Abstract
Certain real-world applications present serious challenges to conventional neural-network design procedures. Blindly trying to train huge networks may lead to unsatisfactory results and wrong conclusions about the type of problems that can be tackled using that technology. In this paper a modular solution to power systems alarm handling and fault diagnosis is described that overcomes the limitations of "toy" alternatives constrained to small and fixed-topology electrical networks. In contrast to monolithical diagnosis systems, the neural-network-based approach presented here accomplishes the scalability and dynamic adaptability requirements of the application. Mapping the power grid onto a set of interconnected modules that model the functional behavior of electrical equipment provides the flexibility and speed demanded by the problem. After a preliminary generation of candidate fault locations, competition among hypotheses results in a fully justified diagnosis that may include simultaneous faults. The way in which the neural system is conceived allows for a natural parallel implementation.
Original language | English |
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Pages (from-to) | 326-340 |
Number of pages | 15 |
Journal | IEEE Transactions on Neural Networks |
Volume | 7 |
Issue number | 2 |
DOIs | |
Publication status | Published - 1996 |
Funding
September 30, 1995. This work was supported in part by CEC ESPRIT I1 Project 5433, BIKIT, Austrian Research Institute for Artificial Intelligence, Labein Research Centre, SocietC Lyonnaise des Eaux-Dumez, EYS-Elorduy Sancho y Cia.
Funders | Funder number |
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Austrian Research Institute for Artificial Intelligence | |
BIKIT | |
EYS-Elorduy | |
Labein Research Centre | |
SocietC Lyonnaise des Eaux-Dumez | |
California Energy Commission |