Journal Article10.1145/2505420.2505423
A framework for processing complex queries in wireless sensor networks
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TL;DR: This work presents a framework, denoted ADAGA -- P*, for processing complex queries and for managing sensor-field regression models and shows that it is quite efficient regarding communication cost and the number of executed float-point operations.
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Abstract: In this work, we present a framework, denoted ADAGA -- P*, for processing complex queries and for managing sensor-field regression models. The proposed mechanism builds and instantiates sensor-field models. Thus ADAGA -- P* makes query engines able to answer complex queries such as give the probability of rain for the next two days in the city of Fortaleza. On the other hand, it is well known that minimizing energy consumption in a Wireless Sensor Network (WSN) is a critical issue for increasing the network lifetime. An efficient strategy for saving power in WSNs is to reduce the data volume injected into the network. For that reason, ADAGA -- P* implements an in-network data prediction mechanism in order to avoid that all sensed data have to be sent to fusion center node (or base station). Thus, sensor nodes only transmit data which are novelties for a regression model applied by ADAGA -- P*. Experiments using real data have been executed to validate our approach. The results show that ADAGA -- P* is quite efficient regarding communication cost and the number of executed float-point operations. In fact, the energy consumption rate to run ADAGA -- P* is up to 14 times lower than the energy consumed by kernel distributed regression for an RMSE difference of 0.003.
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Citations
Improving Multidimensional Wireless Sensor Network Lifetime Using Pearson Correlation and Fractal Clustering.
TL;DR: The results prove that the proposed methods decrease the amount of data flowing in the network and present low root-mean-square error (RMSE), which is important for reducing message transmission in a wireless sensor network.
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A Framework for Wireless Sensor Network Optimization Using Fuzzy-Based Fractal Clustering to Enhance Energy Efficiency
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TL;DR: The proposed approach named Enhanced Energy Efficient Fuzzy-based Fractal Clustering (EEFFC) algorithm optimizes the performance of WSN and increases the lifetime of the wireless sensor network (WSN) by reducing energy consumption and improves routing efficiency.
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TL;DR: In this article, the authors proposed a new approach to cluster sensors in WSNs, called Behavioral Correlation in Wireless Sensor Network (BCWSN), which is based on the behavior of recent historical data collected by sensors.
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Parameter optimization of measuring and control elements in the monitoring systems of complex technical objects with triple reflector
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Fuzzy-Probabilistic Approach for Dense Wireless Sensor Network
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