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Strong Robustness of Randomized Rumor Spreading Protocols

Discrete Mathematics 2013-05-21 v4

Abstract

Randomized rumor spreading is a classical protocol to disseminate information across a network. At SODA 2008, a quasirandom version of this protocol was proposed and competitive bounds for its run-time were proven. This prompts the question: to what extent does the quasirandom protocol inherit the second principal advantage of randomized rumor spreading, namely robustness against transmission failures? In this paper, we present a result precise up to (1±o(1))(1 \pm o(1)) factors. We limit ourselves to the network in which every two vertices are connected by a direct link. Run-times accurate to their leading constants are unknown for all other non-trivial networks. We show that if each transmission reaches its destination with a probability of p(0,1]p \in (0,1], after (1+\e)(1log2(1+p)log2n+1plnn)(1+\e)(\frac{1}{\log_2(1+p)}\log_2n+\frac{1}{p}\ln n) rounds the quasirandom protocol has informed all nn nodes in the network with probability at least 1np\e/401-n^{-p\e/40}. Note that this is faster than the intuitively natural 1/p1/p factor increase over the run-time of approximately log2n+lnn\log_2 n + \ln n for the non-corrupted case. We also provide a corresponding lower bound for the classical model. This demonstrates that the quasirandom model is at least as robust as the fully random model despite the greatly reduced degree of independent randomness.

Keywords

Cite

@article{arxiv.1001.3056,
  title  = {Strong Robustness of Randomized Rumor Spreading Protocols},
  author = {Benjamin Doerr and Anna Huber and Ariel Levavi},
  journal= {arXiv preprint arXiv:1001.3056},
  year   = {2013}
}

Comments

Accepted for publication in "Discrete Applied Mathematics". A short version appeared in the proceedings of the 20th International Symposium on Algorithms and Computation (ISAAC 2009). Minor typos fixed in the second version. Proofs of Lemma 11 and Theorem 12 fixed in the third version. Proof of Lemma 8 fixed in the fourth version

R2 v1 2026-06-21T14:36:06.055Z