In data-centric sensor networks each device is like a minimal computer with cpu and memory able to sense, manage and transmit data performing in-network processing by means of insertions, querying and multi-hop routings. Saving energy is one of the most important goals, therefore radio transmissions, which are the most expensive operations, should be limited by optimizing the number of routings. Moreover the network traffic should be balanced among nodes in order to avoid premature discharge of some devices and then network partitions. In this paper we present a fully decentralized infrastructure able to self-organize fully functional data centric sensor networks from local interactions and learning among devices. Differently from existing solutions, our proposal does not require complex devices that need global information or external help from systems, such as the Global Positioning System (GPS), which works only outdoor with a precision and an efficacy both limited by weather conditions and obstacles. Our solution can be applied to a wider number of scenarios, including mesh networks and wireless community networks. The local learning occurs by exploiting implicit cost-free overhearing at sensors. The work reports an extensive number of comparative experiments, using several distributions of sensors and data, with a well-know competitor solution in literature, showing that an approach fully based on self-organization is more efficient than traditional solutions depending on GPS. Work partially funded by the european project DORII: Deployment of Remote Instrumentation Infrastructure Grant agreement no. 213110.
G. Monti, G. Moro (2009). Self-organization and Local Learning Methods for Improving the Applicability and Efficiency of Data-Centric Sensor Networks. Berlin : Springer [10.1007/978-3-642-10625-5_40].
Self-organization and Local Learning Methods for Improving the Applicability and Efficiency of Data-Centric Sensor Networks
MORO, GIANLUCA
2009
Abstract
In data-centric sensor networks each device is like a minimal computer with cpu and memory able to sense, manage and transmit data performing in-network processing by means of insertions, querying and multi-hop routings. Saving energy is one of the most important goals, therefore radio transmissions, which are the most expensive operations, should be limited by optimizing the number of routings. Moreover the network traffic should be balanced among nodes in order to avoid premature discharge of some devices and then network partitions. In this paper we present a fully decentralized infrastructure able to self-organize fully functional data centric sensor networks from local interactions and learning among devices. Differently from existing solutions, our proposal does not require complex devices that need global information or external help from systems, such as the Global Positioning System (GPS), which works only outdoor with a precision and an efficacy both limited by weather conditions and obstacles. Our solution can be applied to a wider number of scenarios, including mesh networks and wireless community networks. The local learning occurs by exploiting implicit cost-free overhearing at sensors. The work reports an extensive number of comparative experiments, using several distributions of sensors and data, with a well-know competitor solution in literature, showing that an approach fully based on self-organization is more efficient than traditional solutions depending on GPS. Work partially funded by the european project DORII: Deployment of Remote Instrumentation Infrastructure Grant agreement no. 213110.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.