169,350 research outputs found
A Relation Between Network Computation and Functional Index Coding Problems
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.Comment: 3 figures, 7 tables and 9 page
TDMA is Optimal for All-unicast DoF Region of TIM if and only if Topology is Chordal Bipartite
The main result of this work is that an orthogonal access scheme such as TDMA
achieves the all-unicast degrees of freedom (DoF) region of the topological
interference management (TIM) problem if and only if the network topology graph
is chordal bipartite, i.e., every cycle that can contain a chord, does contain
a chord. The all-unicast DoF region includes the DoF region for any arbitrary
choice of a unicast message set, so e.g., the results of Maleki and Jafar on
the optimality of orthogonal access for the sum-DoF of one-dimensional convex
networks are recovered as a special case. The result is also established for
the corresponding topological representation of the index coding problem
On the Capacity Region for Index Coding
A new inner bound on the capacity region of a general index coding problem is
established. Unlike most existing bounds that are based on graph theoretic or
algebraic tools, the bound is built on a random coding scheme and optimal
decoding, and has a simple polymatroidal single-letter expression. The utility
of the inner bound is demonstrated by examples that include the capacity region
for all index coding problems with up to five messages (there are 9846
nonisomorphic ones).Comment: 5 pages, 6 figures, accepted to the 2013 IEEE International Symposium
on Information Theory (ISIT), Istanbul, Turkey, July 201
Optimal Index Codes via a Duality between Index Coding and Network Coding
In Index Coding, the goal is to use a broadcast channel as efficiently as
possible to communicate information from a source to multiple receivers which
can possess some of the information symbols at the source as side-information.
In this work, we present a duality relationship between index coding (IC) and
multiple-unicast network coding (NC). It is known that the IC problem can be
represented using a side-information graph (with number of vertices
equal to the number of source symbols). The size of the maximum acyclic induced
subgraph, denoted by is a lower bound on the \textit{broadcast rate}.
For IC problems with and , prior work has shown that
binary (over ) linear index codes achieve the lower bound
for the broadcast rate and thus are optimal. In this work, we use the the
duality relationship between NC and IC to show that for a class of IC problems
with , binary linear index codes achieve the lower bound on
the broadcast rate. In contrast, it is known that there exists IC problems with
and optimal broadcast rate strictly greater than
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