A unification of network coding and tree-packing (routing) theorems

Given a network of lossless links with rate constraints, a source node, and a set of destination nodes, the multicast capacity is the maximum rate at which the source can transfer common information to the destinations. The multicast capacity cannot exceed the capacity of any cut separating the sour...

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Bibliographic Details
Published inIEEE transactions on information theory Vol. 52; no. 6; pp. 2398 - 2409
Main Authors Wu, Yunnan, Jain, Kamal, Sun-Yuan, Kung
Format Journal Article
LanguageEnglish
Published New York IEEE 01.06.2006
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Acoustic materials
Acoustic signal processing
Codes
Coding
Communications networks
Computer networks
Constraint theory
Data transmission
Flow
Graph theory
Multicast
Network coding
Networks
Packet switched networks
Proving
Relays
Routing
Routing (telecommunications)
Speech processing
Steiner tree
Studies
Tail
Theorems
Theory
Upper bound
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Summary:Given a network of lossless links with rate constraints, a source node, and a set of destination nodes, the multicast capacity is the maximum rate at which the source can transfer common information to the destinations. The multicast capacity cannot exceed the capacity of any cut separating the source from a destination; the minimum of the cut capacities is called the cut bound. A fundamental theorem in graph theory by Edmonds established that if all nodes other than the source are destinations, the cut bound can be achieved by routing. In general, however, the cut bound cannot be achieved by routing. Ahlswede et al. established that the cut bound can be achieved by performing network coding, which generalizes routing by allowing information to be mixed. This paper presents a unifying theorem that includes Edmonds' theorem and Ahlswede et al.'s theorem as special cases. Specifically, it shows that the multicast capacity can still be achieved even if information mixing is only allowed on edges entering relay nodes. This unifying theorem is established via a graph theoretic hardwiring theorem, together with the network coding theorems for multicasting. The proof of the hardwiring theorem implies a new proof of Edmonds' theorem.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0018-9448
1063-6692
1557-9654
1558-2566
DOI:10.1109/TIT.2006.874430