Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations

Holger Boche; Minglai Cai; Christian Deppe; Janis Nötzel

doi:10.1109/ITW.2018.8613533

Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations

Holger Boche, Minglai Cai, Christian Deppe, Janis Nötzel

Chair of Theoretical Information Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Scopus citations

Abstract

We determine the secrecy capacities of AVQCs (arbitrarily varying quantum channels). Both secrecy capacity with average error probability and with maximal error probability are derived. Both derivations are based on one common code construction. The code we construct fulfills a stringent secrecy requirement, which is called the strong code concept. We determine when the secrecy capacity is a continuous function of the system parameters and completely characterize its discontinuity points both for average error criterion and for maximal error criterion. Furthermore, we prove the phenomenon “super-activation” for secrecy capacities of AVQCs, i.e., two quantum channels both with zero secrecy capacity, which, if used together, allow secure transmission with positive capacity. We also discuss the relations between the entanglement distillation capacity, the entanglement generating capacity, and the strong subspace transmission capacity for AVQCs.

Original language	English
Title of host publication	2018 IEEE Information Theory Workshop, ITW 2018
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781538635995
DOIs	https://doi.org/10.1109/ITW.2018.8613533
State	Published - 2 Jul 2018
Event	2018 IEEE Information Theory Workshop, ITW 2018 - Guangzhou, China Duration: 25 Nov 2018 → 29 Nov 2018

Publication series

Name	2018 IEEE Information Theory Workshop, ITW 2018

Conference

Conference	2018 IEEE Information Theory Workshop, ITW 2018
Country/Territory	China
City	Guangzhou
Period	25/11/18 → 29/11/18

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10.1109/ITW.2018.8613533

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Boche, H., Cai, M., Deppe, C., & Nötzel, J. (2018). Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations. In 2018 IEEE Information Theory Workshop, ITW 2018 Article 8613533 (2018 IEEE Information Theory Workshop, ITW 2018). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ITW.2018.8613533

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title = "Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations",

abstract = "We determine the secrecy capacities of AVQCs (arbitrarily varying quantum channels). Both secrecy capacity with average error probability and with maximal error probability are derived. Both derivations are based on one common code construction. The code we construct fulfills a stringent secrecy requirement, which is called the strong code concept. We determine when the secrecy capacity is a continuous function of the system parameters and completely characterize its discontinuity points both for average error criterion and for maximal error criterion. Furthermore, we prove the phenomenon “super-activation” for secrecy capacities of AVQCs, i.e., two quantum channels both with zero secrecy capacity, which, if used together, allow secure transmission with positive capacity. We also discuss the relations between the entanglement distillation capacity, the entanglement generating capacity, and the strong subspace transmission capacity for AVQCs.",

author = "Holger Boche and Minglai Cai and Christian Deppe and Janis N{\"o}tzel",

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year = "2018",

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Boche, H, Cai, M, Deppe, C & Nötzel, J 2018, Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations. in 2018 IEEE Information Theory Workshop, ITW 2018., 8613533, 2018 IEEE Information Theory Workshop, ITW 2018, Institute of Electrical and Electronics Engineers Inc., 2018 IEEE Information Theory Workshop, ITW 2018, Guangzhou, China, 25/11/18. https://doi.org/10.1109/ITW.2018.8613533

Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations. / Boche, Holger; Cai, Minglai; Deppe, Christian et al.
2018 IEEE Information Theory Workshop, ITW 2018. Institute of Electrical and Electronics Engineers Inc., 2018. 8613533 (2018 IEEE Information Theory Workshop, ITW 2018).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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N2 - We determine the secrecy capacities of AVQCs (arbitrarily varying quantum channels). Both secrecy capacity with average error probability and with maximal error probability are derived. Both derivations are based on one common code construction. The code we construct fulfills a stringent secrecy requirement, which is called the strong code concept. We determine when the secrecy capacity is a continuous function of the system parameters and completely characterize its discontinuity points both for average error criterion and for maximal error criterion. Furthermore, we prove the phenomenon “super-activation” for secrecy capacities of AVQCs, i.e., two quantum channels both with zero secrecy capacity, which, if used together, allow secure transmission with positive capacity. We also discuss the relations between the entanglement distillation capacity, the entanglement generating capacity, and the strong subspace transmission capacity for AVQCs.

AB - We determine the secrecy capacities of AVQCs (arbitrarily varying quantum channels). Both secrecy capacity with average error probability and with maximal error probability are derived. Both derivations are based on one common code construction. The code we construct fulfills a stringent secrecy requirement, which is called the strong code concept. We determine when the secrecy capacity is a continuous function of the system parameters and completely characterize its discontinuity points both for average error criterion and for maximal error criterion. Furthermore, we prove the phenomenon “super-activation” for secrecy capacities of AVQCs, i.e., two quantum channels both with zero secrecy capacity, which, if used together, allow secure transmission with positive capacity. We also discuss the relations between the entanglement distillation capacity, the entanglement generating capacity, and the strong subspace transmission capacity for AVQCs.

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Secret message transmission over quantum channels under adversarial quantum noise: Secrecy Capacity and Super-activations

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