Abstract
Real world Structural Health Monitoring (SHM) systems consist of sensors in the scale of hundreds, each sensor generating extremely large amounts of data, often arousing the issue of the cost associated with data transfer and storage. Sensor energy is a major component included in this cost factor, especially in Wireless Sensor Networks (WSN). Data compression is one of the techniques that is being explored to mitigate the effects of these issues. In contrast to traditional data compression techniques, Compressive Sensing (CS) – a very recent development – introduces the means of accurately reproducing a signal by acquiring much less number of samples than that defined by Nyquist's theorem. CS achieves this task by exploiting the sparsity of the signal. By the reduced amount of data samples, CS may help reduce the energy consumption and storage costs associated with SHM systems. This paper investigates CS based data acquisition in SHM, in particular, the implications of CS on damage detection and localization. CS is implemented in a simulation environment to compress structural response data from a Reinforced Concrete (RC) structure. Promising results were obtained from the compressed data reconstruction process as well as the subsequent damage identification process using the reconstructed data. A reconstruction accuracy of 99% could be achieved at a Compression Ratio (CR) of 2.48 using the experimental data. Further analysis using the reconstructed signals provided accurate damage detection and localization results using two damage detection algorithms, showing that CS has not compromised the crucial information on structural damages during the compression process.
Highlights
Transmitting and maintaining large amounts of data in Structural Health Monitoring (SHM) systems have been issues addressed in recent researches due to the large scale real-world structures in use
Compressive Sensing (CS) is explored for its applicability in effective and efficient SHM using experimental structural response data from an Reinforced Concrete (RC) structure
Using CS with SHM measurements, successful reconstruction of the signal was achieved with reconstruction accuracies as good as 99% at considerable compression levels
Summary
Transmitting and maintaining large amounts of data in SHM systems have been issues addressed in recent researches due to the large scale real-world structures in use. Uncompressed structural response signals are acquired by each sensor and transmitted to a central server for processing and damage decision making This task unnecessarily consumes one of the most valuable resource in a WSN-based SHM system - energy, and wastes memory space of sensor nodes in both wired and wireless systems. In a wireless-based SHM system, such wastage results in reduced system lifetime and increased maintenance costs, since data transmission in a WSN is carried out at the cost of limited battery power of sensors For both types of systems, transmitting a lot of data increases the network traffic and collisions, reducing the reliability of data communication process. Damage detection and localization results using the CS reconstructed data are presented followed by the conclusions
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