SMT201 AY2019-20G2 Ex1 Jerome Quah Wei Ren

From Geospatial Analytics for Urban Planning
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

PART I: Thematic Mapping

Map 1: Distribution of Public Education Institutions in Singapore

Map 1: Distribution of Public Education Institutions in Singapore

Description

For this map, the data points were further classified and designed according to their type or main level, namely Centralised Institute, Mixed Level School, Junior College, Secondary School and Primary School, allowing the map viewer to differentiate the different public education institutions around Singapore.

The 2014 Planning Subzone Regions were also used to signify the regions of Singapore, allowing the viewer to further view these institutions in their appropriate regions. The OpenStreetMap layer was inserted to further pinpoint the location of the institutions in terms of different transport modes that can be taken to reach them, nearby amenities etc.

Map 2: Road Network System of Singapore

Map 2: Road Network System of Singapore

Description

The data points were further classified and designed according to their type and symbol description, namely Expressway, Expressway-Sliproad and Major Roads. Contour lines were removed due to its inapplicability and the international boundary was replaced using the OpenStreetMap layer that also represents this. The expressways were labelled accordingly to their name, allowing the map viewer to view these expressways at a glance.

With the function of Rule-based labelling, the major roads were also labelled accordingly with a minimum scale of 1:100000, allowing the viewer to zoom in and identify these roads which can be connected to the expressways via sliproads.

Map 3: 2014 Master Plan Landuse

Map 3: Singapore 2014 Master Plan Landuse

Description

The areas were narrowed down to the following which I feel are relevant in this map. The OpenStreetMap layer was also added for the map viewer to easily identify these areas.

With the land scarcity of Singapore, this map was designed to emphasise the open spaces of Singapore that could be utilised for further developments. The special/reserved areas designate the areas which are unavailable to be utilised. With Singapore being a major transhipment hub relying on exports from foreign countries, waterbodies and agriculture are also highlighted in this map where these areas could be substituted for other purposes.

PART II: Choropleth Mapping

Background Information

For the following maps, the term ‘Aged Population’ refers to Singaporean residents who are at least 65 years of age.

The 2014 Planning Subzone GIS data and the 2008 Planning Subzone GIS data by the Urban Redevelopment Authority were utilized for the maps portraying the resident population AgeGroup and Sex in 2010 and 2018 respectively, in which was acquired from the Department of Statistics Singapore. This is to cater for the difference in the subzone areas between 2014 and 2008, in which the subzones that are present in the 2014 Planning Subzone GIS Data might not be present in the 2008 Planning Subzone GIS data, leading to data discrepancies and unaccounted values.

For instance:

2008 Planning Subzone GIS data: Subzone_Code AMSZ08 is YIO CHU KANG

2014 Planning Subzone GIS data: Subzone_Code AMSZ08 is TAGORE. YIO CHU KANG is AMSZ10 instead.

Map 4: Aged Population in 2010

Map 4: Aged Population in 2010

Spacial Patterns/Reveals

From the map, the aged population of Singapore tends to be clustered in the East Region. From the East Region the subzones of Tampines East, Bedok North, Bedok South and Trafalgar seem to have the highest concentration of the aged population

Reasoning

With the intention of adding a Delimited Text Layer from the CSV. File that contains the integer values, I first started out with ‘cleaning’ the data, in the sense that all the empty cells and cells with ‘-’ are changed to 0. This is to ensure the prevent of any NULL values when the layer is added to QGIS. The layout of the CSV. File was also referenced from the ‘AgeGroup2017’ CSV.File used on HandsOnEx4.

From this, the new field of ‘Age 65+’ was derived through the following expression:

"AgeGroup2010_AGE65-69" + "AgeGroup2010_AGE70-74" + "AgeGroup2010_AGE75-79" + "AgeGroup2010_AGE80-84" + "AgeGroup2010_AGE85"

From this, the Graduated Symbology function was used with the column of ‘Age65+’. The Natural Breaks (Jenks) Mode was used to classify this column, allowing the creation of the choropleth map with the accurate representation of the trends or classes in the aged population.

After which, the Rule-based labelling function was used to identify the names of the subzones that fall within the 4th or 5th classes of the symbology, allowing the map viewer to recognise the areas that have high aged population in Singapore. The following expression was used:

"Age65+" >= 3230

Map 5: Aged Population in 2018

Map 5: Aged Population in 2018

Spacial Patterns/Reveals

Similarly to Map 4, the aged population of Singapore tends to be clustered in the East Region. However, there are fewer subzones that have a particularly high concentration of aged population, namely Tampines East and Bedok North.

From Map 4 and Map 5, there seems to be an increase in the quantity of the Aged Population in Singapore. This can be seen from the Classes used in these Maps. For example, the 4th class of Map 4 starts at a value of 3230, while the very same class of Map 5 starts at 4540.

Reasoning

With the intention of adding a Delimited Text Layer from the CSV. File that contains the integer values, I first started out with ‘cleaning’ the data, in the sense that all the empty cells and cells with ‘-’ are changed to 0. This is to ensure the prevent of any NULL values when the layer is added to QGIS. The layout of the CSV. File was also referenced from the ‘AgeGroup2017’ CSV.File used on HandsOnEx4.

