Pulse Monitoring: Extending the Health-check for the Autonomic GRID

This paper upon looking at the Autonomic Computing architecture and Grid Computing highlights the importance of health check mechanisms to achieve a reflex-healing duel strategy. This will provide new design options for the development of the Autonomic Grid. The resulting pulse monitor is based on extending the existing Grid heart-beat monitor with urgency or anxiety levels such as that used in the NASA beacon monitor. The paper concludes with a discussion that this health check mechanism may be utilized in the future to achieve the necessary sense of urgency within a system for affect and emotion intelligence

PAC-MEN: Personal Autonomic Computing Monitoring Environments

The overall goal of this research is to improve the `environment awareness' aspect of personal autonomic computing. Personal Computing offers unique challenges for self-management due to its multiequipment, multi-situation, and multi-user nature. The aim is to develop a support architecture for multiplatform working, based on autonomic computing concepts and techniques. Of particular interest is collaboration among personal systems to take a shared responsibility for environment awareness. Concepts mirroring human mechanisms, such as 'reflex reactions' and the use of 'vital signs' to assess operational health, are used in designing and implementing the personal computing architecture. A proof of concept self-healing tool is considered and lessons learned used for the requirements specification of the community-based environment awareness prototype environment---PACMEN (Personal Autonomic Computing Monitor ENvironment)

Personal Autonomic Computing Reflex Reactions and Self-Healing

The overall goal of this research is to improve theself-awareness and environment-awareness aspect of personal au-tonomic computing (PAC) to facilitate self-managing capabilitiessuch as self-healing. Personal computing offers unique challengesfor self-management due to its multiequipment, multisituation, andmultiuser nature. The aim is to develop a support architecture formultiplatform working, based on autonomic computing conceptsand techniques. Of particular interest is collaboration among per-sonal systems to take a shared responsibility for self-awareness andenvironment awareness. Concepts mirroring human mechanisms,such as reflex reactions and the use ofvital signsto assess oper-ational health, are used in designing and implementing the PACarchitecture. As proof of concept, this was implemented as a self-healing tool utilizing a pulse monitor and a vital signs health moni-tor within the autonomic manager. This type of functionality opensnew opportunities to provide self-configuring, self-optimizing, andself-protecting, as well as self-healing autonomic capabilities topersonal computing

Towards an Autonomic Cluster Management System (ACMS) with Reflex Autonomicity

Cluster computing, whereby a large number of simple processors or nodes are combined together to apparently function as a single powerful computer, has emerged as a research area in its own right. The approach offers a relatively inexpensive means of providing a fault-tolerant environment and achieving significant computational capabilities for high-performance computing applications. However, the task of manually managing and configuring a cluster quickly becomes daunting as the cluster grows in size. Autonomic computing, with its vision to provide self-management, can potentially solve many of the problems inherent in cluster management. We describe the development of a prototype Autonomic Cluster Management System (ACMS) that exploits autonomic properties in automating cluster management and its evolution to include reflex reactions via pulse monitoring

Autonomic Management of Cloud Neighbourhoods through Pulse Monitoring

Abstract-This paper reports on autonomic computing research, including the development of a self-* proof of concept, for a cloud based environment. It monitors administrative boundaries from within an autonomic manager, with each manager operating in a peer-to-peer mode and utilizing a pulse monitor. The prototype was developed in Java utilizing SNMP to demonstrate the manager's self-situation and environment-awareness of the current state of the whole neighborhood and proves the feasibility of communicating the health of the neighborhood to peer managers using an XML pulse concept. Each manager houses the functionality to enact changes to their neighborhood using SNMP based rules. This enables the capability to provide self-healing, self-configuring, self-optimizing and self-protection to network neighborhoods within cloud computing