Contribution. We study the fundamental naming and counting problems in networks that are anonymous, unknown, and possibly dynamic. Network dynamicity is modeled by the 1-interval connectivity model [KLO10]. We first prove that on static networks with broadcast counting is impossible to solve without a leader and that naming is impossible to solve even with a leader and even if nodes know n. These impossibilities carry over to dynamic networks as well. With a leader we solve counting in linear time. Then we focus on dynamic networks with broadcast. We show that if nodes know an upper bound on the maximum degree that will ever appear then they can obtain an upper bound on n. Finally, we replace broadcast with one-to-each, in which a node may send a different message to each of its neighbors. This variation is then proved to be computationally equivalent to a full-knowledge model with unique names.
Brief announcement: Naming and counting in anonymous unknown dynamic networks / Michail, Othon; Chatzigiannakis, Ioannis; Spirakis, Paul G.. - STAMPA. - 7611:(2012), pp. 437-438. (Intervento presentato al convegno 26th International Symposium on Distributed Computing, DISC 2012 tenutosi a Salvador; Brazil nel 16-18 October 2012) [10.1007/978-3-642-33651-5_46].
Brief announcement: Naming and counting in anonymous unknown dynamic networks
CHATZIGIANNAKIS, Ioannis;
2012
Abstract
Contribution. We study the fundamental naming and counting problems in networks that are anonymous, unknown, and possibly dynamic. Network dynamicity is modeled by the 1-interval connectivity model [KLO10]. We first prove that on static networks with broadcast counting is impossible to solve without a leader and that naming is impossible to solve even with a leader and even if nodes know n. These impossibilities carry over to dynamic networks as well. With a leader we solve counting in linear time. Then we focus on dynamic networks with broadcast. We show that if nodes know an upper bound on the maximum degree that will ever appear then they can obtain an upper bound on n. Finally, we replace broadcast with one-to-each, in which a node may send a different message to each of its neighbors. This variation is then proved to be computationally equivalent to a full-knowledge model with unique names.| File | Dimensione | Formato | |
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