1 A Concise Introduction to Autonomic Computing Roy Sterritt, University of Ulster at Jordanstown, Northern Ireland, UK Manish Parashar, Rutgers University, New Jersey, USA Huaglory Tianfield, Glasgow Caledonian University, Glasgow, UK Rainer Unland, University of Duisburg-Essen, Essen, Germany Presented by: Joseph Cilli Agnostic: Michael Robinson
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1 A Concise Introduction to Autonomic Computing Roy Sterritt, University of Ulster at Jordanstown, Northern Ireland, UK Manish Parashar, Rutgers University,
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A Concise Introduction to Autonomic Computing
Roy Sterritt, University of Ulster at Jordanstown, Northern Ireland, UK
Manish Parashar, Rutgers University, New Jersey, USA
Huaglory Tianfield, Glasgow Caledonian University, Glasgow, UK
Rainer Unland, University of Duisburg-Essen, Essen, Germany
Presented by: Joseph Cilli
Agnostic: Michael Robinson
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Topics
• 1.0 Introduction
• 2.0 Concepts
• 3.0 Autonomic Computing
• 4.0 Examples of Autonomic Systems & Applications
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1.0 Introduction
• Technological advances = High growth
• High growth = More complex systems
• System & application complexity growth
• Brittle, unmanageable, insecure
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1.0 Introduction• Strategies based on biological systems• Inspired by human nervous system
Defined as: A self-managing,autonomous and ubiquitous computingenvironment that completely hides itscomplexity, thus providing the user with an interface that exactly meets her/hisneeds.
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1.0 Introduction
• Make decisions on its own, using high-level guidance from humans
• Constantly checking & optimizing its status & automatically adapt itself to new conditions
• Self-Management achieved through:
Self-governingSelf-adaptationSelf-organizationSelf-optimizationSelf-configurationSelf-diagnosis of faultSelf-protectionSelf-healingSelf-recoveryAutonomy
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2.0 Concepts
• 2.1 Autonomic Nervous System
• 2.2 Autonomic Computing Systems
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2.1 Autonomic Nervous System
• Controls the vegetative functions of the body (involuntary)– Circulation of blood– Intestinal activity & secretion– Production of chemical ‘messengers’
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2.1 Autonomic Nervous System
• Sympathetic– Fast heart rate– Fear
• Parasympathetic– Slow heart rate– Calm
Biological Self-Management Systems Self-Management
• AC advancement– Integrating– Managing– Operating
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• GOALS– Manage complexity
• Technology managing technology
– Reduce cost of ownership• Automation reduces human involvement/error
– Enhance other software qualities• Reflective, self aware components can continually
seek to optimize themselves
2.2 Autonomic Computing Systems
•Source: An architectural blueprint for autonomic computing. Third Edition, June 2005. Available at URL: http://www-03.ibm.com/autonomic/pdfs/AC%20Blueprint%20White%20Paper%20V7.pdf
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• Autonomic elements of human body– Involuntary
• Autonomic elements of computer systems– Decisions based on tasks
2.2 Autonomic Computing Systems
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• Self-Management – Self-configuring
• Adapt automatically to the dynamically changing environment
– Self-healing• Discover, diagnose and react to disruptions
– Self-optimizing• Monitor and tune resources automatically
– Self-protecting• Anticipate, detect, identify, and protect against attacks from anywhere
• User studies• Interfaces (monitor & control behavior)• Techniques (defining, distributing, &
understanding policies)
• Autonomic computing– Makes choices for you
• Personal computing– Allows you to make choices yourself
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3.6 Science of Autonomicity
• Understanding, controlling, or exploiting emergent behavior
• Theoretical investigations of coupled feedback loops, robustness, & other related topics
• Expressed as the automation of systems adaptation
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3.7 Systems & SoftwareEngineering for Autonomic Systems
• Early Days– Implementations/Prototypes– Architectures & proof tools
• Current Models– Programming autonomic systems– Designs for self-management– Gathering requirements
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• Legacy systems– Sensors & effectors
• Kinesthetics eXtreme which runs a lightweight decentralized collection of active middleware components tied together via a publish/subscribe event system
• Astrolabe tool may be used to automate self-configuration & monitoring, & control adaptation
3.7 Systems & SoftwareEngineering for Autonomic Systems
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• 4.1 Early Success
• 4.2 Research Systems
• 4.3 Future
4.0 Examples
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4.1 Early Success
• DBMS– Evolution of more complex features– Reduced human interaction + cost– Alerts to DBA
Self-configure Corporate data centers are multi-vendor, multi-platform. Installing, configuring, integrating systems is time-consuming, error-prone.
Automated configuration of components, systems according to high-level policies; rest of system adjusts automatically. Seamless, like adding new cell to body or new individual to population.
Self-heal Problem determination in large, complex systems can take a team of programmers [for] weeks
Automated detection, diagnosis, and repair of localized software/hardware problems.
Self-optimize WebSphere, DB2 have hundreds of nonlinear tuning parameters; many new ones with each release.
Components and systems will continually seek opportunities to improve their own performance and efficiency.
Self-protect Manual detection and recovery from attacks and cascading failures.
Automated defense against malicious attacks or cascading failures; use early warning to anticipate and prevent system-wide failures.
• Borrowed from Jeff Kephart’s talk, Applications of Multi-Agent Learning in E-Commerce and Autonomic Computing, 2002.