On the push & pull protocol for rumour spreading

The asynchronous push&pull protocol, a randomized distributed algorithm for spreading a rumour in a graph $G$, works as follows. Independent Poisson clocks of rate 1 are associated with the vertices of $G$. Initially, one vertex of $G$ knows the rumour. Whenever the clock of a vertex $x$ rings, it calls a random neighbour $y$: if $x$ knows the rumour and $y$ does not, then $x$ tells $y$ the rumour (a push operation), and if $x$ does not know the rumour and $y$ knows it, $y$ tells $x$ the rumour (a pull operation). The average spread time of $G$ is the expected time it takes for all vertices to know the rumour, and the guaranteed spread time of $G$ is the smallest time $t$ such that with probability at least $1-1/n$, after time $t$ all vertices know the rumour. The synchronous variant of this protocol, in which each clock rings precisely at times $1,2,\dots$, has been studied extensively. We prove the following results for any $n$-vertex graph: In either version, the average spread time is at most linear even if only the pull operation is used, and the guaranteed spread time is within a logarithmic factor of the average spread time, so it is $O(n\log n)$. In the asynchronous version, both the average and guaranteed spread times are $\Omega(\log n)$. We give examples of graphs illustrating that these bounds are best possible up to constant factors. We also prove theoretical relationships between the guaranteed spread times in the two versions. Firstly, in all graphs the guaranteed spread time in the asynchronous version is within an $O(\log n)$ factor of that in the synchronous version, and this is tight. Next, we find examples of graphs whose asynchronous spread times are logarithmic, but the synchronous versions are polynomially large. Finally, we show for any graph that the ratio of the synchronous spread time to the asynchronous spread time is $O(n^{2/3})$.

[1]  George Giakkoupis Tight Bounds for Rumor Spreading with Vertex Expansion , 2014, SODA.

[2]  Fan Chung Graham,et al.  The Average Distance in a Random Graph with Given Expected Degrees , 2004, Internet Math..

[3]  B. Pittel On spreading a rumor , 1987 .

[4]  George Giakkoupis,et al.  Tight bounds for rumor spreading in graphs of a given conductance , 2011, STACS.

[5]  Amin Saberi,et al.  On the spread of viruses on the internet , 2005, SODA '05.

[6]  G. Grimmett,et al.  Probability and random processes , 2002 .

[7]  Richard M. Karp,et al.  Randomized rumor spreading , 2000, Proceedings 41st Annual Symposium on Foundations of Computer Science.

[8]  Arthur L. Liestman,et al.  A survey of gossiping and broadcasting in communication networks , 1988, Networks.

[9]  C. D. Howard,et al.  Models of First-Passage Percolation , 2004 .

[10]  Marc Lelarge,et al.  Flooding in Weighted Sparse Random Graphs , 2013, SIAM J. Discret. Math..

[11]  Yoshiharu Kohayakawa,et al.  On Richardsons model on the hypercube , 1997 .

[12]  Mor Harchol-Balter,et al.  Resource discovery in distributed networks , 1999, PODC '99.

[13]  Konstantinos Panagiotou,et al.  Asynchronous Rumor Spreading on Random Graphs , 2013, ISAAC.

[14]  Stephen P. Boyd,et al.  Randomized gossip algorithms , 2006, IEEE Transactions on Information Theory.

[15]  Thomas Sauerwald,et al.  Cover Time and Broadcast Time , 2009, STACS.

[16]  Konstantinos Panagiotou,et al.  Rumor spreading on random regular graphs and expanders , 2010, Random Struct. Algorithms.

[17]  Silvio Lattanzi,et al.  Rumor spreading in social networks , 2009, Theor. Comput. Sci..

[18]  Thomas Sauerwald,et al.  Diameter and Broadcast Time of Random Geometric Graphs in Arbitrary Dimensions , 2012, Algorithmica.

[19]  Mahmoud Fouz,et al.  Experimental Analysis of Rumor Spreading in Social Networks , 2012, MedAlg.

[20]  James Allen Fill,et al.  PERCOLATION, FIRST-PASSAGE PERCOLATION, AND COVERING TIMES FOR RICHARDSON'S MODEL ON THE n-CUBE (Short title: PERCOLATION ON THE CUBE) , 1993 .

[21]  Mahmoud Fouz,et al.  Social Networks Spread Rumors in Sublogarithmic Time , 2011, Electron. Notes Discret. Math..

[22]  Thomas Sauerwald,et al.  On the runtime and robustness of randomized broadcasting , 2009, Theor. Comput. Sci..

[23]  Mahmoud Fouz,et al.  Asynchronous Rumor Spreading in Preferential Attachment Graphs , 2012, SWAT.

[24]  Scott Shenker,et al.  Epidemic algorithms for replicated database maintenance , 1988, OPSR.

[25]  Albert,et al.  Emergence of scaling in random networks , 1999, Science.

[26]  Thomas Sauerwald,et al.  On Mixing and Edge Expansion Properties in Randomized Broadcasting , 2007, Algorithmica.

[27]  Béla Bollobás,et al.  Combinatorics, geometry, and probability : a tribute to Paul Erdős , 1997 .

[28]  Thomas Sauerwald,et al.  Ultra-fast rumor spreading in social networks , 2012, SODA.

[29]  Johannes Gehrke,et al.  Gossip-based computation of aggregate information , 2003, 44th Annual IEEE Symposium on Foundations of Computer Science, 2003. Proceedings..

[30]  Rick Durrett,et al.  STOCHASTIC GROWTH MODELS: RECENT RESULTS AND OPEN PROBLEMS , 1989 .

[31]  Mahmoud Fouz,et al.  Why rumors spread so quickly in social networks , 2012, Commun. ACM.

[32]  Eli Upfal,et al.  Randomized Broadcast in Networks , 1990, Random Struct. Algorithms.

[33]  Svante Janson,et al.  One, Two and Three Times log n/n for Paths in a Complete Graph with Random Weights , 1999, Combinatorics, Probability and Computing.