Stabilizing Systems: Theory and Practice
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Topics:
- Self-stabilizing systems
- Practically-stabilizing systems, self-* abstractions and research that weakens classical definitions of self-stabilization for implementing fundamental services
- Stabilizing features and recovery for autonomic and adaptive computing
- Stabilization and self-* properties with relation to dependability of hardware, software and middleware
- Design, analysis and implementation methods for stabilizing algorithms and techniques in dynamic distributed systems
- Safety and Self-Stabilization in decentralized, real-time control applications
- Self-Stabilizing Autonomous Mobile Agents
- Self-stabilizing software defined infrastructure
- Self-*: Self-Managing, Self-Configuring, Self-Optimizing, Self-Healing, Self-Organizing, Self-Protecting, Self-Repairing, Self-Managed, and Self-Assembling Systems
- Chryssis Georgiou, University of Cyprus
- Elad Michael Schiller, Chalmers University of Technology
- Lélia Blin, Universite d’Evry-Val-d’Essonne, France
- Borzoo Bonakdarpour, McMaster University, Canada
- Ajoy K Datta, University of Nevada Las Vegas, USA
- Sylvie Delaet, LRI, France
- Sukumar Ghosh, University of Iowa, USA
- Mohamed Gouda, The University of Texas at Austin, USA
- Ted Herman, University of Iowa, USA
- Sayaka Kamei, Hiroshima University, Japan
- Pierre Leone, University of Geneva, Switzerland
- Toshimitsu Masuzawa, Osaka University, Japan
- Calvin Newport, Georgetown University, USA
- Taisuke Izumi, Nagoya Institute of Technology, Japan
- Maria Potop-Butucaru, UPMC Sorbonne Universités, France
- Christian Scheideler, University of Paderborn, Germany
- Stefan Schmid, Aalborg University, Denmark
- Jukka Suomela, Aalto University, Finland
- Sebastien Tixeuil, Université Paris 6, France
- Volker Turau, Hamburg University of Technology, Germany
- Koichi Wada, Hosei University, Japan
- Yamauchi Yukiko, Kyushu University, Japan
- Shmuel Zaks, Technion, Israel
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