Generalised Bagemihl polyhedra and a tight bound on the number of interior Steiner points

We present a parallel Delaunay refinement algorithm for generating well-shaped meshes in both two and three dimensions. Like its sequential counterparts, the parallel algorithm iteratively improves the quality of a mesh by inserting new points, the Steiner points, into the input domain while maintaining the Delaunay triangulation. The Steiner points are carefully chosen from a set of candidates that includes the circumcenters of poorly-shaped triangular elements. We introduce a notion of independence among possible Steiner points that can be inserted simultaneously during Delaunay refinements and show that such a set of independent points can be constructed efficiently and that the number of parallel iterations is O( log 2Δ), where Δ is the spread of the input — the ratio of the longest to the shortest pairwise distances among input features. In addition, we show that the parallel insertion of these set of points can be realized by sequential Delaunay refinement algorithms such as by Ruppert's algorithm in two dimensions and Shewchuk's algorithm in three dimensions. Therefore, our parallel Delaunay refinement algorithm provides the same shape quality and mesh-size guarantees as these sequential algorithms. For generating quasi-uniform meshes, such as those produced by Chew's algorithms, the number of parallel iterations is in fact O( log Δ). To the best of our knowledge, our algorithm is the first provably polylog(Δ) time parallel Delaunay-refinement algorithm that generates well-shaped meshes of size within a constant factor of the best possible.

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A tight bound for frameproof codes viewed in terms of separating hash families

Designs Codes and Cryptography ◽

10.1007/s10623-013-9800-0 ◽

2013 ◽

Vol 72 (3) ◽

pp. 713-718 ◽

Cited By ~ 6

Author(s):

Tran van Trung

Keyword(s):

Tight Bound ◽

Frameproof Codes

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Tight Bound for the Number of Distinct Palindromes in a Tree

String Processing and Information Retrieval - Lecture Notes in Computer Science ◽

10.1007/978-3-319-23826-5_26 ◽

2015 ◽

pp. 270-276 ◽

Cited By ~ 2

Author(s):

Paweł Gawrychowski ◽

Tomasz Kociumaka ◽

Wojciech Rytter ◽

Tomasz Waleń

Keyword(s):

Tight Bound

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On Length Independent Security Bounds for the PMAC Family

IACR Transactions on Symmetric Cryptology ◽

10.46586/tosc.v2021.i2.423-445 ◽

2021 ◽

pp. 423-445

Author(s):

Bishwajit Chakraborty ◽

Soumya Chattopadhyay ◽

Ashwin Jha ◽

Mridul Nandi

Keyword(s):

Block Cipher ◽

Block Size ◽

Gray Code ◽

Tight Bound ◽

Simple Modification ◽

Security Proof ◽

Tight Security ◽

Pseudorandom Function ◽

Exact Security ◽

Query Length

At FSE 2017, Gaži et al. demonstrated a pseudorandom function (PRF) distinguisher (Gaži et al., ToSC 2016(2)) on PMAC with Ω(lq2/2n) advantage, where q, l, and n, denote the number of queries, maximum permissible query length (in terms of n-bit blocks), and block size of the underlying block cipher. This, in combination with the upper bounds of Ο(lq2/2n) (Minematsu and Matsushima, FSE 2007) and Ο(qσ/2n) (Nandi and Mandal, J. Mathematical Cryptology 2008(2)), resolved the long-standing problem of exact security of PMAC. Gaži et al. also showed that the dependency on l can be dropped (i.e. O(q2/2n) bound up to l ≤ 2n/2) for a simplified version of PMAC, called sPMAC, by replacing the Gray code-based masking in PMAC with any 4-wise independent universal hash-based masking. Recently, Naito proposed another variant of PMAC with two powering-up maskings (Naito, ToSC 2019(2)) that achieves l-free bound of O(q2/2n), provided l ≤ 2n/2. In this work, we first identify a flaw in the analysis of Naito’s PMAC variant that invalidates the security proof. Apparently, the flaw is not easy to fix under the existing proof setup. We then formulate an equivalent problem which must be solved in order to achieve l-free security bounds for this variant. Second, we show that sPMAC achieves O(q2/2n) bound for a weaker notion of universality as compared to the earlier condition of 4-wise independence. Third, we analyze the security of PMAC1 (a popular variant of PMAC) with a simple modification in the linear combination of block cipher outputs. We show that this simple modification of PMAC1 has tight security O(q2/2n) provided l ≤ 2n/4. Even if l < 2n/4, we still achieve same tight bound as long as total number of blocks in all queries is less than 22n/3.

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Algorithms for the power-p Steiner tree problem in the Euclidean plane

Revista de Informática Teórica e Aplicada ◽

10.22456/2175-2745.80525 ◽

2018 ◽

Vol 25 (4) ◽

pp. 28

Author(s):

Christina Burt ◽

Alysson Costa ◽

Charl Ras

Keyword(s):

Spanning Tree ◽

Minimum Spanning Tree ◽

Valid Inequalities ◽

Minimum Cost ◽

Performance Ratio ◽

Mixed Integer ◽

Steiner Tree Problem ◽

Steiner Points ◽

Tree Construction ◽

The Cost

We study the problem of constructing minimum power-$p$ Euclidean $k$-Steiner trees in the plane. The problem is to find a tree of minimum cost spanning a set of given terminals where, as opposed to the minimum spanning tree problem, at most $k$ additional nodes (Steiner points) may be introduced anywhere in the plane. The cost of an edge is its length to the power of $p$ (where $p\geq 1$), and the cost of a network is the sum of all edge costs. We propose two heuristics: a ``beaded" minimum spanning tree heuristic; and a heuristic which alternates between minimum spanning tree construction and a local fixed topology minimisation procedure for locating the Steiner points. We show that the performance ratio $\kappa$ of the beaded-MST heuristic satisfies $\sqrt{3}^{p-1}(1+2^{1-p})\leq \kappa\leq 3(2^{p-1})$. We then provide two mixed-integer nonlinear programming formulations for the problem, and extend several important geometric properties into valid inequalities. Finally, we combine the valid inequalities with warm-starting and preprocessing to obtain computational improvements for the $p=2$ case.

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