SMT201 AY2019-20G1 EX2 Riana

From Geospatial Analytics for Urban Planning
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Objective

The motive of this project is to find a suitable location for building a National Communicable Disease Quarantine Centre. The selected site must be located in Gombak Planning Subzone. Criteria: 1. A contiguous area of 10,000 m2 2. Factors: a. Economic Factor: avoid steep slope b. Accessibility Factor: close to existing local roads, namely: service roads and tracks c. Health Risk Factor: The selected site should be away from population d. Natural Conservation Factor: The selected site should be away from forested land, park and water.


Overview of Gombak Subzone


Data Source: Master Plan 2014 Subzone Boundary (No Sea) (SHP) from URA. Roads, Buildings and Natural (SHP) from OpenStreetMap. ASTER Global Digital Elevation Model (GDEM) dataset (TIFF) jointly prepared by NASA and METI, Japan; raster dataset combined by Professor Kam Tin Seong.


For this map, I use the different types and thickness of the lines and different colors to represent different types of road. Since expressway is the most travelled road, I use a thicker line to represent it, then follow by major road and minor road. In order to distinguish the line more, I used the different types of line to represent each of the road. Classification of expressway and major road is retrieved from the data.gov.sg while the minor road is retrieved from LTA DataMall.

2014 Master Plan Landuse


2014 Master Plan Landuse Riana.png


For this map, I have used a different colors and pattern to represent the different landuse purpose. Since there are a lot of categories from the data, I combined some of the categories such as Residential and Business. Besides colors, I used patterns to further distinguish some of the landuse. Furthermore, I have chosen colors that are the closest to the categories, e.g. red for restricted area and blue for waterbody.

Part 2: Choropleth Mapping

Aged population (+65) in 2010


Aged Population ( 65) in 2010.png


Firstly, in order to join to the subzone planning area data, I changed the subzone in the population data to uppercase using excel before importing to QGIS. Then, in order to cut down the processing time, I filtered the data by year 2010 and age group of 65 and above. Afterwards, I use GroupStats plugin to get the sum the aged population by the subzone and join the data with the subzone planning area data. I have used equal interval classification to classify the number of population in each subzone. I chose equal interval as it gives me a better insight of the area that are more aged population. I did not deal with any missing value in this map as I have use another subzone planning area map as a base map. From this map, we can infer that there are more aged population in the east side of Singapore in the year 2010.

Aged population (+65) in 2018


Aged Population ( 65) 2018.png


The steps to derive this map is exactly the same with the Aged Population in Singapore 2010 map. In this map, I found that there are no missing value, therefore, I can dispose the use of a base map. I used the same classification as Aged Population in Singapore 2010 to be able to compare the data more accurately. From the classification, we can see that the number of aged population has increase 1.5 times compared to 2010. The area with high number of aged population is still remained the same as 2010, which is on the east side of Singapore.

Proportional of aged population in 2010


Propotion of Aged Population 2010.png


In order to get the proportion of aged population, I get the sum of the total population in the subzone by using GroupStat plugin. After getting the sum of the total population by subzone, I joined the data with the sum of aged population from previous section. With these data, I get the proportion of the aged population compared to the total population. In this map, I used the natural breaks classification as it gives me more diverse result compared to other classification. From the map, we can infer that there are more proportion of aged population in the central area despite that there are more aged population in the east side from the previous section.

Proportional of aged population in 2018


Proportion of Aged Population 2018.png


I have used the same steps as the previous section to get the map. In order to see the changes of Proportion of aged population in a glance, I have used the same classification as the 2010 map. There are also missing values from the map and I also use a base map for this map. From this map, we can see that the proportion of aged population is still higher at the central however there are increase in proportion in the west side.

Percentage change of aged population between 2010 and 2018


Percentage Change of Aged Population in Singapore From 2010 to 2018.png


In order to get the data of percentage change of aged population, I use the data of sum of aged population in 2010 and 2018 from the previous section and by using the field calculator, I get the percentage change of from 2010 to 2018. For the classification, I have set the range myself as I would like to have 0 – 50 as the middle range. Besides, I use the green colour to represent that there is a drop in the percentage of aged population and red colour to represent that there is an increase in the percentage of aged population. From this map, we can see more clearly the difference of proportion of aged population over the years. We can see that there are mostly increase in the proportion of aged population over the years.