Abstract
Air pollution is a widespread problem due to its impact on both humans and the environment. Providing decision makers with artificial intelligence based solutions requires to monitor the ambient air quality accurately and in a timely manner, as AI models highly depend on the underlying data used to justify the predictions. Unfortunately, in urban contexts, the hyper-locality of air quality, varying from street to street, makes it difficult to monitor using high-end sensors, as the cost of the amount of sensors needed for such local measurements is too high. In addition, development of pollution dispersion models is challenging. The deployment of a low-cost sensor network allows a more dense cover of a region but at the cost of noisier sensing. This paper describes the development and deployment of a low-cost sensor network, discussing its challenges and applications, and is highly motivated by talks with the local municipality and the exploration of new technologies to improve air quality related services. However, before using data from these sources, calibration procedures are needed to ensure that the quality of the data is at a good level. We describe our steps towards developing calibration models and how they benefit the applications identified as important in the talks with the municipality.
Highlights
Good air quality in urban areas is essential for human well-being
We explore the feasibility of using a network of low-cost sensors for services such as air quality monitoring and forecasting in a city or decisionmaking support to decision makers in the municipality
It consists of three components: first the low-cost sensor network, which collects and regularly sends data via an Internet of Things (IoT) gateway to an air quality server (AQ Server) that stores and adjusts the data based on the lab calibration parameters
Summary
Good air quality in urban areas is essential for human well-being. Since 2008, when the European Union released the Ambient Air Quality EU Directive 2008/50/EC that establishes health-based standards and objectives for pollutants present in the air, the assessment of outdoor air quality has been focused on by municipalities. Have collaborated with the municipality of Trondheim (Norway) since August 2018 on the exploration of options for improved air quality services based on new technologies within the context of artificial intelligence (AI) and Internet of Things (IoT). This collaboration is referred to as the AI4IoT (https://research.idi.ntnu.no/ai4eu/, accessed on 3 May 2021). We focus on supervised learning but the pipeline is general enough to accommodate any other type of model Those components can be accessed by decision-making tools for providing air quality information to citizens or decision makers
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