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Distributed Systems

Almost every computing system nowadays is distributed, ranging from multi-core laptops to Internet-scale services; understanding the principles of distributed computing is hence important for the design and engineering of modern computing systems.  Fundamental issues that arise in reliable and efficient distributed systems include developing adequate methods for modeling failures and synchrony assumptions, determining precise performance bounds on implementations of concurrent data structures, capturing the trade-off between consistency and efficiency, and demarcating the frontier of feasibility in distributed computing.

For example, popular Internet services and applications such as CNN.com, YouTube, Facebook, Skype, BitTorrent attract millions of users every day, and only by the effective load-balancing and collaboration of many thousand machines, an acceptable Quality-of-Service/Quality-of-Experience can be guaranteed. While distributed systems promise a good scalability as well as a high robustness, they pose challenging research problems, such as: How to design robust and scalable distributed architectures and services? How to coordinate access to a shared resource, e.g., by electing a leader? Or how to provide incentives for cooperation in an open, collaborative distributed system?

Selected Publications

Time Complexity of Distributed Topological Self-Stabilization: The Case of Graph Linearization
Zitatschlüssel GJRSST-TCDTSSCGL-10
Autor Gall, Dominik and Jacob, Riko and Richa, Andréa and Scheideler, Christian and Schmid, Stefan and Täubig, Hanjo
Buchtitel Proceedings of 9th Latin American Theoretical Informatics Symposium (LATIN '10)
Seiten 294–305
Jahr 2010
ISBN 978-3-642-12199-9
ISSN 0302-9743
DOI http://dx.doi.org/10.1007/978-3-642-12200-2_27
Ort Oaxaca, Mexico
Adresse Berlin / Heidelberg, Germany
Jahrgang 6034
Monat April
Verlag Springer
Serie Lecture Notes in Computer Science (LNCS)
Zusammenfassung Topological self-stabilization is an important concept to build robust open distributed systems (such as peer-to-peer systems) where nodes can organize themselves into meaningful network topologies. The goal is to devise distributed algorithms that converge quickly to such a desirable topology, independently of the initial network state. This paper proposes a new model to study the parallel convergence time. Our model sheds light on the achievable parallelism by avoiding bottlenecks of existing models that can yield a distorted picture. As a case study, we consider local graph linearization–i.e., how to build a sorted list of the nodes of a connected graph in a distributed and self-stabilizing manner. We propose two variants of a simple algorithm, and provide an extensive formal analysis of their worst-case and best-case parallel time complexities, as well as their performance under a greedy selection of the actions to be executed.
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