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Kvantovaya Elektronika, 2020, Volume 50, Number 5, Pages 440–446 (Mi qe17254)  
This article is cited in 17 scientific papers (total in 17 papers)

Trends in the developments quantum communications

Quantum channel capacities

A. S. Holevo

Steklov Mathematical Institute of Russian Academy of Sciences, Moscow
Full-text PDF (822 kB) Citations (17)
References:
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Abstract: A brief general review is presented of the theory of information transmission capacities of quantum communication channels, which is a development of the classical Shannon theory. Unlike a classical communication channel, a quantum channel is characterised by a whole set of different capacities, which depend on the type of transmitted information (classical or quantum) and on additional resources used during transmission. The main characteristics of a quantum channel are considered: classical capacity, capacity assisted by entanglement between the channel input and output, quantum capacity and secret classical capacity. The unique role of the quantum entanglement property, which manifests itself, in particular, in a nonclassical phenomenon of capacity superadditivity, is emphasised.
Keywords: quantum information theory, quantum communication channel, coding theorem, capacity, entanglement, superadditivity.
Received: 11.02.2020
English version:
Quantum Electronics, 2020, Volume 50, Issue 5, Pages 440–446
DOI: https://doi.org/10.1070/QEL17285
Bibliographic databases:
Document Type: Article
Language: Russian


Citation: A. S. Holevo, “Quantum channel capacities”, Kvantovaya Elektronika, 50:5 (2020), 440–446 [Quantum Electron., 50:5 (2020), 440–446]
Linking options:
  • https://www.mathnet.ru/eng/qe17254
  • https://www.mathnet.ru/eng/qe/v50/i5/p440
    • This publication is cited in the following 17 articles:
    1. Michael Kasprzak, Erickson Tjoa, J. Phys. A: Math. Theor., 58:9 (2025), 095301  crossref
    2. Chandan Datta, Tulja Varun Kondra, Marek Miller, Alexander Streltsov, Quantum, 8 (2024), 1290  crossref
    3. Myeongjin Shin, Junseo Lee, Kabgyun Jeong, Quantum Inf Process, 23:2 (2024)  crossref
    4. Jun-Li Jiang, Ming-Xing Luo, Song-Ya Ma, IEEE J. Select. Areas Commun., 42:7 (2024), 1900  crossref
    5. Zhengzhong Yi, Zhipeng Liang, Yulin Wu, Xuan Wang, Entropy, 26:10 (2024), 818  crossref
    6. P. V. Srinidhi, Indranil Chakrabarty, Samyadeb Bhattacharya, Nirman Ganguly, Phys. Rev. A, 110:4 (2024)  crossref
    7. Asutosh Kumar, Physics Letters A, 2024, 130091  crossref
    8. Samuel C. Smith, Benjamin J. Brown, Stephen D. Bartlett, Commun Phys, 7:1 (2024)  crossref
    9. Armin Tavakoli, Alejandro Pozas-Kerstjens, Peter Brown, Mateus Araújo, Rev. Mod. Phys., 96:4 (2024)  crossref
    10. Zhengzhong Yi, Zhipeng Liang, Xuan Wang, Quantum Inf Process, 22:5 (2023)  crossref
    11. Joseph C. Chapman, Joseph M. Lukens, Muneer Alshowkan, Nageswara Rao, Brian T. Kirby, Nicholas A. Peters, Phys. Rev. Applied, 19:4 (2023)  crossref
    12. Joseph C. Chapman, Joseph M. Lukens, Muneer Alshowkan, Nageswara S. V. Rao, Brian T. Kirby, Nicholas A. Peters, Philip R. Hemmer, Alan L. Migdall, Quantum Computing, Communication, and Simulation III, 2023, 39  crossref
    13. Felix Leditzky, Debbie Leung, Vikesh Siddhu, Graeme Smith, John A. Smolin, Phys. Rev. Lett., 130:20 (2023)  crossref
    14. Grace D. Metcalfe, Boyan Tabakov, Tristan Nguyen, Jiwei Lu, Ali Sayir, AIAA Journal, 61:12 (2023), 5191  crossref
    15. Siming Zhang, Minghao Wang, Bin Zhou, Quantum Inf Process, 22:7 (2023)  crossref
    16. Zheng-Da Hu, Jicheng Wang, Yun Zhu, Mengmeng Li, Sergei Khakhomov, Igor Semchenko, Commun. Theor. Phys., 75:5 (2023), 055104  crossref
    17. E. G. El-Hadidy, K. El Anouz, N. Metwally, Mod. Phys. Lett. A, 38:26n27 (2023)  crossref
    Citing articles in Google Scholar: Russian citations, English citations
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    		Квантовая электроника Quantum Electronics
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