Spelling suggestions: "subject:"bnetwork error correction"" "subject:"bnetwork error eorrection""
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Exploiting the implicit error correcting ability of networks that use random network coding / by Suné von SolmsVon Solms, Suné January 2009 (has links)
In this dissertation, we developed a method that uses the redundant information implicitly
generated inside a random network coding network to apply error correction to the transmitted
message. The obtained results show that the developed implicit error correcting method can
reduce the effect of errors in a random network coding network without the addition of
redundant information at the source node. This method presents numerous advantages
compared to the documented concatenated error correction methods.
We found that various error correction schemes can be implemented without adding
redundancy at the source nodes. The decoding ability of this method is dependent on the
network characteristics. We found that large networks with a high level of interconnectivity
yield more redundant information allowing more advanced error correction schemes to be
implemented.
Network coding networks are prone to error propagation. We present the results of the
effect of link error probability on our scheme and show that our scheme outperforms
concatenated error correction schemes for low link error probability. / Thesis (M.Ing. (Computer Engineering))--North-West University, Potchefstroom Campus, 2010.
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Exploiting the implicit error correcting ability of networks that use random network coding / by Suné von SolmsVon Solms, Suné January 2009 (has links)
In this dissertation, we developed a method that uses the redundant information implicitly
generated inside a random network coding network to apply error correction to the transmitted
message. The obtained results show that the developed implicit error correcting method can
reduce the effect of errors in a random network coding network without the addition of
redundant information at the source node. This method presents numerous advantages
compared to the documented concatenated error correction methods.
We found that various error correction schemes can be implemented without adding
redundancy at the source nodes. The decoding ability of this method is dependent on the
network characteristics. We found that large networks with a high level of interconnectivity
yield more redundant information allowing more advanced error correction schemes to be
implemented.
Network coding networks are prone to error propagation. We present the results of the
effect of link error probability on our scheme and show that our scheme outperforms
concatenated error correction schemes for low link error probability. / Thesis (M.Ing. (Computer Engineering))--North-West University, Potchefstroom Campus, 2010.
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On Network Coding and Network-Error CorrectionPrasad, Krishnan January 2013 (has links) (PDF)
The paradigm of network coding was introduced as a means to conserve bandwidth (or equivalently increase throughput) in information flow networks. Network coding makes use of the fact that unlike physical commodities, information can be replicated and coded together at the nodes of the network. As a result, routing can be strictly suboptimal in many classes of information flow networks compared to network coding. Network-error correction is the art of designing network codes such that the sinks of the network will be able to decode the required information in the presence of errors in the edges of the network, known as network-errors. The network coding problem on a network with given sink demands can be considered to have the following three major subproblems, which naturally also extend to the study of network-error correcting codes, as they can be viewed as a special class of network codes (a) Existence of a network code that satisfies the demands (b) Efficient construction of such a network code (c) Minimum alphabet size for the existence of such a network code.
This thesis primarily considers linear network coding and error correction and in- vestigates solutions to these issues for certain classes of network coding and error correction problems in acyclic networks. Our contributions are broadly summarised as follows.
(1) We propose the use of convolutional codes for multicast network-error correc- tion. Depending upon the number of network-errors required to be corrected in the network, convolutional codes are designed at the source of the multicast network so that these errors can be corrected at the sinks of the networks as long as they are separated by certain number of time instants (for which we give a bound). In con- trast to block codes for network-error correction which require large field sizes, using convolutional codes enables the field size of the network code to be small. We discuss the performance of such networks under the BSC edge error model.
(2)Existing construction algorithms of block network-error correcting codes require a rather large field size, which grows with the size of the network and the number of sinks, and thereby can be prohibitive in large networks. In our work, we give an algorithm which, starting from a given network-error correcting code, can obtain an- other network code using a small field, with the same error correcting capability as the original code. The major step in our algorithm is to find a least degree irreducible poly- nomial which is coprime to another large degree polynomial. We utilize the algebraic properties of finite fields to implement this step so that it becomes much faster than the brute-force method. A recently proposed algorithm for network coding using small fields can be seen as a special case of our algorithm for the case of no network-errors.
(3)Matroids are discrete mathematical objects which generalize the notion of linear independence of sets of vectors. It has been observed recently that matroids and network coding share a deep connection, and several important results of network coding has been obtained using these connections from matroid theory. In our work, we establish that matroids with certain special properties correspond to networks with error detecting and correcting properties. We call such networks as matroidal error detecting (or equivalently, correcting) networks. We show that networks have scalar linear network-error detecting (or correcting) codes if and only if there are associated with representable matroids with some special properties. We also use these ideas to construct matroidal error correcting networks along with their associated matroids. In the case of representable matroids, these algorithms give rise to scalar linear network- error correcting codes on such networks. Finally we also show that linear network coding is not sufficient for the general network-error detection (correction) problem with arbitrary demands.
(4)Problems related to network coding for acyclic, instantaneous networks have been extensively dealt with in the past. In contrast, not much attention has been paid to networks with delays. In our work, we elaborate on the existence, construction and minimum field size issues of network codes for networks with integer delays. We show that the delays associated with the edges of the network cannot be ignored, and in fact turn out to be advantageous, disadvantageous or immaterial, depending on the topology of the network and the network coding problem considered. In the process, we also show multicast network codes which involve only delaying the symbols arriving at the nodes of the networks and coding the delayed symbols over a binary field, thereby making coding operations at the nodes less complex.
(5) In the usual network coding framework, for a given set of network demands over an arbitrary acyclic network with integer delays assumed for the links, the out- put symbols at the sink nodes, at any given time instant, is a Fq-linear combination of the input symbols generated at different time instants where Fq denotes the field over which the network operates. Therefore the sinks have to use sufficient memory elements in order to decode simultaneously for the entire stream of demanded infor- mation symbols. We propose a scheme using an ν-point finite-field discrete fourier transform (DFT) which converts the output symbols at the sink nodes at any given time instant, into a Fq-linear combination of the input symbols generated during the same time instant without making use of memory at the intermediate nodes. We call this as transforming the acyclic network with delay into ν-instantaneous networks (ν is sufficiently large). We show that under certain conditions, there exists a network code satisfying sink demands in the usual (non-transform) approach if and only if there exists a network code satisfying sink demands in the transform approach.
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