Subcubic Equivalences Between Graph Centrality Problems, APSP and Diameter

Abboud, Amir; Grandoni, Fabrizio; Williams, Virginia Vassilevska

doi:10.1137/1.9781611973730.112

Cited by 94 publications

(317 citation statements)

References 51 publications

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“…Then, we can show that there are only O (log n) squares in total that can potentially be large. This reduces the guessing time to (log n) O (1) = O (1) · n O (1) . More generally, with our approach we can obtain such an improved bound in any setting with only few (profit) classes of input squares where for each class there are only few relevant squares if we know that the class contributes only a small number of squares to a (near-)optimal solution.…”

Section: Our Techniquesmentioning

confidence: 99%

“…Theorem 1.2. There is an algorithm for the twodimensional knapsack problem for rectangles under (1 + )-resource augmentation with and without rotation with running time O (1) · n O (1) . This algorithm computes a solution with profit at least the profit of the optimal solution (that does not use resource augmentation).…”

Section: Our Techniquesmentioning

confidence: 99%

“…In Section 3 we present a technique that allows us to guess the large squares in time O (1) · n O (1) . Then in Section 4 we present an EPTAS for the special case that N N , i.e., the knapsack is a rectangle with very large aspect ratio.…”

Section: Other Related Workmentioning

confidence: 99%

“…For each input rectangle i denote by h i ∈ N its height and by w i ∈ N its width. We reduce the running time of the known PTAS [9] of Ω n 1/ 1/ to O (1) · n O (1) and compute even a solution whose profit is at least p(OP T ), instead of a (1 + )-approximative solution. We investigate first the case without the possibility to rotate the rectangles.…”

Section: Computing the Packingmentioning

confidence: 99%

“…This raises the question whether this highly impractical running time is necessary or whether better running times are possible of e.g., n O(1/ ) or even O (1) · n O(1) (where O (1) denotes a value that is constant for constant ). Recently, there has been a lot of research on determining the best possible running times for specific problems, see e.g., [6,1] and references therein. For some problems, we know even the best possible exponent of n under standard complexity assumptions.…”

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confidence: 99%

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Faster approximation schemes for the two-dimensional knapsack problem

Heydrich¹,

Wiese²

2017

Proceedings of the Twenty-Eighth Annual ACM-SIAM Symposium on Discrete Algorithms

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An important question in theoretical computer science is to determine the best possible running time for solving a problem at hand. For geometric optimization problems, we often understand their complexity on a rough scale, but not very well on a finer scale. One such example is the two-dimensional knapsack problem for squares. There is a polynomial time (1 + )-approximation algorithm for it (i.e., a PTAS) but the running time of this algorithm is triple exponential in 1/ , i.e., Ω(n 2 2 1/ ). A double or triple exponential dependence on 1/ is inherent in how this and several other algorithms for other geometric problems work. In this paper, we present an EPTAS for knapsack for squares, i.e., a (1+ )-approximation algorithm with a running time of O (1) · n O(1) . In particular, the exponent of n in the running time does not depend on at all! Since there can be no FPTAS for the problem (unless P = NP) this is the best kind of approximation scheme we can hope for. To achieve this improvement, we introduce two new key ideas: We present a fast method to guess the Ω(2 2 1/ ) relatively large squares of a suitable near-optimal packing instead of using brute-force enumeration. Secondly, we introduce an indirect guessing framework to define sizes of cells for the remaining squares. In the previous PTAS each of these steps needs a running time of Ω(n 2 2 1/ ) and we improve both to O (1) · n O(1) . We complete our result by giving an algorithm for twodimensional knapsack for rectangles under (1 + )-resource augmentation. In this setting, we also improve the best known running time of Ω(n 1/ 1/ ) to O (1) · n O(1) and compute even a solution with optimal profit, in contrast to the best previously known polynomial time algorithm for this setting that computes only an approximation. We believe that our new techniques have the potential to be useful for other settings as well.

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Section: Our Techniquesmentioning

confidence: 99%

Section: Our Techniquesmentioning

confidence: 99%

Section: Other Related Workmentioning

confidence: 99%

Section: Computing the Packingmentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Faster approximation schemes for the two-dimensional knapsack problem

Heydrich¹,

Wiese²

2017

Proceedings of the Twenty-Eighth Annual ACM-SIAM Symposium on Discrete Algorithms

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Fast Approximation of Centrality and Distances in Hyperbolic Graphs

Chepoi¹,

Dragan²,

Habib³

et al. 2018

Combinatorial Optimization and Applications

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We show that the eccentricities (and thus the centrality indices) of all vertices of a δhyperbolic graph G = (V, E) can be computed in linear time with an additive one-sided error of at most cδ, i.e., after a linear time preprocessing, for every vertex v of G one can compute in O(1) time an estimateê(v) of its eccentricity eccG(v) such that eccG(v) ≤ê(v) ≤ eccG(v) + cδ for a small constant c. We prove that every δ-hyperbolic graph G has a shortest path tree, constructible in linear time, such that for every vertexThese results are based on an interesting monotonicity property of the eccentricity function of hyperbolic graphs: the closer a vertex is to the center of G, the smaller its eccentricity is. We also show that the distance matrix of G with an additive one-sided error of at most c ′ δ can be computed in O(|V | 2 log 2 |V |) time, where c ′ < c is a small constant. Recent empirical studies show that many real-world graphs (including Internet application networks, web networks, collaboration networks, social networks, biological networks, and others) have small hyperbolicity. So, we analyze the performance of our algorithms for approximating centrality and distance matrix on a number of real-world networks. Our experimental results show that the obtained estimates are even better than the theoretical bounds.

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