DocumentCode
3127299
Title
Explicit capacity-achieving receivers for optical communication and quantum reading
Author
Wilde, Mark M. ; Guha, Saikat ; Tan, Si-Hui ; Lloyd, Seth
Author_Institution
Sch. of Comput. Sci., McGill Univ., Montreal, QC, Canada
fYear
2012
fDate
1-6 July 2012
Firstpage
551
Lastpage
555
Abstract
An important practical open question has been to design explicit, structured optical receivers that achieve the Holevo limit in the contexts of optical communication and “quantum reading.” The Holevo limit is an achievable rate that is higher than the Shannon limit of any known optical receiver. We demonstrate how a sequential decoding approach can achieve the Holevo limit for both of these settings. A crucial part of our scheme for both settings is a non-destructive “vacuum-or-not” measurement that projects an n-symbol modulated codeword onto the n-fold vacuum state or its orthogonal complement, such that the post-measurement state is either the n-fold vacuum or has the vacuum removed from the support of the n symbols´ joint quantum state. The sequential decoder for optical communication requires the additional ability to perform multimode optical phase-space displacements - realizable using a beamsplitter and a laser, while the sequential decoder for quantum reading also requires the ability to perform phase-shifting (realizable using a phase plate) and online squeezing (a phase-sensitive amplifier).
Keywords
decoding; optical beam splitters; optical communication; optical receivers; orthogonal codes; sequential codes; Holevo limit; Shannon limit; beamsplitter; explicit capacity-achieving receivers; laser; multimode optical phase-space displacements; n symbol joint quantum state; n-fold vacuum state; n-symbol modulated codeword; nondestructive vacuum-or-not measurement; online squeezing; optical communication; orthogonal complement codes; phase-shifting; post-measurement state; quantum reading; sequential decoding approach; structured optical receivers; Decoding; Optical fiber communication; Optical receivers; Optical transmitters; Photonics; Quantum mechanics;
fLanguage
English
Publisher
ieee
Conference_Titel
Information Theory Proceedings (ISIT), 2012 IEEE International Symposium on
Conference_Location
Cambridge, MA
ISSN
2157-8095
Print_ISBN
978-1-4673-2580-6
Electronic_ISBN
2157-8095
Type
conf
DOI
10.1109/ISIT.2012.6284251
Filename
6284251
Link To Document