Martin J. Strauss scite author profile

Abstract. First, we introduce the notion of divertibility as a protocol property as opposed to the existing notion as a language property (see Okamoto, Ohta [0090]). We give a definition of protocol divertibility that applies to arbitrary 2-party protocols and is compatible with Okamoto and Ohta's definition in the case of interactive zero-knowledge proofs. Other important examples falling under the new definition are blind signature protocols. We propose a sufficiency criterion for divertibility that is satisfied by many existing protocols and which, surprisingly, generalizes to cover several protocols not normally associated with divertibility (e.g., Diffie-Hellman key exchange). Next, we introduce atomic proxy cryptography, in which an atomic proxy ]unction, in conjunction with a public proxy key, converts ciphertexts (messages or signatures) for one key into ciphertexts for another. Proxy keys, once generated, may be made public and proxy functions applied in untrusted environments. We present atomic proxy functions for discrete-log-based encryption, identification, and signature schemes. It is not clear whether atomic proxy functions exist in general for all public-key cryptosystems. Finally, we discuss the relationship between divertibility and proxy cryptography.

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Combining geometry and combinatorics: A unified approach to sparse signal recovery

Berinde¹,

Gilbert

Indyk³

et al. 2008

323

433

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There are two main algorithmic approaches to sparse signal recovery: geometric and combinatorial. The geometric approach starts with a geometric constraint on the measurement matrix Φ and then uses linear programming to decode information about x from Φx. The combinatorial approach constructs Φ and a combinatorial decoding algorithm to match. We present a unified approach to these two classes of sparse signal recovery algorithms.The unifying elements are the adjacency matrices of high-quality unbalanced expanders. We generalize the notion of Restricted Isometry Property (RIP), crucial to compressed sensing results for signal recovery, from the Euclidean norm to the ℓp norm for p ≈ 1, and then show that unbalanced expanders are essentially equivalent to RIP-p matrices.From known deterministic constructions for such matrices, we obtain new deterministic measurement matrix constructions and algorithms for signal recovery which, compared to previous deterministic algorithms, are superior in either the number of measurements or in noise tolerance.

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Improved time bounds for near-optimal sparse Fourier representations

2005

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We study the problem of finding a Fourier representation R of m terms for a given discrete signal A of length N . The Fast Fourier Transform (FFT) can find the optimal N -term representation in time O(N log N ) time, but our goal is to get sublinear time algorithms when m N .Suppose A 2 ≤ M A − R opt 2 , where R opt is the optimal output. The previously best known algorithms output2 with probability at least 1 − δ in time * poly(m, log(1/δ), log N, log M, 1/ ). Although this is sublinear in the input size, the dominating expression is the polynomial factor in m which, for published algorithms, is greater than or equal to the bottleneck at m 2 that we identify below. Our experience with these algorithms shows that this is serious limitation in theory and in practice. Our algorithm beats this m 2 bottleneck.Our main result is a significantly improved algorithm for this problem and the d-dimensional analog. Our algorithm outputs an R with the same approximation guarantees but it runs in time m · poly(log(1/δ), log N, log M, 1/ ). This article replaces several earlier, unpublished drafts.

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Martin J. Strauss

Algorithms for simultaneous sparse approximation. Part I: Greedy pursuit

Divertible protocols and atomic proxy cryptography

Combining geometry and combinatorics: A unified approach to sparse signal recovery

Improved time bounds for near-optimal sparse Fourier representations

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