11. SUSTAINABLE CITIES AND COMMUNITIES

Fresher AIr: AI and mobility data may improve air pollution exposure models

Fresher AIr: AI and mobility data may improve air pollution exposure models
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Fresher AIr: AI and mobility data may improve air pollution exposure …  Science Daily

Fresher AIr: AI and mobility data may improve air pollution exposure models

American Northeast Faces Air Quality Challenges Due to Wildfire Smoke

Americans in the northeast paid greater attention to air quality alerts this summer as wildfire smoke thickened skies with an orange-tinted haze. Smoke and other sources of air pollution contain tiny particles, called fine particulate matter (PM 2.5). Smaller than the width of a human hair, PM 2.5 pose health dangers when inhaled, especially to people with pre-existing heart and lung conditions.

Improving Air Quality Models Using Artificial Intelligence and Mobility Data

“Our research shows that incorporating artificial intelligence and mobility data into air quality models can improve the models and help decision makers and public health officials prioritize areas that need extra monitoring or safety alerts because of unhealthy air quality or a combination of unhealthy air quality and high pedestrian traffic,” said Manzhu Yu, assistant professor of geography at Penn State and first author of the study.

Reported in the journal Frontiers in Environmental Science, the researchers examined PM 2.5 measurements across eight large metropolitan areas in the continental United States. Air quality data came from Environmental Protection Agency (EPA) monitoring stations and low-cost sensors usually purchased and distributed by local community organizations. They used the data to find hourly PM 2.5 averages in each region.

The scientists input the air quality data into a land use regression model. The model uses local geographical factors like satellite-measured aerosol levels, also called aerosol optical depth; distance to nearest road or stream; elevation; vegetation; and meteorological conditions such as humidity and wind speed to examine how the factors affect air quality. Past models have taken a linear approach to assessing air pollution, meaning that they assigned a fixed importance to each geographic factor and its impact on air quality, Yu explained. Certain factors like vegetation and meteorological conditions, however, cannot be represented this way because they change hourly or seasonally and may have complex interactions with other factors that affect air quality.

Yu and her colleagues took a nonlinear approach to better account for these changing or complex factors by incorporating automated machine learning — a type of artificial intelligence that automatically performs time-consuming tasks such as data preparation, parameter selection, and model selection and deployment — into the land use regression model. The automated machine learning approach used an ensemble method, which allows the machine to run and combine multiple models, to identify the best-performing model for each region. The researchers also examined anonymized cell phone mobility data to pinpoint areas with unhealthy air quality and high visitor numbers.

The researchers found that their automated machine learning method with integrated data from low-cost sensors and EPA monitoring stations improved the accuracy of air pollution exposure models by an average of 17.5%, offering greater spatial variation than using regulatory monitors alone. Yu credited the improved accuracy to the method’s ability to better account for the dynamic variables of aerosol optical depth and meteorological factors, which consistently proved to be the most important across all study regions. The mobility data component allowed the team to map potential hotspots within regions and times during the day and year when large numbers of people may be exposed to high PM 2.5 levels in these areas.

Utilizing Sustainable Development Goals (SDGs)

“Many areas may have consistently high air pollution levels, like those near factories and major transportation hubs, but that is not enough information to make a prioritized list of places needing extra monitoring or health alerts,” she said. “Our mobility-based exposure maps show public health officials and decision makers hotspots that have unhealthy air quality levels plus high visitor traffic. They can use this information to send alerts to people’s mobile phones when they enter an area with really high PM 2.5 levels to reduce their exposure to unhealthy air quality.”

Contributors and Support

Additional contributors to the research were Shiyan Zhang, doctoral candidate in geography, Penn State; Junjun Yin, assistant research professor in the Social Science Research Institute, Penn State; Jiheng Miao, who recently graduated with a bachelor’s degree in geography from Penn State; Kai Zhang, Empire Innovation Associate Professor in the School of Public Health, State University of New York, Albany; and Matthew Varela, an incoming Penn State graduate student who recently graduated with a bachelor’s degree in meteorology from the University of Oklahoma and participated in the study during Penn State’s summer 2022 Research Experiences for Undergraduates in Climate Science program.

