Analysis of retrieval performance for records and objects using optical disk technology
ACM Transactions on Database Systems (TODS)
Performance analysis and fundamental performance tradeoffs for CLV optical disks
SIGMOD '88 Proceedings of the 1988 ACM SIGMOD international conference on Management of data
Efficient placement of audio data on optical disks for real-time applications
Communications of the ACM
Multimedia: computing, communications and applications
Multimedia: computing, communications and applications
Stochastic service guarantees for continuous data on multi-zone disks
PODS '97 Proceedings of the sixteenth ACM SIGACT-SIGMOD-SIGART symposium on Principles of database systems
Algorithmic Studies in Mass Storage Systems
Algorithmic Studies in Mass Storage Systems
A Comprehensive Analytical Performance Model for Disk Devices under Random Workloads
IEEE Transactions on Knowledge and Data Engineering
Principles of Optimally Placing Data in Tertiary Storage Libraries
VLDB '97 Proceedings of the 23rd International Conference on Very Large Data Bases
Dynamic data reallocation in disk arrays
ACM Transactions on Storage (TOS)
Analysis of set-up time models: A metric perspective
Theoretical Computer Science
A file assignment strategy independent of workload characteristic assumptions
ACM Transactions on Storage (TOS)
HiPC'07 Proceedings of the 14th international conference on High performance computing
| Hi-index | 0.00 |
The problem of optimally placing data on disks (ODP) to maximize disk-access performance has long been recognized as important. Solutions to this problem have been reported for some widely available disk technologies, such as magnetic CAV and optical CLV disks. However, important new technologies such as multizoned magnetic disks, have been recently introduced. For such technologies no formal solution to the ODP problem has been reported. In this paper, we first identify the fundamental characteristics of disk-device technologies which influence the solution to the ODP problem. We develop a comprehensive solution to the problem that covers all currently available disk technologies. We show how our comprehensive solution can be reduced to the solutions for existing disk technologies, contributing thus a solution to the ODP problem for multizoned disks. Our analytical solution has been validated through simulations and through its reduction to the known solutions for particular disks. Finally, we study how the solution for multizoned disks is affected by the disk and data characteristics.