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Real-Time Water Quality Monitoring and Estimation in AIoT for Freshwater Biodiversity Conservation

Yuhao Wang, Ivan Wang‐Hei Ho, Chen Yang, Yuhong Wang, Yinghong Lin

2021IEEE Internet of Things Journal64 citationsDOIOpen Access PDF

Abstract

Deteriorating water quality leads to the freshwater biodiversity crisis. The interrelationships among water quality parameters and the relationships between these parameters and taxa groups are complicated in affecting biodiversity. Nevertheless, due to the limited types of Internet-of-Things (IoT) sensors available on the market, a large number of chemical and biological parameters still rely on laboratory tests. With the latest advancement in Artificial intelligence and the IoT (AIoT), this technique can be applied to real-time monitoring of water quality, and further conserving biodiversity. In this article, we conducted a comprehensive literature review on water quality parameters that impact the biodiversity of freshwater and identified the top-10 crucial water quality parameters. Among these parameters, the interrelationships between the IoT measurable parameters and IoT unmeasurable parameters are estimated using a general regression neural network (GRNN) model and a multivariate polynomial regression (MPR) model based on historical water quality monitoring data. Conventional field water sampling and in-lab experiments, together with the developed IoT-based water quality monitoring system were jointly used to validate the estimation results along an urban river in Hong Kong. The GRNN can successfully distinguish the abnormal increase of parameters against normal situations. For the MPR model of degree 8, the coefficients of determination results are 0.89, 0.78, 0.87, and 0.81 for NO3-N, BOD <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">5</sub> , PO4, and NH3-N, respectively. The effectiveness and efficiency of the proposed systems and models were validated against laboratory results and the overall performance is acceptable with most of the prediction errors smaller than 0.2 mg/L, which provides insights into how AIoT techniques can be applied to pollutant discharge monitoring and other water quality regulatory applications for freshwater biodiversity conservation.

Topics & Concepts

Water qualityBiodiversityComputer scienceMultivariate statisticsSampling (signal processing)Quality (philosophy)Artificial neural networkEnvironmental scienceWater resourcesRegression analysisInternet of ThingsData miningMachine learningEcologyTelecommunicationsBiologyDetectorEmbedded systemPhilosophyEpistemologyWater Quality Monitoring TechnologiesWater Quality and Pollution AssessmentHydrological Forecasting Using AI
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