Title :
Optimal resiliency against mobile faults
Author :
Buhrman, H. ; Garay, J.A. ; Hoepman, J.-H.
Author_Institution :
CWI, Amsterdam, Netherlands
Abstract :
We consider a model where malicious agents can corrupt hosts and move around in a network of processors. We consider a family of mobile fault models MF(t/n-1,/spl rho/). In MF(t/n-1,/spl rho/) there are a total of n processors, the maximum number of mobile faults is t, and their roaming pace is /spl rho/ (for example, /spl rho/=3 means that it takes an agent at least 3 rounds to "hop" to the next host). We study in these models the classical testbed problem for fault tolerant distributed computing: Byzantine agreement. It has been shown that if /spl rho/=1, then agreement cannot be reached in the presence of even one fault, unless one of the processors remains uncorrupted for a certain amount of time. Subject to this proviso, we present a protocol for MF(/sup 1///sub 3/,1), which is optimal. The running time of the protocol is O(n) rounds, also optimal for these models.<>
Keywords :
computer network reliability; fault tolerant computing; protocols; reliability; Byzantine agreement; classical testbed problem; fault tolerant distributed computing; malicious agents; mobile fault models; mobile faults; optimal resiliency; protocol; roaming pace; running time; Computer networks; Computer viruses; Cryptographic protocols; Cryptography; Distributed computing; Fault tolerance; Noise measurement; Open systems; Testing; Viruses (medical);
Conference_Titel :
Fault-Tolerant Computing, 1995. FTCS-25. Digest of Papers., Twenty-Fifth International Symposium on
Conference_Location :
Pasadena, CA, USA
Print_ISBN :
0-8186-7079-7
DOI :
10.1109/FTCS.1995.466995
