Network Coding in Minimal Multicast Networks

Rouayheb, Salim Y. El; Georghiades, C.N.; Sprintson, Alex

doi:10.1109/itw.2006.1633835

Cited by 10 publications

(23 citation statements)

References 11 publications

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“…For h = 2, we assume G is a minimal network supporting h = 2 [15], i.e., any edge removal makes a multicast rate 2 infeasible. For such edge-minimal networks, we sometimes consider its orientation in which the max-flow from the source to each receiver is 2, and refer to the in-degree and out-degree of nodes in such an orientation.…”

Section: Network Model and Preliminariesmentioning

confidence: 99%

Information multicast in (pseudo-)planar networks: Efficient network coding over small finite fields

Xiahou

2013

2013 International Symposium on Network Coding (NetCod)

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Abstract-Network coding encourages in-network mixing of information flows for enhanced network capacity, particularly for multicast data dissemination. This work aims to explore properties in the underlying network topology for efficient network coding solutions, including efficient code assignment algorithms and efficient encoding/decoding operations that come with small base field sizes. The following cases of (pseudo-)planar types of networks are studied: outer-planar networks where all nodes colocate on a common face, relay/terminal co-face networks where all relay/terminal nodes co-locate on a common face, general planar networks, and apex networks.

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Section: Network Model and Preliminariesmentioning

confidence: 99%

Information multicast in (pseudo-)planar networks: Efficient network coding over small finite fields

Xiahou

2013

2013 International Symposium on Network Coding (NetCod)

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“…Combined with Kuratowski's Theorem [6], this further implies that coding over F 3 suffices for all planar networks. While there exist proofs for the latter result that exploit planarity of the network [5], [8], our result reveals that whether planarity holds is actually not important, and planar networks enjoy the sufficiency of F 3 because they form a special class of K 5 -free networks. Our result also reveals that the de facto standard of using F 2 8 and F 2 16 in network coding implementations is an overkill, in the sense that no conceivable real-world network can have a so large clique minor.…”

Section: Introductionmentioning

confidence: 76%

“…A multicast network is h-minimal if it can deliver h flows to all the receivers but not with any of its links removed. The in-degree of a node is at most h in such a network [8].…”

Section: A Network Model and Basic Definitionsmentioning

confidence: 99%

“…To study this conjecture, we focus on the basic scenario of multicast, where the source has two information flows to disseminate. A multicast network G is 2-minimal if a multicast rate 2 is feasible in G but infeasible with any edge in G removed [8]. 2-minimal networks are easy to analyze, yet fundamental: they lead to the largest known throughput gap between network coding and routing [9], and require a fullfledged suite of coding operations based on unbounded field sizes, for unlimited number of receivers [4], [9].…”

Section: Introductionmentioning

confidence: 99%

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A graph minor perspective to network coding: Connecting algebraic coding with network topologies

Yin

Yan

Wang

et al. 2013

2013 Proceedings IEEE INFOCOM

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Abstract-Network Coding encourages information coding across a communication network. While the necessity, benefit and complexity of network coding are sensitive to the underlying graph structure of a network, existing theory on network coding often treats the network topology as a black box, focusing on algebraic or information theoretic aspects of the problem. This work aims at an in-depth examination of the relation between algebraic coding and network topologies. We mathematically establish a series of results along the direction of: if network coding is necessary/beneficial, or if a particular finite field is required for coding, then the network must have a corresponding hidden structure embedded in its underlying topology, and such embedding is computationally efficient to verify. Specifically, we first formulate a meta-conjecture, the NC-Minor Conjecture, that articulates such a connection between graph theory and network coding, in the language of graph minors. We next prove that the NC-Minor Conjecture is almost equivalent to the Hadwiger Conjecture, which connects graph minors with graph coloring. Such equivalence implies the existence of K4, K5, K6, and K O(q/ log q) minors, for networks requiring F3, F4, F5 and Fq, respectively. We finally prove that network coding can make a difference from routing only if the network contains a K4 minor, and this minor containment result is tight. Practical implications of the above results are discussed.

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“…In the literature of network coding, the case of two integral flows has attracted considerable research interests [7] [8]. It represents the most basic scenario where network coding can make a difference from routing.…”

Section: Upper-bounds On the Number Of Relay Nodesmentioning

confidence: 99%

Min-cost multicast networks in Euclidean space

Yin

Wang

et al. 2012

2012 IEEE International Symposium on Information Theory Proceedings

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Abstract-Space information flow is a new field of research recently proposed by Li and Wu [1], [2]. It studies the transmission of information in a geometric space, where information flows can be routed along any trajectories, and can be encoded wherever they meet. The goal is to satisfy given endto-end unicast/multicast throughput demands, while minimizing a natural bandwidth-distance sum-product (network volume). Space information flow models the design of a blueprint for a minimum-cost network. We study the multicast version of the space information flow problem, in Euclidean spaces. We present a simple example that demonstrates the design of an information network is indeed different from that of a transportation network. We discuss properties of optimal multicast network embedding, prove that network coding does not make a difference in the basic case of 1-to-2 multicast, and prove upper-bounds on the number of relay nodes required in an optimal multicast network in general.

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Network Coding in Minimal Multicast Networks

Cited by 10 publications

References 11 publications

Information multicast in (pseudo-)planar networks: Efficient network coding over small finite fields

Information multicast in (pseudo-)planar networks: Efficient network coding over small finite fields

A graph minor perspective to network coding: Connecting algebraic coding with network topologies

Min-cost multicast networks in Euclidean space

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