Air Quality Monitoring Network: Difference between revisions

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|Published=2022-03-16
|Published=2022-03-16
|Organization=Hello Lamp Post, University of British Columbia
|Organization=Hello Lamp Post, University of British Columbia
|poc=Tiernan_Mines
|Where=Vancouver BC
|Where=Vancouver BC
|Summary=Air Pollution is an urgent problem linked to as many as nine million deaths per year worldwide and 14,000 annually in Canada, primarily from related heart and lung diseases. On UBC campus, sources of air pollution include personal vehicles, construction, restaurants, and businesses. In fact, the BC Air Quality Health Index can change from “Low-Risk” to “High-Risk” on campus during air pollution events such as wildfires. To address this, we have installed a network of 8 low-cost air quality sensors across UBC campus to measure air pollutant concentrations at different locations on campus.
|Link=https://ireach.mech.ubc.ca/air-quality-monitoring-network/
|Display=Yes
|Display=Yes
|sector=Data, Wellbeing
|sector=Data, Wellbeing
|Release=Hello-ubc-case-study5page.pdf
}}
}}
Air Pollution is an urgent problem linked to as many as nine million deaths per year worldwide and 14,000 annually in Canada, primarily from related heart and lung diseases. In Vancouver, British Columbia (BC), sources of air pollution include industrial emissions, vehicle emissions and wildfire smoke. The air pollutants of concern include Particulate Matter less than 2.5 µm in size (PM2.5), Ozone, Carbon Monoxide (CO), Carbon Dioxide (CO2) and Nitrogen Oxides1. Breathing high concentrations of these pollutants can cause chronic illnesses, headaches, and even lung cancer and heart disease. On UBC campus, sources of air pollution include personal vehicles, construction, restaurants, and businesses. In fact, the BC Air Quality Health Index can change from “Low-Risk” to “High-Risk” on campus during air pollution events such as wildfires.
To address this, we have installed a network of 8 low-cost air quality sensors across UBC campus to measure air pollutant concentrations at different locations on campus. We are leveraging UBC’s existing 5G test bed that includes 1. anonymized video cameras (partnership with Numina2 and Blue City3) at traffic intersections to track vehicles, buses, pedestrians, and bicyclists; 2. Anonymized mobile data aggregation (partnership with Rogers Communication and Downtown.AI4) and 3. Survey Information (partnership with Hello Lamp Post5).
Our low-cost air quality sensors are called “Remote Air Quality Monitoring Platform” (RAMPs). RAMPs are capable of measuring air pollutants such as PM2.5, CO, CO2, NO and NO2 every 15 seconds. RAMPs are solar-powered, battery-operated and can also measure wind speed and direction (with attachments).
;Watch a video to learn more about our air pollution monitoring network on UBC campus
{{#ev:vimeo|591302352 }}
Hello Air Quality - UBC from Naomi Zimmerman on Vimeo.
;Real-time air quality on UBC campus
Click on this map below to find out more about your personal air pollution exposure at different locations on campus. Click on the individual sensors to read the respective pollutant concentrations across campus. The colour of the circle changes as the PM2.5 concentration increases. Breathing high concentrations of PM2.5 can lead to chronic illnesses including lung cancer and increased risk of heart attacks.
{{#display_map: University of British Columbia |center| zoom=10 |width=450|height=250}}
;Making sense of air quality data
[[File:TableAirQualityUBC.jpg|400px|center|Table of Air Quality]]
Metro Vancouver set a maximum allowable exposure level of 25 ug m-3 over a 24-hour period as part of its Air Quality Objectives (as of January 2020). Other air quality objectives are provided in the table below.
;Join our efforts
Please spread the word and ask your friends to answer the survey questions by texting 604-409-4498 to engage in friendly banter while learning about air pollution on UBC campus.
Meet the Researchers (helloairquality@mech.ubc.ca)
    Surya Dhulipala
    James Hindson
    Naomi Zimmerman
;Acknowledgements
This research was supported through funding from Rogers Communications and the Mitacs Accelerate program. Additionally, this research was undertaken, in part thanks to funding from the Canada Research Chairs Program.

Latest revision as of 05:23, April 28, 2022


News
Image Logo
Published 2022-03-16
Point(s) of Contact Tiernan_Mines
Organization(s) Hello Lamp Post
University of British Columbia
Where Vancouver BC
Display Yes
Press Release

Air Pollution is an urgent problem linked to as many as nine million deaths per year worldwide and 14,000 annually in Canada, primarily from related heart and lung diseases. On UBC campus, sources of air pollution include personal vehicles, construction, restaurants, and businesses. In fact, the BC Air Quality Health Index can change from “Low-Risk” to “High-Risk” on campus during air pollution events such as wildfires. To address this, we have installed a network of 8 low-cost air quality sensors across UBC campus to measure air pollutant concentrations at different locations on campus.

Air Pollution is an urgent problem linked to as many as nine million deaths per year worldwide and 14,000 annually in Canada, primarily from related heart and lung diseases. In Vancouver, British Columbia (BC), sources of air pollution include industrial emissions, vehicle emissions and wildfire smoke. The air pollutants of concern include Particulate Matter less than 2.5 µm in size (PM2.5), Ozone, Carbon Monoxide (CO), Carbon Dioxide (CO2) and Nitrogen Oxides1. Breathing high concentrations of these pollutants can cause chronic illnesses, headaches, and even lung cancer and heart disease. On UBC campus, sources of air pollution include personal vehicles, construction, restaurants, and businesses. In fact, the BC Air Quality Health Index can change from “Low-Risk” to “High-Risk” on campus during air pollution events such as wildfires.

To address this, we have installed a network of 8 low-cost air quality sensors across UBC campus to measure air pollutant concentrations at different locations on campus. We are leveraging UBC’s existing 5G test bed that includes 1. anonymized video cameras (partnership with Numina2 and Blue City3) at traffic intersections to track vehicles, buses, pedestrians, and bicyclists; 2. Anonymized mobile data aggregation (partnership with Rogers Communication and Downtown.AI4) and 3. Survey Information (partnership with Hello Lamp Post5).

Our low-cost air quality sensors are called “Remote Air Quality Monitoring Platform” (RAMPs). RAMPs are capable of measuring air pollutants such as PM2.5, CO, CO2, NO and NO2 every 15 seconds. RAMPs are solar-powered, battery-operated and can also measure wind speed and direction (with attachments).

Watch a video to learn more about our air pollution monitoring network on UBC campus

Hello Air Quality - UBC from Naomi Zimmerman on Vimeo.

Real-time air quality on UBC campus

Click on this map below to find out more about your personal air pollution exposure at different locations on campus. Click on the individual sensors to read the respective pollutant concentrations across campus. The colour of the circle changes as the PM2.5 concentration increases. Breathing high concentrations of PM2.5 can lead to chronic illnesses including lung cancer and increased risk of heart attacks.

Loading map...
Making sense of air quality data
Table of Air Quality

Metro Vancouver set a maximum allowable exposure level of 25 ug m-3 over a 24-hour period as part of its Air Quality Objectives (as of January 2020). Other air quality objectives are provided in the table below.

Join our efforts

Please spread the word and ask your friends to answer the survey questions by texting 604-409-4498 to engage in friendly banter while learning about air pollution on UBC campus. Meet the Researchers (helloairquality@mech.ubc.ca)

   Surya Dhulipala
   James Hindson
   Naomi Zimmerman
Acknowledgements

This research was supported through funding from Rogers Communications and the Mitacs Accelerate program. Additionally, this research was undertaken, in part thanks to funding from the Canada Research Chairs Program.