• Effects of the Generation Size...

Treffer: Effects of the Generation Size and Overlap on Throughput and Complexity in Randomized Linear Network Coding

Title:
Effects of the Generation Size and Overlap on Throughput and Complexity in Randomized Linear Network Coding
Authors:
YAO LI, SOLJANIN, Emina, SPASOJEVIC, Predrag
Source:
Facets of Coding Theory: From Algorithms to Networks. Special Issue Dedicated to the Scientific Legacy of Ralf KoetterIEEE transactions on information theory. 57(2):1111-1123
Publisher Information:
New York, NY: Institute of Electrical and Electronics Engineers, 2011.
Publication Year:
2011
Physical Description:
print, 16 ref
Original Material:
INIST-CNRS
Subject Terms:
Telecommunications, Télécommunications, Sciences exactes et technologie, Exact sciences and technology, Sciences appliquees, Applied sciences, Telecommunications et theorie de l'information, Telecommunications and information theory, Théorie de l'information, du signal et des communications, Information, signal and communications theory, Théorie de l'information, Information theory, Théorie du signal et des communications, Signal and communications theory, Codage, codes, Coding, codes, Télécommunications, Telecommunications, Systèmes, réseaux et services de télécommunications, Systems, networks and services of telecommunications, Transmission et modulation (techniques et équipements), Transmission and modulation (techniques and equipments), Codage linéaire, Linear coding, Codificación lineal, Complexité calcul, Computational complexity, Complejidad computación, Débit information, Information rate, Índice información, Décodage, Decoding, Desciframiento, Défaillance, Failures, Fallo, Fourniture information, Information delivery, Entrega informacíon, Ordonnancement, Scheduling, Reglamento, Perte transmission, Transmission loss, Pérdida transmisión, Temps retard, Delay time, Tiempo retardo, Transmission donnée, Data transmission, Transmisión datos, Transmission information, Information transmission, Transmisión información, Coupon collector's problem, Network coding, rateless codes
Document Type:
Fachzeitschrift Article
File Description:
text
Language:
English
Author Affiliations:
WINLAB, Department of Electrical and Computer Engineering, Rutgers University, North Brunswick, NJ 08902, United States
Mathematics of Networking and Communication Department, Enabling Computing Technologies, Bell Laboratories, Alcatel-Lucent, Murray Hill, NJ 07974, United States
ISSN:
0018-9448
Access URL:
http://pascal-francis.inist.fr/vibad/index.php?action=search&terms=23938019
Rights:
Copyright 2015 INIST-CNRS
CC BY 4.0
Sauf mention contraire ci-dessus, le contenu de cette notice bibliographique peut être utilisé dans le cadre d’une licence CC BY 4.0 Inist-CNRS / Unless otherwise stated above, the content of this bibliographic record may be used under a CC BY 4.0 licence by Inist-CNRS / A menos que se haya señalado antes, el contenido de este registro bibliográfico puede ser utilizado al amparo de una licencia CC BY 4.0 Inist-CNRS
Notes:
Telecommunications and information theory
Accession Number:
edscal.23938019
Database:
PASCAL Archive

Weitere Informationen

To reduce computational complexity and delay in randomized network coded content distribution, and for some other practical reasons, coding is not performed simultaneously over all content blocks, but over much smaller, possibly overlapping subsets of these blocks, known as generations. A penalty of this strategy is throughput reduction. To analyze the throughput loss, we model coding over generations with random generation scheduling as a coupon collector's brotherhood problem. This model enables us to derive the expected number of coded packets needed for successful decoding of the entire content as well as the probability of decoding failure (the latter only when generations do not overlap) and further, to quantify the tradeoff between computational complexity and throughput. Interestingly, with a moderate increase in the generation size, throughput quickly approaches link capacity. Overlaps between generations can further improve throughput substantially for relatively small generation sizes.