Workload-Aware Data Partitioning in Community-Driven Data Grids
Authors
- Tobias Scholl (Technische Universität München, Germany)
- Bernhard K. Bauer (Technische Universität München, Germany)
- Jessica Müller (Technische Universität München, Germany)
- Benjamin Gufler (Technische Universität München, Germany)
- Angelika Reiser (Technische Universität München, Germany)
- Alfons Kemper (Technische Universität München, Germany)
Abstract
Collaborative research in various scientific disciplines requires support for scalable data management enabling the efficient correlation of globally distributed data sources. Motivated by the expected data rates of upcoming projects and a growing number of users, communities explore new data management techniques for achieving high throughput. Community-driven data grids deliver such high-throughput data distribution for scientific federations by partitioning data according to application-specific data and query characteristics. Query hot spots are an important and challenging problem in this environment. Existing approaches to load-balancing from Peer-to-Peer (P2P) data management and sensor networks do not directly meet the requirements of a data-intensive e-science environment. In this paper, our contributions are partitioning schemes based on multi-dimensional index structures enabling communities to trade off data load balancing and handling query hot spots via splitting and replication. We evaluate the partitioning schemes with two typical kinds of data sets from the astrophysics domain and workloads extracted from Sloan Digital Sky Survey (SDSS) query traces and perform throughput measurements in real and simulated networks. The experiments demonstrate the improved workload distribution capabilities and give promising directions for the development of future community grids.
Session
EDBT Research Session 1: System Architectures (Tuesday, March 24, 11:00—12:30)