Author_Institution :
Dept. of Comput. Sci., New Jersey Inst. of Technol., Newark, NJ
Abstract :
Disk mirroring or RAID level 1 (RAID1) is a popular paradigm to achieve fault tolerance and a higher disk access bandwidth for read requests. We consider four RAID1 organizations: basic mirroring, group rotate declustering, interleaved declustering, and chained declustering, where the last three organizations attain a more balanced load than basic mirroring when disk failures occur. We first obtain the number of configurations, A(n, i), which do not result in data loss when i out of n disks have failed. The probability of no data loss in this case is A(n, i)/matrix of(n, i). The reliability of each RAID1 organization is the summation over 1 les i les n/2 of A(n, i)rn-i (1 - r) i, where r denotes the reliability of each disk. A closed-form expression for A(n, i) is obtained easily for the first three organizations. We present a relatively simple derivation of the expression for A(n, i) for the chained declustering method, which includes a correctness proof. We also discuss the routing of read requests to balance disk loads, especially when there are disk failures, to maximize the attainable throughput
Keywords :
RAID; fault tolerant computing; file organisation; probability; resource allocation; RAID1 organization; chained declustering method; closed-form expression; data loss probability; disk access bandwidth; disk failure; disk load balancing; disk mirroring; disk organization reliability analysis; fault tolerance; group rotate declustering; interleaved declustering; Bandwidth; Closed-form solution; Costs; Disk recording; Fault tolerance; Protection; Redundancy; Reed-Solomon codes; Routing; Throughput; Disk mirroring; RAID level 1; chained declustering; group rotate declustering.; interleaved declustering; reliability modeling;