From this, the new field of ‘Age 65+’ was derived through the following expression:

"AgeGroup2018_AGE65-69" + "AgeGroup2018_AGE70-74" + "AgeGroup2018_AGE75-79" + "AgeGroup2018_AGE80-84" + "AgeGroup2018_AGE85"

From this, the Graduated Symbology function was used with the column of ‘Age65+’. The Natural Breaks (Jenks) Mode was used to classify this column, allowing the creation of the choropleth map with the accurate representation of the trends or classes in the aged population.

After which, the Rule-based labelling function was used to identify the names of the subzones that fall within the 4th or 5th classes of the symbology, allowing the map viewer to recognise the areas that have high aged population in Singapore. The following expression was used:

"Age65 +" >= 4540

Map 6: Proportion of Aged Population in 2010

Map 6: Proportion of Aged Population in 2010

Spacial Patterns/Reveals

After calculating the proportions, the subzones that consist of a large aged population tends to cluster in the Central Zone of Singapore. Some examples of these subzones are Telok Blangah Drive, Alexandra Hill and Farrer Court. Jalan Kayu West seems to have the highest proportion of aged residents in Singapore.

Reasoning

Following the steps carried out in Maps 4 and 5, calculating the proportion of Aged Population in Singapore would require one more field which would be the ‘AgeTotal’. This new field was derived from the following expression:

"AgeGroup2010_AGE0-4" + "AgeGroup2010_AGE5-9" + "AgeGroup2010_AGE10-14" + "AgeGroup2010_AGE15-19" + "AgeGroup2010_AGE20-24" + "AgeGroup2010_AGE25-29" + "AgeGroup2010_AGE30-34" + "AgeGroup2010_AGE35-39" + "AgeGroup2010_AGE40-44" + "AgeGroup2010_AGE45-49" + "AgeGroup2010_AGE50-54" + "AgeGroup2010_AGE55-59" + "AgeGroup2010_AGE60-64" + "AgeGroup2010_AGE65-69" + "AgeGroup2010_AGE70-74" + "AgeGroup2010_AGE75-79" + "AgeGroup2010_AGE80-84" + "AgeGroup2010_AGE85"

After the calculation of this field, a new field named ‘ProportionAged’ was derived using the following expression:

“Age65+” / “AgeTotal”

However, after calculating, this field consisted of NULL values as there are cases in which the subzones do not have any integer values. An example would be PLSZ04 – AIRPORT ROAD. Therefore, the NULL values would be derived from a Zero Division Error when the ‘ProportionAged’ expression was used (0/0). I mitigated around this by manually changing the NULL values to 0 by using the Toggle Editing Mode in the Attribute Table.

From this, the Graduated Symbology function was used with the column of ‘ProportionAged’. The Natural Breaks (Jenks) Mode was used to classify this column, allowing the creation of the choropleth map with the accurate representation of the trends or classes in the aged population.

After which, the Rule-based labelling function was used to identify the names of the subzones that fall within the 4th or 5th classes of the symbology, allowing the map viewer to recognise the areas that have a high proportion of aged residents in Singapore. The following expression was used:

"ProportionAged" >= 0.143

Map 7: Proportion of Aged Population in 2018

Map 7: Proportion of Aged Population in 2018

Spacial Patterns/Reveals

After calculating the proportions, the subzones that consist of a large aged population tends to cluster in the Central and East Zones of Singapore. Some examples of these subzones are Marine Parade, Commonwealth, Siglap, Bedok South and Bugis. For this map, Loyang West seems to have the highest proportion of aged residents in Singapore.

In contrast to Map 6, there seems to be more subzones that have a high proportions of aged residents in Singapore, where there are more subzones in 2018 that fall within the 4th class of the symbology as compared to Map 6. Furthermore, this map also indicates that there is a rising aging population in Singapore, with the values of the symbology classes being higher than that of Map 6.

Reasoning

Following the steps carried out in Maps 4 and 5, calculating the proportion of Aged Population in Singapore would require one more field which would be the ‘AgeTotal’. This new field was derived from the following expression:

"AgeGroup2018_AGE0-4" + "AgeGroup2018_AGE5-9" + "AgeGroup2018_AGE10-14" + "AgeGroup2018_AGE15-19" + "AgeGroup2018_AGE20-24" + "AgeGroup2018_AGE25-29" + "AgeGroup2018_AGE30-34" + "AgeGroup2018_AGE35-39" + "AgeGroup2018_AGE40-44" + "AgeGroup2018_AGE45-49" + "AgeGroup2018_AGE50-54" + "AgeGroup2018_AGE55-59" + "AgeGroup2018_AGE60-64" + "AgeGroup2018_AGE65-69" + "AgeGroup2018_AGE70-74" + "AgeGroup2018_AGE75-79" + "AgeGroup2018_AGE80-84" + "AgeGroup2018_AGE85"

After the calculation of this field, a new field named ‘ProportionAged’ was derived using the following expression:

“Age65 +” / “AgeTotal”

However, after calculating, this field consisted of NULL values as there are cases in which the subzones do not have any integer values. An example would be TSSZ04 – TUAS BAY. Therefore, the NULL values would be derived from a Zero Division Error when the ‘ProportionAged’ expression was used (0/0). I mitigated around this by manually changing the NULL values to 0 by using the Toggle Editing Mode in the Attribute Table.

