Abstract
Monitoring contemporary water distribution networks (WDN) relies increasingly on smart metering technologies and wireless sensor network infrastructures. Smart meters and sensor nodes are deployed to capture and transfer information from the WDN to a control center for further analysis. Due to difficulties in accessing the water assets, many water utility companies employ battery-powered nodes, which restricts the use of high sampling rates, thus limiting the knowledge we can extract from the recorder data. To mitigate this issue, compressive sensing (CS) has been introduced as a powerful framework for reducing dramatically the required bandwidth and storage resources, without diminishing the meaningful information content. Despite its well-established and mathematically rigorous foundations, most of the focus is given on the algorithmic perspective, while the real benefits of CS in practical scenarios are still underexplored. To address this problem, this work investigates the advantages of a CS-based implementation on real sensing devices utilized in smart water networks, in terms of execution speedup and reduced ener experimental evaluation revealed that a CS-based scheme can reduce compression execution times around , while achieving significant energy savings compared to lossless compression, by selecting a high compression ratio, without compromising reconstruction fidelity. Most importantly, the above significant savings are achieved by simultaneously enabling a weak encryption of the recorded data without the need for additional encryption hardware or software components.
Highlights
Drinking water supplies face pressing issues, in island regions, where climate change, water scarcity, pollution, and the high cost of desalination are putting pressure on water distribution organisations
This study demonstrated the execution and energy efficiency of a Compressive sensing (CS)-based system for smart water network infrastructures equipped with sensing devices with possibly limited power and computational resources
Our implementation on real hardware revealed a significant reduction of the average execution time up to approximately 50%, when compared against a well-established lossless compression method that is used in commercial solutions, namely the fast Lempel–Ziv (LZ77) algorithm
Summary
Drinking water supplies face pressing issues, in island regions, where climate change, water scarcity, pollution, and the high cost of desalination are putting pressure on water distribution organisations. The main challenge of these infrastructures is that sensor nodes typically consume a lot of energy to record and transmit high-precision data [19] This constraint limits the amounts of data that can be sensed and relayed for analysis, which is necessary for timely and reliable anomaly detection (e.g., leakages and bursts) and alerting. Despite the well-established and mathematically rigorous foundations of CS, most of the focus is given on the algorithmic perspective, while the real benefits of CS in practical scenarios are still underexplored To address this problem, this work investigates the advantages of implementing a CS mechanism for lossy data compression on real sensing devices utilized in a real urban WDN, in terms of execution speedup and reduced energy consumption, when compared against a lossless compression alternative that is widely used in commercial hardware solutions.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
