Mechanisms to Support Situated Agent Systems
ISCC '02 Proceedings of the Seventh International Symposium on Computers and Communications (ISCC'02)
Self-Organizing Resource Allocation for Autonomic Networks
DEXA '03 Proceedings of the 14th International Workshop on Database and Expert Systems Applications
Self-Optimizing Architecture for QoS Provisioning in Differentiated Services
ICAC '05 Proceedings of the Second International Conference on Automatic Computing
Biologically inspired self-adaptive multi-path routing in overlay networks
Communications of the ACM - Self managed systems
Applying blood glucose homeostatic model towards self-management of IP qos provisioned networks
IPOM'06 Proceedings of the 6th IEEE international conference on IP Operations and Management
Self-organization in communication networks: principles and design paradigms
IEEE Communications Magazine
IEEE Journal on Selected Areas in Communications
Self-organizing network services with evolutionary adaptation
IEEE Transactions on Neural Networks
Policy-constrained bio-inspired processes for autonomic route management
Computer Networks: The International Journal of Computer and Telecommunications Networking
ICCOM'10 Proceedings of the 14th WSEAS international conference on Communications
WSEAS TRANSACTIONS on COMMUNICATIONS
An intelligent information security mechanism for the network layer of WSN: BIOSARP
CISIS'11 Proceedings of the 4th international conference on Computational intelligence in security for information systems
ACS'11 Proceedings of the 11th WSEAS international conference on Applied computer science
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The current complexity of network management has helped drive the need for autonomic capabilities. The vision of autonomic network management provides the ability for network devices to cooperatively self-organise and self-govern in the support of high level business goals. These principles are inspired by biological systems. In this paper, we propose key self-organisation and self-governance techniques that are drawn from principles of molecular biology including (i) blood glucose homeostasis, (ii) reaction diffusion like principles, (iii) microorganism mobility using chemotaxis techniques, and (iv) hormone signaling. Preliminary simulation results have also been presented to validate our model.