Using Multi-level Graphs for Timetable Information in Railway Systems

Schulz, Frank; Wagner, Dorothea; Zaroliagis, Christos

doi:10.1007/3-540-45643-0_4

Cited by 101 publications

(119 citation statements)

References 18 publications

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“…The same holds for the dynamic variant of Arc-Flags proposed in [1], where, after a number of updates, the query performances get worse yielding only a low speed-up over Dijkstra's algorithm. In [15], ideas from highway hierarchies [14] and overlay graphs [16] are combined yielding very good query times in dynamic road networks. In [2], a theoretical approach to correctly update overlay graphs has been proposed, but the proposed algorithms have not been shown to have good practical performances in real-world networks.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Arc-Flags in Road Networks

D’Angelo

Frigioni

Vitale

2011

Experimental Algorithms

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Abstract. In this work we introduce a new data structure, named RoadSigns, which allows us to efficiently update the Arc-Flags of a graph in a dynamic scenario. Road-Signs can be used to compute Arc-Flags, can be efficiently updated and do not require large space consumption for many real-world graphs like, e.g., graphs arising from road networks. In detail, we define an algorithm to preprocess Road-Signs and an algorithm to update them each time that a weight increase operation occurs on an edge of the network. We also experimentally analyze the proposed algorithms in real-world road networks showing that they yields a significant speedup in the updating phase of Arc-Flags, at the cost of a very small space and time overhead in the preprocessing phase.

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Section: Introductionmentioning

confidence: 99%

Dynamic Arc-Flags in Road Networks

D’Angelo

Frigioni

Vitale

2011

Experimental Algorithms

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“…Routing can now be restricted to G 1 and the components containing s and t respectively. This process can be iterated yielding a multi-level method [69,35,36,34]. A limitation of this approach is that the graphs at higher levels become much more dense than the input graphs thus limiting the benefits gained from the hierarchy.…”

Section: Exploiting Hierarchymentioning

confidence: 99%

“…In [65] the multi-level routing scheme with overlay graphs [67,69,35,36] is generalized so that it works with arbitrary sets of nodes rather than only with separators. This is achieved using a new query algorithm that stalls suboptimal branches of search on lower levels of the hierarchy.…”

Section: Highway-node Routing (Hnr)mentioning

confidence: 99%

Engineering Route Planning Algorithms

Delling

Sanders

Schultes

et al. 2009

Lecture Notes in Computer Science

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370

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Abstract. Algorithms for route planning in transportation networks have recently undergone a rapid development, leading to methods that are up to three million times faster than Dijkstra's algorithm. We give an overview of the techniques enabling this development and point out frontiers of ongoing research on more challenging variants of the problem that include dynamically changing networks, time-dependent routing, and flexible objective functions.

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“…During the last years, speed-up techniques have been developed for road networks (see [14,18] for an overview), that make the shortest path computation a matter of microseconds [4] even on huge road networks consisting of millions of nodes and edges. One core part of many of these speed-up techniques is the insertion of shortcuts [3,5,7,8,9,11,13,15,16,17], i.e. additional edges (u, v) whose length is the distance from u to v and that represent shortest u-v-paths in the graph.…”

Section: Introductionmentioning

confidence: 99%

“…Speed-up techniques that incorporate the usage of shortcuts are the following. Given a graph G = (V, E) the multi-level overlay graph technique [5,11,15,16,17] uses some centrality measures or separation strategies to choose a set of important nodes V on the graph and sets the shortcuts S such that the graph (V , S) is edge minimal among all graphs (V , E ) for which the distances between nodes in V are the same in (V, E) and (V , E ). Highway hierarchies [13] and reach based pruning [8,9] iteratively sparsificate the graph according to the importance of the nodes.…”

Section: Introductionmentioning

confidence: 99%

The Shortcut Problem – Complexity and Approximation

Bauer

D’Angelo

Delling

et al. 2009

Lecture Notes in Computer Science

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Abstract. During the last years, speed-up techniques for DIJKSTRA's algorithm have been developed that make the computation of shortest paths a matter of microseconds even on huge road networks. The most sophisticated methods enhance the graph by inserting shortcuts, i.e. additional edges, that represent shortest paths in the graph. Until now, all existing shortcut-insertion strategies are heuristics and no theoretical results on the topic are known. In this work, we formalize the problem of adding shortcuts as a graph augmentation problem, study the algorithmic complexity of the problem, give approximation algorithms and show how to stochastically evaluate a given shortcut assignment on graphs that are too big to evaluate it exactly.

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Using Multi-level Graphs for Timetable Information in Railway Systems

Cited by 101 publications

References 18 publications

Dynamic Arc-Flags in Road Networks

Dynamic Arc-Flags in Road Networks

Engineering Route Planning Algorithms

The Shortcut Problem – Complexity and Approximation

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