Proceedings of the Twenty-Eighth Annual ACM-SIAM Symposium on Discrete Algorithms 2017
DOI: 10.1137/1.9781611974782.29
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Deterministic Partially Dynamic Single Source Shortest Paths for Sparse Graphs

Abstract: In this paper we consider the decremental single-source shortest paths (SSSP) problem, where given a graph G and a source node s the goal is to maintain shortest paths between s and all other nodes in G under a sequence of online adversarial edge deletions. (Our algorithm can also be modified to work in the incremental setting, where the graph is initially empty and subject to a sequence of online adversarial edge insertions.)In their seminal work, Even and Shiloach [JACM 1981] presented an exact solution to t… Show more

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Cited by 23 publications
(66 citation statements)
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“…We wish to bound this probability Pr[E τ ], which is evaluated over the past random choices of the algorithm which the adversary fixing the order of edge insertions is oblivious to. 6 We do this by using the principle of deferred decision.…”
Section: [T R ] ≤ O(t ) + O(t Hp )mentioning
confidence: 99%
See 1 more Smart Citation
“…We wish to bound this probability Pr[E τ ], which is evaluated over the past random choices of the algorithm which the adversary fixing the order of edge insertions is oblivious to. 6 We do this by using the principle of deferred decision.…”
Section: [T R ] ≤ O(t ) + O(t Hp )mentioning
confidence: 99%
“…We believe that this is an important question, since it may help in understanding how to develop deterministic dynamic algorithms in general. It is very challenging and interesting to design deterministic dynamic algorithms with performances similar to the randomized ones for many dynamic graph problems such as maximal matching [5,10,9,11,12,13], connectivity [24,28,32,27], and shortest paths [6,8,7,21,22].…”
Section: Open Problemsmentioning
confidence: 99%
“…This, improves the algorithms by Bernstein and Chechik [BC16, BC17, Ber17] over the entire sparsity m = O(n 1.5−o(1) ) and dominates it heavily for the important case when m = O(n) where our algorithm improves the current running time ofÕ(n 1+3/4 ) to just O(n 1.5+o(1) ) total update time. This matches a natural barrier to the problem encountered by all current approaches as pointed out by Bernstein and Chechik [BC17]. We present the algorithm for the more challenging decremental setting but point out that an adaption to the incremental setting is straight-forward.…”
Section: Our Contributionsmentioning
confidence: 61%
“…To overcome this problem, Bernstein and Chechik [Che + 16] presented the first deterministic algorithm running inÕ(n 2 ) total time. They also presented an algorithm for sparse graphs [BC17] with update timeÕ(n 1.25 √ m) =Õ(mn 3/4 ). Bernstein [Ber17] later extended the algorithm for dense graphs to handle edge weights in [1, W ] with total update timeÕ(n 2 log W ).…”
Section: Related Workmentioning
confidence: 99%
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