28,392 research outputs found
On the optimization of bipartite secret sharing schemes
Optimizing the ratio between the maximum length of the shares and the length of the secret value in secret sharing schemes for general access structures is an extremely difficult and long-standing open problem. In this paper, we study it for bipartite access structures, in which the set of participants is divided in two parts, and all participants in each part play an equivalent role. We focus on the search of lower bounds by using a special class of polymatroids that is introduced here, the tripartite ones. We present a method based on linear programming to compute, for every given bipartite access structure, the best lower bound that can be obtained by this combinatorial method. In addition, we obtain some general lower bounds that improve the previously known ones, and we construct optimal secret sharing schemes for a family of bipartite access structures.Peer ReviewedPostprint (author's final draft
On asymptotically good ramp secret sharing schemes
Asymptotically good sequences of linear ramp secret sharing schemes have been
intensively studied by Cramer et al. in terms of sequences of pairs of nested
algebraic geometric codes. In those works the focus is on full privacy and full
reconstruction. In this paper we analyze additional parameters describing the
asymptotic behavior of partial information leakage and possibly also partial
reconstruction giving a more complete picture of the access structure for
sequences of linear ramp secret sharing schemes. Our study involves a detailed
treatment of the (relative) generalized Hamming weights of the considered
codes
Economical (k,m)-threshold controlled quantum teleportation
We study a (k,m)-threshold controlling scheme for controlled quantum
teleportation. A standard polynomial coding over GF(p) with prime p > m-1 needs
to distribute a d-dimensional qudit with d >= p to each controller for this
purpose. We propose a scheme using m qubits (two-dimensional qudits) for the
controllers' portion, following a discussion on the benefit of a quantum
control in comparison to a classical control of a quantum teleportation.Comment: 11 pages, 2 figures, v2: minor revision, discussions improved, an
equation corrected in procedure (A) of section 4.3, v3: major revision,
protocols extended, citations added, v4: minor grammatical revision, v5:
minor revision, discussions extende
Network Codes Resilient to Jamming and Eavesdropping
We consider the problem of communicating information over a network secretly
and reliably in the presence of a hidden adversary who can eavesdrop and inject
malicious errors. We provide polynomial-time, rate-optimal distributed network
codes for this scenario, improving on the rates achievable in previous work.
Our main contribution shows that as long as the sum of the adversary's jamming
rate Zo and his eavesdropping rate Zi is less than the network capacity C,
(i.e., Zo+Zi<C), our codes can communicate (with vanishingly small error
probability) a single bit correctly and without leaking any information to the
adversary. We then use this to design codes that allow communication at the
optimal source rate of C-Zo-Zi, while keeping the communicated message secret
from the adversary. Interior nodes are oblivious to the presence of adversaries
and perform random linear network coding; only the source and destination need
to be tweaked. In proving our results we correct an error in prior work by a
subset of the authors in this work.Comment: 6 pages, to appear at IEEE NetCod 201
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