin-Photon Source for Quantum Communication , 1999 .

[28]  Haiyuan Liu,et al.  Parameter optimization of cascade in quantum key distribution , 2019, Optik.

[29]  Stefan Rass,et al.  Implementation of quantum key distribution network simulation module in the network simulator NS-3 , 2017, Quantum Information Processing.

[30]  G. H. Aguilar,et al.  Quantum teleportation across a metropolitan fibre network , 2016, Nature Photonics.

[31]  Z. Yuan,et al.  Quantum key distribution over 122 km of standard telecom fiber , 2004, quant-ph/0412171.

[32]  Gilles Brassard,et al.  Quantum cryptography: Public key distribution and coin tossing , 2014, Theor. Comput. Sci..