Difference between revisions of "IS428 2018-19 T1 Assign Fu Yu"

From Visual Analytics for Business Intelligence
Jump to navigation Jump to search
Line 26: Line 26:
 
* Air Tube datasets with geohash column being decoded
 
* Air Tube datasets with geohash column being decoded
 
* EEA time series data
 
* EEA time series data
[[File:Combined EEA datasets yu.fu.2015.png|center]]
+
</b>[[File:Combined EEA datasets yu.fu.2015.png|left]]</br>
 
* EEA metadata to show station locations
 
* EEA metadata to show station locations
 
* METEO-data
 
* METEO-data

Revision as of 22:31, 11 November 2018

Problem & Motivation

Air pollution is an important risk factor for health in Europe and worldwide. A recent review of the global burden of disease showed that it is one of the top ten risk factors for health globally. Worldwide an estimated 7 million people died prematurely because of pollution; in the European Union (EU) 400,000 people suffer a premature death. The Organisation for Economic Cooperation and Development (OECD) predicts that in 2050 outdoor air pollution will be the top cause of environmentally related deaths worldwide. In addition, air pollution has also been classified as the leading environmental cause of cancer.

Air quality in Bulgaria is a big concern: measurements show that citizens all over the country breathe in air that is considered harmful to health. For example, concentrations of PM2.5 and PM10 are much higher than what the EU and the World Health Organization (WHO) have set to protect health.

Bulgaria had the highest PM2.5 concentrations of all EU-28 member states in urban areas over a three-year average. For PM10, Bulgaria is also leading on the top polluted countries with 77 μg/m3on the daily mean concentration (EU limit value is 50 μg/m3).

According to the WHO, 60 percent of the urban population in Bulgaria is exposed to dangerous (unhealthy) levels of particulate matter (PM10).

Dataset Analysis & Transformation Process

Decode the geohash column in Air Tube data files

Geohash tells the station locations. However Tableau is not able to interpret geohash as geographic data. Before Air Tube data is imported to Tableau for analysis, geohash needs to be decoded into geographical coordinates. As the two Air Tube data files- data_bg_2017.xlsx and data_bg_2018.xlsx are of big sizes and there are duplicate geohash records in the data, an Excel file containing a unique geohash list was created.

Step 1: Use "pygeohash" package to decode the geohash list and output the coordinates in an Excel file

Geohash decode yu.fu.2015.PNG

Step 2: Combine geohash list and coordinates list into one Excel file and update the coordinates, latitude, longitude in data_bg_2017.xlsx and data_bg_2018.xlsx using VLOOKUP, LEFT and RIGHT functions in Excel

Coordinates latitude longitude yu.fu.2015.png

Combine multiple yearly data files into one time series data file

Combine files yu.fu.2015.png

Dataset Import Structure & Process

Datasets Imported to Tableau for Analysis

  • Air Tube datasets with geohash column being decoded
  • EEA time series data
Combined EEA datasets yu.fu.2015.png


  • EEA metadata to show station locations
  • METEO-data
  • TOPO-data

Join METEO-Data and Station STA-BG0052A Timeseries Data

With the given Meteo-data, which describes the temerature, wind speed, humidity, pressure and rainfall in Sofia Airport (42.6537, 23.3829 ), we can investigate the relationships between meteorology and air pollution. Since station STA-BG0052A(42.6665, 23.4002) is closest to Sofia Airport compared with other three stations, I use data in station STA-BG0052A for Comparison. Before visualising the two datasets, it is better to join them into one dataset. This can be done in tableau.

Join tables yu.fu.2015.png

The two datasets was joined by dates. Since the dates in the Meteo-data file are separate into year, month and day and the data types are string. Before joining them, the data types need to be changed to date.

Interactive Visualization

Interesting & Anomalous Observations

Task 1: Spatio-temporal Analysis of Official Air Quality

1.1 Most Recent and Past Situation of Air Quality in Sofia City

Sofia city air 2018 yu.fu.2015.png
Sofia city air 2013 yu.fu.2015.pngSofia city air 2014 yu.fu.2015.pngSofia city air 2015 yu.fu.2015.pngSofia city air 2016 yu.fu.2015.pngPM10 concentration lengend yu.fu.2015.png

The above graphs display the PM10 concentration in Sofia City from January 2013 to September 2018 where data for 2017 is omitted because there is only November and December data. Dark green indicates good air quality where PM10 concentration <= 50 ug/m3 . Light green indicates satisfactory air quality where 51 ug/m3 < PM10 concentration <=100 ug/m3. Yellow indicates poor air quality where PM10 concentration > 100 ug/m3. Each heatmap represents the air quality of one measured station in Sofia City.

Trends:

  • Air quality in all the four stations is usually poor at the start and the end of a year.
  • Being the station with fewest days having good air quality in 2013, station STA-BG0052A has the most days with good air quality in 2018 compared with other stations.
1.2 A Typical Day in Sofia City

A typical day in sofia city yu.fu.2015.png

To investigate how PM10 concentrations vary from hours to hours in a day, one can simply highlight a day on the heatmap and the hourly PM10 concentration graphs will update accordingly. For example, as shown in the diagram above, on 8 January 2018, air quality in stations STA-BG0052A and STA-BG0050A is poor after 10pm while air quality in station STA-BG0073A is poor starting from 12pm and in STA-BG0040A, air quality is poor throughout the day.

