On Network Coding for Sum-Networks

Kumar, Brijesh; Dey, Bikash Kumar

doi:10.1109/tit.2011.2169532

Cited by 74 publications

(109 citation statements)

References 34 publications

(64 reference statements)

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“…However, no handy necessary condition has been derived in [19] for the nonexistence of linear solutions, and this is a key reason that only a few exemplifying networks with the special property q min < q * max were designed therein. For instance, the nonexistence of a linear solution over GF (17) Recall that when q − 1 is prime, Cauchy-Davenport Theorem asserts that for any two nonempty subsets A and B of Z q−1 , |A + B| ≥ min{|A| + |B| − 1, q − 1}. Thus, for arbitrary We next generalize the Cauchy-Davenport Theorem to be over Z q−1 , where q − 1 can be a composite.…”

Section: Has a Linear Solution Over Gf(q) If And Only Ifmentioning

confidence: 99%

“…Specifically, a general method was proposed in [16] to associate a polynomial set with a network, such that the polynomials have common roots over a field if and only if the corresponding network has a linear solution over the same field. In [17], analogous equivalence was also established between the existence of common roots over a finite field for a polynomial set and the existence of a linear solution over the same field for an associated sum-network, in which all receivers attempt to recover the sum of all source data symbols. However, when attention is only paid to multicast networks, these results are not applicable anymore.…”

Section: Introductionmentioning

confidence: 96%

“…However, when attention is only paid to multicast networks, these results are not applicable anymore. First, since a multicast network is linearly solvable over a large enough field, it is linearly solvable over some field of characteristic p for every prime p. Moreover, the general method proposed in [16] and [17] cannot necessarily construct a multicast network from a polynomial set.…”

Section: Introductionmentioning

confidence: 99%

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On base field of linear network coding

Sun

2015

2015 International Symposium on Network Coding (NetCod)

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For a (single-source) multicast network, the size of a base field is the most known and studied algebraic identity that is involved in characterizing its linear solvability over the base field. In this paper, we design a new class N of multicast networks and obtain an explicit formula for the linear solvability of these networks, which involves the associated coset numbers of a multiplicative subgroup in a base field. The concise formula turns out to be the first that matches the topological structure of a multicast network and algebraic identities of a field other than size. It further facilitates us to unveil infinitely many new multicast networks linearly solvable over GF(q) but not over GF(q ′ ) with q < q ′ , based on a subgroup order criterion. In particular, i) for every k ≥ 2, an instance in N can be found linearly solvable over GF(2 2k ) but not over GF(2 2k+1 ), and ii) for arbitrary distinct primes p and p ′ , there are infinitely many k and k ′ such that an instance in N can be found linearly solvable over GF(p k )but not over GF(pOn the other hand, the construction of N also leads to a new class of multicast networks with Θ(q 2 ) nodes and Θ(q 2 ) edges, where q ≥ 5 is the minimum field size for linear solvability of the network.

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Section: Has a Linear Solution Over Gf(q) If And Only Ifmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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On base field of linear network coding

Sun

2015

2015 International Symposium on Network Coding (NetCod)

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“…In this paper, we show that for many function classes of practical interest, noninteractive function computation using computation trees can give near-optimal performance. 6) Function Multicasting: One particular problem that has attracted attention is the case where there are several sources, and each destination demands the sum of the sources [34], [35], [37]. In our terminology, we call this the function multicasting problem; in this case, the function happens to be linear as well.In [37], the case of a directed acyclic communication graph is considered and several negative results demonstrating the insufficiency of scalar and vector linear coding is shown, deriving inspiration from similar results for multiple unicast in directed networks.…”

Section: Fig 1: Multi-session Examplementioning

confidence: 99%

Multi-Session Function Computation and Multicasting in Undirected Graphs

Kannan

Viswanath

2013

IEEE J. Select. Areas Commun.

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Abstract-In the function computation problem, certain nodes of an undirected graph have access to independent data, while some other nodes of the graph require certain functions of the data; this model, motivated by sensor networks and cloud computing, is the focus of this paper. We study the maximum rates at which function computation is possible on a capacitated graph; the capacities on the edges of the graph impose constraints on the communication rate.We consider a simple class of computation strategies based on Steiner-tree packing (so-called computation trees), which does not involve block coding and has minimal delay. With a single terminal requiring function computation, computation trees are known to be optimal when the underlying graph is itself a directed tree, but have arbitrarily poor performance in general directed graphs. Our main result is that computation trees are near optimal for a wide class of function computation requirements even at multiple terminals in undirected graphs.The key technical contribution involves connecting approximation algorithms for Steiner cuts in undirected graphs to the function computation problem. Furthermore, we show that existing algorithms for Steiner tree packings allow us to compute approximately optimal packings of computation trees in polynomial time. We also show a close connection between the function computation problem and a communication problem involving multiple multicasts.

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“…The notion of min-cut bound for the network coding problem [2] was extended to the function computation problem in a directed acyclic network with multiple sources and one sink in [8]. The case of directed acyclic network with multiple sources, multiple sinks and each sink demanding the sum of source messages was studied in [10]; such a network is called a sum-network. Relation between linear solvability of multiple-unicast networks and sum-networks was established.…”

Section: Introductionmentioning

confidence: 99%

A Relation Between Network Computation and Functional Index Coding Problems

Gupta

Rajan

2017

IEEE Trans. Commun.

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Abstract-In contrast to the network coding problem wherein the sinks in a network demand subsets of the source messages, in a network computation problem the sinks demand functions of the source messages. Similarly, in the functional index coding problem, the side information and demands of the clients include disjoint sets of functions of the information messages held by the transmitter instead of disjoint subsets of the messages, as is the case in the conventional index coding problem. It is known that any network coding problem can be transformed into an index coding problem and vice versa. In this work, we establish a similar relationship between network computation problems and a class of functional index coding problems, viz., those in which only the demands of the clients include functions of messages. We show that any network computation problem can be converted into a functional index coding problem wherein some clients demand functions of messages and vice versa. We prove that a solution for a network computation problem exists if and only if a functional index code (of a specific length determined by the network computation problem) for a suitably constructed functional index coding problem exists. And, that a functional index coding problem admits a solution of a specified length if and only if a suitably constructed network computation problem admits a solution.

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On Network Coding for Sum-Networks

Cited by 74 publications

References 34 publications

On base field of linear network coding

On base field of linear network coding

Multi-Session Function Computation and Multicasting in Undirected Graphs

A Relation Between Network Computation and Functional Index Coding Problems

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