Scottish experts develop AI to remotely monitor water quality

A team of researchers at the University of Stirling has developed a new algorithm (artificial intelligence) to remotely monitor water quality.

The algorithm analyzes data directly from satellite sensors and makes it easier for coastal zone, environmental and industry managers to monitor issues such as harmful algal blooms (HABs). It also allows for monitoring of possible toxicity in shellfish and finfish.

Deteriorating water quality, largely due to climate change or pollution, remains a challenge almost across the world, putting futher strain on available water resources needed for potable purposes.

According to an official statement, environmental protection agencies and industry bodies currently monitor the ‘trophic state’ of water — its biological productivity — as an indicator of ecosystem health. Large clusters of microscopic algae, or phytoplankton, is called eutrophication and can turn into HABs, an indicator of pollution and which pose risk to human and animal health.

HABs are estimated to cost the Scottish shellfish industry £1.4 million per year, and a single HAB event in Norway killed eight million salmon in 2019, with a direct value of over £74 million.

“Currently, satellite-mounted sensors, such as the Ocean and Land Instrument (OLCI), measure phytoplankton concentrations using an optical pigment called chlorophyll-a. However, retrieving chlorophyll-a across the diverse nature of global waters is methodologically challenging”, said lead author Mortimer Werther, a PhD researcher in biological and environmental sciences at Stirling’s Faculty of Natural Sciences.

“We have developed a method that bypasses the chlorophyll-a retrieval and enables us to estimate water health status directly from the signal measured at the remote sensor.”

Eutrophication and hype eutrophication is often caused by excessive nutrient input, for example from agricultural practices, waste discharge, or food and energy production. In impacted waters, HABs are common, and cyanobacteria may produce cyanotoxins which affect human and animal health. In many locations, these blooms are of concern to the finfish and shellfish aquaculture industries.

“To understand the impact of climate change on freshwater aquatic environments such as lakes, many of which serve as drinking water resources, it is essential that we monitor and assess key environmental indicators, such as trophic status, on a global scale with high spatial and temporal frequency”, Werther was quoted as saying.

“This research, funded by the European Union’s Horizon 2020 programme, is the first demonstration that trophic status of complex inland and nearshore waters can be learnt directly by machine learning algorithms from OLCI reflectance measurements. Our algorithm can produce estimates for all trophic states on imagery acquired by OLCI over global water bodies”.

“Our method outperforms a comparable state-of-the-art approach by 5-12% on average across the entire spectrum of trophic states, as it also eliminates the need to choose the right algorithm for water observation. It estimates trophic status with over 90% accuracy for highly affected eutrophic and hypereutrophic waters”, he added.