Research project

IoT-based ocean pollutant monitoring for source detection

Project overview

Pollution in water bodies such as rivers, ports, and estuaries often go unnoticed until its detrimental effects become evident. This delayed response contrasts with the more immediate detection methods available in urban air quality monitoring. The environmental impact in less populated regions, crucial for local economies reliant on natural resources, can be long-lasting and devastating [1-2]. This study introduces a sophisticated method for promptly detecting pollution and identifying its sources in aquatic environments. The method combines Internet-of-Things (IoT) technology with advanced machine learning techniques. We employ a network of IoT devices equipped with Long Range (LoRa) radio transceiver modules, covering a range of 15-20km. These devices, designed to be either stationary (buoys) or mobile (shipborne), are outfitted with sensors to monitor air and water quality. Data from these sensors are wirelessly transmitted to a central hub, which uploads it to the cloud in real-time. Our sensors track a range of pollutants, such as volatile organic compounds, carbon dioxide, particulates in air, and waterborne substances like dissolved oxygen and hydrocarbons. Utilizing this data, we can spot unusual environmental changes and trace back to potential pollution sources, like ships. This process is enhanced by integrating data from Automatic Identification Systems (AIS) with our sensor data, including air and water current data [3].

To quantify and trace the pollution dispersion from potential sources, we employ a physics-informed machine learning (PIML) approach. This PIML method has two key steps that involve initial pollution dispersion modelling from source candidates followed by adjustment of the model to align with the sensor data. We simplify the complex interaction between pollutant dispersion and environmental factors, assuming homogenous and isotropic pollutant diffusivity, and constant laminar wind/current velocity [4]. In addition to PIML, we use a traditional feature-based machine learning approach to categorize sensor data into 'pollutant' or 'non-pollutant' classes based on predefined expert thresholds. This categorization is then compared with AIS data to pinpoint passing vessels as potential pollution sources. This streamlined approach focuses on vessels that repeatedly appear in polluted areas allows for more accurate identification and reduces the resources needed for monitoring. The integration of IoT technology with machine learning provides a robust framework for real-time environmental surveillance. This approach allows for the efficient identification of pollution sources, contributing significantly to the preservation and protection of aquatic ecosystems. The data collected from this system will enable the analysis of pollutant vessel movements, assisting in the development of effective pollution control strategies.

This work presents a notable advancement in environmental monitoring by combining IoT with machine learning to effectively identify and track pollution sources in aquatic environments. By facilitating early detection and efficient source identification, this approach holds great promise for enhancing environmental protection and supporting sustainable management of natural resources, marking a crucial step forward in ecological conservation efforts.

References:
[1] Stefan Gössling, Christiane Meyer-Habighorst, and Andreas Humpe. A global review of marine air pollution policies, their scope and effectiveness. Ocean & Coastal Management, 212:105824, October 2021

[2] Daniel Mueller, Stefanie Uibel, Masaya Takemura, Doris Klingelhoefer, and David A Groneberg. Ships, ports and particulate air pollution - an analysis of recent studies. Journal of Occupational Medicine and Toxicology, 6(1):31, 2011.

[3] Martí Puig, Arnau Pla, Xavier Seguí, and Rosa Mari Darbra. Tool for the identification and implementation of environmental indicators in ports (TEIP). Ocean & Coastal Management, 140:34–45, May 2017.

[4] John M. Stockie. The mathematics of atmospheric dispersion modeling. SIAM Review, 53(2):349–372, January 2011.

Staff

Lead researchers

Mr Gyanendro Loitongbam PhD

Research Fellow

Research interests

  • the application of Natural Language Processing tasks,
  • multimodal text analysis,
  • sentiment analysis on social media data,
Connect with Gyanendro
Other researchers

Dr Ayodeji Abioye

Research Fellow in Human-Swarm Interactn

Research interests

  • Unmanned Multi-rotor Aircraft
  • Autonomous Robotic Systems
  • Human Machine Interaction
Connect with Ayodeji

Dr Arturo Vazquez Galvez

Engineering Research Fellow
Connect with Arturo

Dr Henrik Sykora

Research Fellow

Research interests

  • Numerical and computational methods for stochastic dynamical systems (stability, pathwise simulation, PDF evolution)Data-driven identification of inherently stochastic dynamical systemsStochastic nonsmooth systems with applications in energy harvestingStochastic dynamical systems with delay with applications in control systems and machine tool vibrations
Connect with Henrik

Collaborating research institutes, centres and groups

Research outputs