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Michael Langberg: Open University of Israel

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1 Brief Announcement: Distributed Broadcasting and Mapping Protocols in Directed Anonymous Networks
Michael Langberg: Open University of Israel Moshe Schwartz: Ben Gurion University of the Negev Jehoshua Bruck: California Institute of Technology Presenting: Michael Elkin, Ben Gurion University of the Negev

2 Anonymous Networks General framework: Processors: Objectives:
Do not have unique identifiers. Execute identical protocols. No knowledge of topology of network. May distinguish between incoming edges. Objectives: Broadcast. Label assignment. Graph exploration. Previously studied: Undirected graphs (or directed + strongly connected). Protocols based on message passing.

3 This talk Directed anonymous graphs.
Not necessarily strongly connected. Has not been considered previously. Standard (message passing) protocols studied do not apply: Graph may not be strongly connected. Processors may have single chance to send message. Outline of talk: Model. Results.

4 Model Motivation: s Two special vertices: s
Consider dynamically growing network of unknown topology. Access to network through s and t. Our model enables to perform maintenance tasks. Maintenance is triggered by s and status report obtained via t. Otherwise cannot distinguish between: s Two special vertices: Root s. Terminal t. Protocol proceeds as follows: Initial message sent from s to children. Triggers a distributed protocol. Protocol terminates when terminal vertex t is in final state – with its state as the output of protocol. Connectivity: Protocol will terminate iff all nodes lay on a path between s and t. Nodes only reachable from s or nodes that are only connected to t will not allow termination. t s Not connected t

5 Results Broadcast: send a message m to entire network.
Trivial without termination requirement at t. Theorem: Broadcast + termination achievable with total communication O(|E|2|V|log(dout)) + |E||m|. Proof idea for termination: Messages sent will represent a certain commodity. Send unit of commodity out of s (split between children). Internal vertex: upon receiving commodity – process commodity and split among children. t terminates when over time it receives a unit of commodity. Proof is non trivial even for acyclic graphs: must split commodity carefully – otherwise exponential communication complexity. Improved complexity bounds which are “tight” for DAGs. Proof more involved for graphs with cycles.

6 Results II Unique label assignment:
Theorem: Unique label assignment + termination achievable with total communication complexity of O(|E|2|V|log(dout)). Labels are of length O(|V|log(dout)). Proof idea: Follows commodity based protocol for broadcast. Part of the commodity is reserved for unique id. Large label length is essential (matching lower bound).

7 Summary Initiate study of anonymous directed networks which are not strongly connected. Present protocols for broadcast and label assignment + termination. Open questions: Close gap in communication complexity (not tight for digraphs with and without cycles). Our algorithms based on commodity preserving paradigm. Does paradigm yield optimal complexity on DAGs?

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