Trends:

  • There is no obvious trend showing on what time of a day the PM10 concentration is higher or lower
  • Nevertheless, PM10 concentrations do vary from time to time in a day.
1.3 Anomalies in the Datesetss

  • From 2013 to 2015, hourly PM10 concentration data is not available. Data was either only collected at 00:00 once or the hour when the data was collected was not recorded from 2013 to 2015. Also, in 2016, data was only collected at 00:00 on some days. If the data was only collected at 00:00 or only collected once, it might affect the accuracy of PM10 concentration distribution across the year because PM10 concentrations are different at different time in a day. It might happen that at the time the data was collected, the PM10 concentration was too high or too low, which would not be representative of the PM10 concentration of a day.
  • For 2017, only November and December data is available. Hence changes in air quality from 2016 to 2017 could not be investigated which might give the insights of why air quality in 2018 has improved.

Task 2: Spatio-temporal Analysis of Citizen Science Air Quality Measurements

2.1 Sensor Coverage, Performance and Operation

  • 2.1.1 Sensor Coverage
Sofia Sensor Coverage yu.fu.2015.png

The most recent sensor distribution (on 7 April 2018) shows that the sensors are not evenly spread out across the entire city. They are saturated in the center of the city. Nevertheless, the sensors did cover the central part of the city well.

  • 2.1.2 Sensor Performance and Operation
Abnormal sensor 42.625x23.321 yu.fu.2015.png

However, the sensors were not always working properly. As shown in the graphs above, fora example, on 3 February 2018, the sensor at (42.625, 23.321) was working properly. Its readings of pressure, humidity and temperature fluctuate within reasonable ranges though the day.

Abnormal sensor 42.625x23.321 4Feb yu.fu.2015.png

However, on 4 February 2018, the sensor temperature reading had a sharp drop from 7 degree to -139 degree at 9AM, which is not reasonable. At the same time, pressure and humidity readings also increased sharply, suggesting that the sensor might have a problem on 9AM, 4 February 2018.

Abnormal sensor 42.625x23.321 5Feb yu.fu.2015.png

The suspect was approved by the static sensor readings on 5 February 2018, suggesting that the sensor was not working. Similar sensor behaviors can also be seen on other sensors such as the sensor located at (42.686, 23.347) after 14 February 2018 and the sensor located at (42.715, 23.161) after 7 February 2018.

2.2 Air Pollution

Most of the time, pollution started from the northern part of the city. As time passes, the pollution can spread in different directions.

  • Case 1: Pollution spread to the south
11242017 concentration yu.fu.2015.png
11252017 concentration yu.fu.2015.png
11262017 concentration yu.fu.2015.png
  • Case 2: Pollution spread to the south first and then back to the north
12312017 concentration yu.fu.2015.png
01012018 concentration yu.fu.2015.png
01022018 concentration yu.fu.2015.png


Task 3: Factors Affecting Air Quality in Sofia City

Factor 1: Local Energy Sources
Local enery source yu.fu.2015.png

The diagrams above shows that in cities like Sofia and Blagoevgrad, P1 concentration is relatively high. This might be because these cities are along the main gas pipeline system. Since the cities are rich in hard coal, the gas and energy generated in these cities might be from burning of hard coals, which damages the air.

Factor 2: Local Meteorology

With the given Meteo-data, which describes the temperature, wind speed, humidity, pressure and rainfall in Sofia Airport (42.6537, 23.3829 ), we can investigate the relationships between meteorology and air pollution. Since station STA-BG0052A(42.6665, 23.4002) is closest to Sofia Airport compared with other three stations, I use data in station STA-BG0052A for comparison.

Local meteorology and air quality yu.fu.2015.png

The diagrams above compare the patterns of temperature, wind speed, humidity, pressure and rainfall in Sofia Airport (42.6537, 23.3829 ) with the pattern of PM10 concentration in Station STA-BG0052A(42.6665, 23.4002) in 2014. It shows that PM10 concentration tends to be high in a low temperature, low wind speed, high humidity and high pressure environment. However, the relationship between rainfall and PM10 concentration is not very obvious. Data in 2016 also shows the same findings.

Factor 3: Local Topography
Local topography and air quality yu.fu.2015.png

As mentioned in Task 2, pollution usually starts from the northern part of Sofia city. This may be due to the fact that Sofia's altitude is low in the north and high in the southwest. PM10 particles from the north can flow into Sofia city much more easily than those from the southwest.

Factor 4: Complex interactions between local topography and meteorological characteristics
Local topography and meteorology and air quality yu.fu.2015.png

The diagram shows that even though the pressure was high, humidity was high and temperature was low across the city, the pollution level is high in the northern part of the city mainly because of the low altitude in the northern part.

Factor 5: Transboundary Pollution

Pollution does spread from one place to another as discussed in Task 2. The graph below also displays that when air quality in Sofia is poor, the cities around it also have places with poor air quality.

Transboundary yu.fu.2015.png

References