Penn State, through the Miller Faculty Fellow Award from the College of Earth and Mineral Sciences, supported this research.

SDGs, Targets, and Indicators

  1. SDG 3: Good Health and Well-being

    • Target 3.9: By 2030, substantially reduce the number of deaths and illnesses from hazardous chemicals and air, water, and soil pollution and contamination.
    • Indicator: PM 2.5 measurements and air pollution exposure models.
  2. SDG 11: Sustainable Cities and Communities

    • Target 11.6: By 2030, reduce the adverse per capita environmental impact of cities, including by paying special attention to air quality and municipal and other waste management.
    • Indicator: Improved air quality models using artificial intelligence and mobility data.

Analysis

The article addresses two Sustainable Development Goals (SDGs) – SDG 3: Good Health and Well-being and SDG 11: Sustainable Cities and Communities.

SDG 3: Good Health and Well-being

The article is connected to SDG 3 as it discusses the health dangers posed by fine particulate matter (PM 2.5) in the air. The research aims to assess exposure to PM 2.5 and help public health officials develop strategies to reduce the number of deaths and illnesses caused by air pollution.

SDG 11: Sustainable Cities and Communities

The article is connected to SDG 11 as it focuses on improving air quality models using artificial intelligence and mobility data. By incorporating these technologies, decision makers and public health officials can prioritize areas that need extra monitoring or safety alerts due to unhealthy air quality or a combination of unhealthy air quality and high pedestrian traffic.

Based on the content of the article, the following targets and indicators can be identified:

Target 3.9: By 2030, substantially reduce the number of deaths and illnesses from hazardous chemicals and air, water, and soil pollution and contamination.

The research aims to improve air pollution exposure models using artificial intelligence and mobility data. By accurately assessing air quality and identifying areas with high PM 2.5 levels, public health officials can develop strategies to reduce the number of deaths and illnesses caused by air pollution.

Target 11.6: By 2030, reduce the adverse per capita environmental impact of cities, including by paying special attention to air quality and municipal and other waste management.

The research focuses on improving air quality models to better understand the adverse environmental impact of cities. By incorporating artificial intelligence and mobility data, decision makers can prioritize areas with unhealthy air quality and high visitor traffic, allowing them to take necessary measures to reduce the adverse impact on public health.

The article mentions several indicators that can be used to measure progress towards the identified targets:

  • PM 2.5 measurements: The researchers examined PM 2.5 measurements across eight large metropolitan areas in the United States to assess exposure to fine particulate matter.
  • Air pollution exposure models: The research team designed improved models using artificial intelligence and mobility data to better understand the impact of air pollution on public health.
  • Improved accuracy of air pollution exposure models: The automated machine learning method used in the research improved the accuracy of air pollution exposure models by an average of 17.5%, offering greater spatial variation than using regulatory monitors alone.
  • Mobility-based exposure maps: The researchers used anonymized cell phone mobility data to map potential hotspots within regions and times during the day and year when large numbers of people may be exposed to high PM 2.5 levels.

SDGs, Targets, and Indicators

SDGs Targets Indicators
SDG 3: Good Health and Well-being Target 3.9: By 2030, substantially reduce the number of deaths and illnesses from hazardous chemicals and air, water, and soil pollution and contamination. – PM 2.5 measurements
– Air pollution exposure models
SDG 11: Sustainable Cities and Communities Target 11.6: By 2030, reduce the adverse per capita environmental impact of cities, including by paying special attention to air quality and municipal and other waste management. – Improved air quality models using artificial intelligence and mobility data
– Improved accuracy of air pollution exposure models
– Mobility-based exposure maps

Behold! This splendid article springs forth from the wellspring of knowledge, shaped by a wondrous proprietary AI technology that delved into a vast ocean of data, illuminating the path towards the Sustainable Development Goals. Remember that all rights are reserved by SDG Investors LLC, empowering us to champion progress together.

Source: sciencedaily.com

 

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