Queue-Channel Capacities with Generalized Amplitude Damping

The generalized amplitude damping channel (GADC) is considered an important model for quantum communications, especially over optical networks. Wemake two salient contributions in this paper apropos of this channel. First, we consider a symmetric GAD channel characterized by the parameter n = 1/2, and derive its exact classical capacity, by constructing a specific induced classical channel. We show that the Holevo quantity for the GAD channel equals the Shannon capacity of the induced binary symmetric channel, establishing at once the capacity result and that theGAD channel capacity can be achievedwithout the use of entanglement at the encoder or joint measurements at the decoder. Second, motivated by the inevitable buffering of qubits in quantum networks, we consider a generalized amplitude damping queuechannel —that is, a setting where qubits suffer a waiting time dependent GAD noise as they wait in a buffer to be transmitted. This GAD queue channel is characterized by non-i.i.d. noise due to correlated waiting times of consecutive qubits. We exploit a conditional independence property in conjunction with additivity of the channel model, to obtain a capacity expression for the GAD queue channel in terms of the stationary waiting time in the queue. Our results provide useful insights towards designing practical quantum communication networks, and highlight the need to explicitly model the impact of buffering.

[1]  C. King The capacity of the quantum depolarizing channel , 2003, IEEE Trans. Inf. Theory.

[2]  Sergio Verdú,et al.  A general formula for channel capacity , 1994, IEEE Trans. Inf. Theory.

[3]  P. Shor Additivity of the classical capacity of entanglement-breaking quantum channels , 2002, quant-ph/0201149.

[4]  Cheng-Zhi Peng,et al.  Protecting entanglement from finite-temperature thermal noise via weak measurement and quantum measurement reversal , 2017 .

[5]  Axel Dahlberg,et al.  Designing a quantum network protocol , 2020, CoNEXT.

[6]  H. Yuen Quantum detection and estimation theory , 1978, Proceedings of the IEEE.

[7]  On the Stochastic Analysis of a Quantum Entanglement Distribution Switch , 2021, IEEE Transactions on Quantum Engineering.

[8]  Richard E. Blahut,et al.  Computation of channel capacity and rate-distortion functions , 1972, IEEE Trans. Inf. Theory.

[9]  Isaac L. Chuang,et al.  Prescription for experimental determination of the dynamics of a quantum black box , 1997 .

[10]  Prabha Mandayam,et al.  The Classical Capacity of Additive Quantum Queue-Channels , 2020, IEEE Journal on Selected Areas in Information Theory.

[11]  Christopher King,et al.  Properties of Conjugate Channels with Applications to Additivity and Multiplicativity , 2005 .

[12]  Isaac L. Chuang,et al.  Quantum Computation and Quantum Information (10th Anniversary edition) , 2011 .

[13]  Peter W. Shor The adaptive classical capacity of a quantum channel, or Information capacities of three symmetric pure states in three dimensions , 2004, IBM J. Res. Dev..

[14]  Prabha Mandayam,et al.  Qubits through Queues: The Capacity of Channels with Waiting Time Dependent Errors , 2018, 2019 National Conference on Communications (NCC).

[15]  Masahito Hayashi,et al.  General formulas for capacity of classical-quantum channels , 2003, IEEE Transactions on Information Theory.

[16]  C. Monroe,et al.  Decoherence of quantum superpositions through coupling to engineered reservoirs , 2000, Nature.

[17]  R. Schumann Quantum Information Theory , 2000, quant-ph/0010060.

[18]  Simon J. Devitt,et al.  Photonic Quantum Networks formed from NV− centers , 2014, Scientific Reports.

[19]  S. Barnett,et al.  Accessible information and optimal strategies for real symmetrical quantum sources , 1998, quant-ph/9812062.

[20]  F. Schmidt,et al.  Waiting time in quantum repeaters with probabilistic entanglement swapping , 2017, Physical Review A.

[21]  Alexander S. Holevo,et al.  The Capacity of the Quantum Channel with General Signal States , 1996, IEEE Trans. Inf. Theory.

[22]  Michael D. Westmoreland,et al.  Sending classical information via noisy quantum channels , 1997 .

[23]  Jeffrey H. Shapiro,et al.  Optical communication with two-photon coherent states-Part I: Quantum-state propagation and quantum-noise , 1978, IEEE Trans. Inf. Theory.

[24]  Moe Z. Win,et al.  Quantum Queuing Delay , 2020, IEEE Journal on Selected Areas in Communications.

[25]  G. Burkard,et al.  Decoherence in solid-state qubits , 2008, 0809.4716.

[26]  侯丽珍,et al.  The Holevo capacity of a generalized amplitude-damping channel , 2007 .

[27]  C. King Additivity for unital qubit channels , 2001, quant-ph/0103156.

[28]  Lav R. Varshney,et al.  Capacity of systems with queue-length dependent service quality , 2016, 2016 International Symposium on Information Theory and Its Applications (ISITA).

[29]  M. Wilde,et al.  Information-theoretic aspects of the generalized amplitude-damping channel , 2019, 1903.07747.

[30]  C. Monroe,et al.  Decoherence and Decay of Motional Quantum States of a Trapped Atom Coupled to Engineered Reservoirs , 2000 .

[31]  V. Giovannetti,et al.  Quantum channels and memory effects , 2012, 1207.5435.

[32]  J. Shapiro The Quantum Theory of Optical Communications , 2009, IEEE Journal of Selected Topics in Quantum Electronics.

[33]  Leandros Tassiulas,et al.  Routing entanglement in the quantum internet , 2017, npj Quantum Information.

[34]  Suguru Arimoto,et al.  An algorithm for computing the capacity of arbitrary discrete memoryless channels , 1972, IEEE Trans. Inf. Theory.

[35]  Hiroki Koga,et al.  Information-Spectrum Methods in Information Theory , 2002 .

[36]  dek,et al.  Parameter regimes for a single sequential quantum repeater , 2018 .