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Polar Codes for Degradable Quantum Channels
- Source :
- IEEE Transactions on Information Theory. 59:4718-4729
- Publication Year :
- 2013
- Publisher :
- Institute of Electrical and Electronics Engineers (IEEE), 2013.
-
Abstract
- Channel polarization is a phenomenon in which a particular recursive encoding induces a set of synthesized channels from many instances of a memoryless channel, such that a fraction of the synthesized channels becomes near perfect for data transmission and the other fraction becomes near useless for this task. Mahdavifar and Vardy have recently exploited this phenomenon to construct codes that achieve the symmetric private capacity for private data transmission over a degraded wiretap channel. In the current paper, we build on their work and demonstrate how to construct quantum wiretap polar codes that achieve the symmetric private capacity of a degraded quantum wiretap channel with a classical eavesdropper. Due to the Schumacher-Westmoreland correspondence between quantum privacy and quantum coherence, we can construct quantum polar codes by operating these quantum wiretap polar codes in superposition, much like Devetak's technique for demonstrating the achievability of the coherent information rate for quantum data transmission. Our scheme achieves the symmetric coherent information rate for quantum channels that are degradable with a classical environment. This condition on the environment may seem restrictive, but we show that many quantum channels satisfy this criterion, including amplitude damping channels, photon-detected jump channels, dephasing channels, erasure channels, and cloning channels. Our quantum polar coding scheme has the desirable properties of being channel-adapted and symmetric capacity-achieving along with having an efficient encoder, but we have not demonstrated that the decoding is efficient. Also, the scheme may require entanglement assistance, but we show that the rate of entanglement consumption vanishes in the limit of large blocklength if the channel is degradable with classical environment.<br />12 pages, 1 figure; v2: IEEE format, minor changes including new figure; v3: minor changes, accepted for publication in IEEE Transactions on Information Theory
- Subjects :
- FOS: Computer and information sciences
Physics
Quantum Physics
Information Theory (cs.IT)
Computer Science - Information Theory
Dephasing
FOS: Physical sciences
Coherent information
Quantum entanglement
Library and Information Sciences
Topology
Computer Science Applications
Quantum Physics (quant-ph)
Quantum
Decoding methods
Computer Science::Information Theory
Information Systems
Communication channel
Coherence (physics)
Data transmission
Subjects
Details
- ISSN :
- 15579654 and 00189448
- Volume :
- 59
- Database :
- OpenAIRE
- Journal :
- IEEE Transactions on Information Theory
- Accession number :
- edsair.doi.dedup.....8328655493976eae40c45221e3f0cc4e
- Full Text :
- https://doi.org/10.1109/tit.2013.2250575