https://doi.org/10.4081/jlimnol.2021.2011

Automated high frequency monitoring of Lake Maggiore through in situ sensors: system design, field test and data quality control

Vol. 80 No. 2 (2021)
Submitted: 3 March 2021
Accepted: 19 April 2021
Published: 21 June 2021
Water quality, chlorophyll, data management, sensors, SIMILE project
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Authors

Rocco Tiberti
https://orcid.org/0000-0003-1617-8826
National Research Council of Italy, Water Research Institute (CNR‐IRSA), Verbania, Italy.
Rossana Caroni
National Research Council of Italy, Water Research Institute (CNR‐IRSA), Verbania, Italy.
Massimiliano Cannata
https://orcid.org/0000-0003-2527-1416
Institute of Earth Sciences, Department of Environment, Construction and Design, University of Applied Sciences of Southern Switzerland (SUPSI), Mendrisio, Eswatini.
Andrea Lami
National Research Council of Italy, Water Research Institute (CNR‐IRSA), Verbania, Italy.
Dario Manca
National Research Council of Italy, Water Research Institute (CNR‐IRSA), Verbania, Italy.
Daniele Strigaro
Institute of Earth Sciences, Department of Environment, Construction and Design, University of Applied Sciences of Southern Switzerland (SUPSI), Mendrisio, Switzerland.
Michela Rogora
michela.rogora@cnr.it
https://orcid.org/0000-0003-3515-0220
National Research Council of Italy, Water Research Institute (CNR‐IRSA), Verbania, Italy.

A high frequency monitoring (HFM) system for the deep subalpine lakes Maggiore, Lugano and Como is under development within the EU INTERREG project SIMILE. The HFM system is designed to i) describe often neglected but potentially relevant processes occurring on short time scale; ii) become a cost-effective source of environmental data; and iii) strengthen the coordinated management of water resources in the subalpine lake district. In this project framework, a first HFM station (LM1) consisting of a monitoring buoy was placed in Lake Maggiore. LM1 represents a pilot experience within the project, aimed at providing the practical know-how needed for the development of the whole HFM system. To increase replicability and transferability, LM1 was developed in-house, and conceived as a low-cost modular system. LM1 is presently equipped with solar panels, a weather station, and sensors for water temperature, pH, dissolved oxygen, conductivity, and chlorophyll-a. In this study, we describe the main features of LM1 (hardware and software) and the adopted Quality Assurance/Quality Control (QA/QC) procedures. To this end, we provide examples from a test period, i.e., the first 9-months of functioning of LM1. A description of the software selected as data management software for the HFM system (IstSOS) is also provided. Data gathered during the study period provided clear evidence that coupling HFM and discrete sampling for QA/QC controls is necessary to produce accurate data and to detect and correct errors, mainly because of sensor fouling and calibration drift. These results also provide essential information to develop further the HFM system and shared protocols adapted to the local environmental (i.e., large subalpine lakes) and technical (expertise availability) context. Next challenge is making HFM not only a source of previously unaffordable information, but also a cost-effective tool for environmental monitoring.

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Edited by

Diego Fontaneto, CNR-IRSA Water Research Institute, Verbania, Italy
Daniele Strigaro, Institute of Earth Sciences, Department of Environment, Construction and Design, University of Applied Sciences of Southern Switzerland (SUPSI), Mendrisio

Department of Earth and Environmental Sciences (DSTA), University of Pavia, Italy

How to Cite

Tiberti, Rocco, Rossana Caroni, Massimiliano Cannata, Andrea Lami, Dario Manca, Daniele Strigaro, and Michela Rogora. 2021. “Automated High Frequency Monitoring of Lake Maggiore through <em>in situ< em> Sensors: System Design, Field Test and Data Quality Control”. Journal of Limnology 80 (2). https://doi.org/10.4081/jlimnol.2021.2011.
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