From this, the Graduated Symbology function was used with the column of ‘ProportionAged’. The Natural Breaks (Jenks) Mode was used to classify this column, allowing the creation of the choropleth map with the accurate representation of the trends or classes in the aged population.

After which, the Rule-based labelling function was used to identify the names of the subzones that fall within the 4th or 5th classes of the symbology, allowing the map viewer to recognise the areas that have a high proportion of aged residents in Singapore. The following expression was used:

"ProportionAged" >= 0.196

Map 8: Percentage Change of Aged Population between 2010 and 2018

Map 8: Percentage Change of Aged Population between 2010 and 2018

Spacial Patterns/Reveals

From the map, there seems to be an increase in the percentage of aged residents in Singapore, with majority of the subzones having a percentage increase between 3.9% and 19.0%. Loyang West has a particularly greater increase. This indicates an overall increase in the aging population in Singapore from 2010 to 2018. In contrast, the subzones of Sengkang West and Gali Batu seem to have a reduction in this percentage.

Reasoning

With reference to the Background Information of the maps in this part of the assignment, the first issue would be the choice of which Subzone Planning GIS data to use (2014 or 2008) due to the different subzones and their codes. This meant that the 2014 GIS data would be compatible with the 2018 CSV data, and the 2008 GIS data will be compatible with the 2010 CSV data. I choose to use the 2014 GIS data, where it would be more relevant to portray data that is more current in its date and the current subzones.

In this case, I have joined the 2010 CSV data to the 2018 CSV data using the SUBZONE_C Field for this field is unique for each data entry. After which, the 2018 CSV data (now containing the 2010 CSV data fields) were joined to the 2014 Subzone Planning GIS data.

From this, I have discovered that there are 13 Subzones in which there are NULL values, meaning that these subzones are not present in 2008 but are present in 2014. From this, since that these subzones do not have any data, I have chosen to make a layer in which these subzones are 'unavailable zones' in the map, in which the percentage change is unable to be applied for these subzones. The following are the 13 Subzones:

  1. HGSZ09 - DEFU INDUSTRIAL PARK
  2. HGSZ10 - LORONG HALUS
  3. AMSZ11 - YIO CHU KANG NORTH
  4. PGSZ07 - CONEY ISLAND
  5. SLSZ03 - PULAU PUNGGOL TIMOR
  6. SLSZ02 - PULAU PUNGGOL BARAT
  7. SLSZ04 - SELETAR
  8. AMSZ12 - YIO CHU KANG EAST
  9. SGSZ05 - LORONG CHUAN
  10. HGSZ08 - TAI SENG
  11. SGSZ07 - UPPER PAYA LEBAR
  12. PRSZ08 - FLORA DRIVE
  13. SGSZ06 - SERANGOON CENTRAL

After which, the Rule-based labelling function was used to identify the these subzones via the their subzone code (SUBZONE_C). The following expression was used:

SUBZONE_C = 'PGSZ07' OR SUBZONE_C = 'HGSZ09' OR SUBZONE_C = 'HGSZ10' OR SUBZONE_C = 'PRSZ08' OR SUBZONE_C = 'AMSZ12' OR SUBZONE_C = 'SGSZ07' OR SUBZONE_C = 'HGSZ08' OR SUBZONE_C = 'SGSZ06' OR SUBZONE_C = 'SGSZ05' OR SUBZONE_C = 'SLSZ03' OR SUBZONE_C = 'SLSZ02' OR SUBZONE_C = 'SLSZ04' OR SUBZONE_C = 'AMSZ11'

Following this, I have created a seperated layer to account for the percentage change. With reference with the expressions present in Maps 4 to 7, the following fields were calculated:

  • Age 65+ for 2010 and 2018
  • Total Age for 2010 and 2018
  • Proportion of Aged Population for 2010 and 2018

From that, the field 'PercentageChange' was calculated via the following expression:

(ProportionAgedPopulation2018 - ProportionAgedPopulation2010)*100

From this, the Graduated Symbology function was used with the column of ‘PercentageChange’. The Natural Breaks (Jenks) Mode was used to classify this column, allowing the creation of the choropleth map with the accurate representation of the trends or classes in the aged population.

After which, the Rule-based labelling function was used to identify the names of the subzones that fall within the 1st and 5th classes of the symbology, allowing the map viewer to recognize the subzones with the greatest negative percentage change or positive percentage change in aged population. The following expression was used:

  • "PercentageChange" >= -86 and "PercentageChange" <= -28 for the 1st class
  • "PercentageChange" > 20 for the 5th class

The class of 'No Change' was also added to identify the subzones with no percentage change.