n this work we propose a computational scheme inspired by the workings of human cognition. We embed some fundamental aspects of the human cognitive system into this scheme in order to obtain a minimization of computational resources and the evolution of a dynamic knowledge network over time, and apply it to computer networks. Such algorithm is capable of generating suitable strategies to explore huge graphs like the Internet that are too large and too dynamic to be ever perfectly known. The developed algorithm equips each node with a local information about possible hubs which are present in its environment. Such information can be used by a node to change its connections whenever its fitness is not satisfying some given requirements. Eventually, we compare our algorithm with a randomized approach within an ecological scenario for the ICT domain, where a network of nodes carries a certain set of objects, and each node retrieves a subset at a certain time, constrained with limited resources in terms of energy and bandwidth. We show that a cognitive-inspired approach improves the overall networks topology better than a randomized algorithm.
A Cognitive-Inspired Model for Self-Organizing Networks2012 IEEE Sixth International Conference on Self-Adaptive and Self-Organizing Systems Workshops / Daniel Borkmann;Andrea Guazzini;Emanuele Massaro;Stefan Rudolph. - STAMPA. - (2012), pp. 229-234. (Intervento presentato al convegno IEEE Sixth International Conference on Self-Adaptive and Self-Organizing Systems) [10.1109/SASOW.2012.47].
A Cognitive-Inspired Model for Self-Organizing Networks2012 IEEE Sixth International Conference on Self-Adaptive and Self-Organizing Systems Workshops
GUAZZINI, ANDREA;MASSARO, EMANUELE;
2012
Abstract
n this work we propose a computational scheme inspired by the workings of human cognition. We embed some fundamental aspects of the human cognitive system into this scheme in order to obtain a minimization of computational resources and the evolution of a dynamic knowledge network over time, and apply it to computer networks. Such algorithm is capable of generating suitable strategies to explore huge graphs like the Internet that are too large and too dynamic to be ever perfectly known. The developed algorithm equips each node with a local information about possible hubs which are present in its environment. Such information can be used by a node to change its connections whenever its fitness is not satisfying some given requirements. Eventually, we compare our algorithm with a randomized approach within an ecological scenario for the ICT domain, where a network of nodes carries a certain set of objects, and each node retrieves a subset at a certain time, constrained with limited resources in terms of energy and bandwidth. We show that a cognitive-inspired approach improves the overall networks topology better than a randomized algorithm.I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.