Urbani izziv, volume 33, no. 2, 2022
115
UDC: 316.334.56:711.523(680)
doi:10.5379/urbani-izziv-en-2022-33-02-05
Received: 5 October 2022
Accepted: 25 November 2022
Roussetos-Marios STEFANIDIS
Alexandros BARTZOKAS-TSIOMPRAS
Where to improve pedestrian streetscapes:  
Prioritizing and mapping street-level walkability 
interventions in Cape Town’s city centre
Pedestrian interventions for healthier and more inclusive 
streetscapes can be powerful mechanisms to increase the 
safety and comfort of walking in African cities. This ar-
ticle proposes a multiscale walkability analysis approach 
to identify both suitable streets for pedestrian travel and 
problematic areas requiring small-scale improvements 
(e.g., pavement repairs, building maintenance, street-
lights, and public seating). We applied a GIS-based 
framework to the central urban area of Cape Town, South 
Africa, which presents complex social and environmental 
challenges. For each street-and-crossing segment, a virtual 
pedestrian streetscape audit tool was used to collect mi-
cro- and mesoscale environmental indicators and assess 
the quality of public space. This composite street-level 
assessment tool was weighted with a space syntax analysis 
indicator (i.e., spatial integration) to detect the network’s 
most interconnected and high-priority pathways. The 
Jenks natural breaks classification algorithm was used to 
classify scores for each segment, which ultimately found 
that the highest-priority streets for redevelopment are 
clustered in Bo-Kaap, a relatively disadvantaged, mul-
ticultural, and hilly district on Cape Town’s west side. 
Policy recommendations are evaluated to increase the 
quality of the urban environment and the city’s overall 
attractiveness to pedestrians. The proposed methodology 
facilitates more effective place management and classifies 
the city’s needs in improvements, minimizing both time 
and budget costs.
 
Keywords: walkability, pedestrian mobility, built envi-
ronment, Google Street View, Cape Town
Urbani izziv, volume 33, no. 2, 2022
116
1 Introduction
Building healthier transportation systems and more walkable 
and inclusive streets is vital to achieving high urban sustain-
ability and liveability levels (Loo, 2021). Walkability is an 
umbrella term that considers the quality of the built enviro-
nment as it facilitates walking (Forsyth, 2015). The concept has 
received substantial research interest; it has been associated, 
inter alia, with public health issues (e.g., physical inactivity, 
obesity, hypertension, and cancer; Sallis et al., 2016; Cerin 
et al., 2022), air pollution (Marshall et al., 2009), transport 
equity and car dependence (Knight et al., 2018), and real estate 
markets (Trichês Lucchesi et al., 2020). Thus, assessing walka-
bility is a good way to measure the impact of urban mobility 
and spatial planning policies on pedestrians.
Measuring walkability is a complex task involving a variety 
of methods and datasets. Fonseca et al. (2022) list thirty-two 
attributes of the built environment that influence walkability, 
as well as sixty-three measures related to land use, accessibility, 
street network connectivity, pedestrian facilities and comfort, 
safety and security issues, and streetscape design. In another 
example, the 3D concept (Density, Diversity, Design) propo-
sed by Cervero and Kockelman (1997) has inspired several 
GIS-based walkability indices of neighbourhood-level vari-
ables, such as population density, land-use mix, intersection 
density, and retail floor area ratio (e.g., see the GIS-based wal-
kability app developed by Frank et al., 2010). Notably, Cerin 
et al. (2022) demonstrate that people living in neighbourhoods 
with more than 5,700 inhabitants, one hundred street inter-
sections, and twenty-five transit stops per square kilometre are 
more likely to walk for transportation or physical recreation. 
In addition, a recent global study identified consistent associ-
ations between perceived design features and walking across 
twenty-one countries with different development profiles that 
include land-use mix diversity, land-use mix access, and stre-
et connectivity (Boakye et al., 2022). Koohsari et al. (2019) 
propose a non-data-intensive space syntax walkability measure 
based on space syntax integration (i.e., urban form) and popu-
lation density (i.e., urban function). Bartzokas-Tsiompras and 
Bakogiannis (2022) assessed the fifteen-minute walkable city 
idea across 121 European metropolitan areas using comparable 
indicators of walking accessibility to seven destination types 
(i.e., schools, food shops, population, recreation, restaurants, 
green spaces, and hospitals) and the PROMETHEE II mul-
ticriteria approach. Some researchers distribute questionnaires, 
such as the Neighbourhood Environment Walkability Scale 
framework, to measure perceived walkability levels (Adams 
et al., 2009), and others apply virtual or in situ streetscape 
audits (Brownson et al., 2004) to capture more policy-amena-
ble features (e.g., crosswalks, pavements, buildings, streetlights, 
aesthetics, and fear of crime).
However, African walkability research is still limited (Lofti & 
Koohsari, 2011; Ramakreshnan et al., 2021) and comprises 
only 1.5% of the global walkability literature (Hasan et al., 
2021), even though African people are more active for tran-
sport (56 min. a day) than the global average (43.9 min. a day) 
(UN-Habitat, 2022: 13). Previous African walkability studies 
have found that, compared to North American or European 
urban settings, different environmental attributes influence 
walking in Africa. For example, the perception of traffic safety 
in African environments is incidental to utilitarian walking be-
cause local populations tend to be more familiar with handling 
dangerous and congested roads; rather, it is the perception of 
crime that deters people from walking (Oyeyemi et al., 2017). 
Furthermore, Oyeyemi et al. (2017) indicate that local identi-
fiers and aesthetics do not encourage pedestrian trips because 
African populations generally have low expectations about the 
attractiveness of public spaces. Another study in Accra, Ghana, 
found a positive association between perceived walkability and 
prosocial behaviour (e.g., pro-environmental behaviour and 
socially responsible consumption), which is strengthened by 
urban residents’ sustainability knowledge (Opuni et al., 2022).
Globally, prioritizing interventions in the pedestrian enviro-
nment continues to draw research attention because even mi-
nor improvements to the street network can reduce pedestrian 
travel time and increase sustainable urban mobility (Delso et 
al., 2017, 2018). The targeted focus of investments in pede-
strian mobility infrastructure ensures that resources are used 
efficiently (D’Orso & Migliore, 2020). Introducing GIS tools 
in walkability studies has proven to be successful in formula-
ting geographically significant methodologies to characterize 
road networks (Delso et al., 2017, 2018; Ortega et al., 2021). 
In this regard, street-level pedestrian suitability analysis can be 
applied to the urban environment. This analysis combines stre-
et network proximity and connectivity with several variables 
concerning pedestrians’ physical environment, and it can ge-
nerate priority methodologies that easily identify which street 
segments require improvements (Delso et al., 2019). Priority 
methodologies provide information about city sectors that 
require alterations to the built environment to boost urban 
mobility (Ortega et al., 2021), such as street furniture or pe-
destrian infrastructure (Delso et al., 2017). Similarly, bicycle 
suitability analysis relies on common open-source datasets of 
factors that influence route choices, such as speed limit, slope, 
and type of cycle lane (Wysling & Purves, 2022). However, 
these methods can fail to consider audit-based data assessing 
the microscale elements of pedestrian and public space infra-
structure, and they may be insufficient to generate feasible, 
targeted actions for healthier streets.
Therefore, this study proposes a mixed-methods geographical 
approach to prioritizing and mapping street-level walkability 
R.-M. STEFANIDIS , A. BARTZOKAS-TSIOMPRAS 
Urbani izziv, volume 33, no. 2, 2022
117
interventions to improve pedestrian mobility and urban de-
sign. This approach combines some of the most important 
elements of the city’s built environment, including microscale 
environmental factors, which are relatively easy to change, and 
street-level connectivity, which is harder. The outcome of this 
approach is Street Segment Suitability (SSS), which indicates 
the degree to which pedestrians can use a street (i.e., how su-
itable it is for comfortable walking). The SSS score of every 
street segment is then subtracted from the space syntax integra-
tion to produce a Street-level Redevelopment Priorities (SRP) 
index. The higher the SRP value, the more work is required 
for maintenance, renovation, or improvement. Because many 
African cities lack the transportation research depth that their 
Global North counterparts enjoy, Cape Town’s city centre was 
selected as a case study.
2 Case study area: Cape Town
Cape Town is the legislative capital and second-largest city in 
South Africa, with an estimated population of 4.68 million 
as of 2021 (City of Cape Town, 2022). In recent decades, 
the city has seen substantial urban growth due to rural–urban 
migration. Reflecting its apartheid legacy, it retains significant 
socio-spatial inequalities that reinforce socio-spatial segregati-
on, poverty, and exclusion (Lloyd et al., 2021). From 1980 to 
2000, Cape Town’s population doubled (Western, 2002) and 
then increased steadily at a rate of 3.3% per annum between 
2000 and 2010 before slowing to 1.5% per annum from 2010 
to the present (Scheba et al., 2021). However, between 1998 
and 2019, the urban land cover grew from only 625 km² to 
679 km², meaning population growth outstripped it by 8.7% 
(Scheba et al., 2021). This underscores the densification and 
compaction trend reported by many scholars (Horn, 2018; 
Scheba et al., 2021). Furthermore, Cape Town is one of the 
most congested cities in Africa, mainly because of the poor 
quality of mobility. Its inefficient and unsafe public transpor-
tation network, with a network density of about 2 km/km² 
(UN-Habitat, 2013), is far outpaced by car travel. Indeed, 60% 
of residents travel by car, and only 4% walk (Deloitte, 2019). In 
addition, despite a large network of bike lanes (about 450 km), 
the share of cycling is less than 1%. Meanwhile, with about 7 
km of pedestrianized streets, Cape Town has the fourth-largest 
network (but small in global terms) of pedestrianized streets 
in all of Africa (Bartzokas-Tsiompras, 2021).
Cape Town’s urban fabric ranges from colonial grid patterns to 
conventional sprawling neighbourhoods (Wilkinson, 2000), 
Figure 1: Case study area (illustration: Alexandros Bartzokas-Tsiompras).
Where to improve pedestrian streetscapes: Prioritizing and mapping street-level walkability interventions in Cape Town’s city centre
Urbani izziv, volume 33, no. 2, 2022
118
and half of the total energy consumption at the city level is 
transportation-based (in many European cities the levels are 
roughly one-quarter; UN-Habitat, 2013). This complex urban 
system arose from former social and spatial policies (Ordor & 
Michell, 2022), notably the spatial inequalities that divided the 
city under the previous century’s apartheid system (Odendaal 
& McCann, 2016). Apartheid forced the city’s African and 
coloured populations to live in racially segregated residential 
zones with underdeveloped housing, transportation, and pu-
blic services (Gibb, 2007). To this end, apartheid transporta-
tion policies were designed to decrease connectivity and deter 
active travel in turn. Bo-Kaap, one of the oldest districts of 
Cape Town, located west of the city centre, is typical of the 
city’s formerly segregated neighbourhoods. Notably, it is the 
centre of Cape Malay Muslim culture. This area is now facing 
gentrification, as residential upgrades increase property values 
and displace the neighbourhood’s original inhabitants (Kotze, 
2013).
Therefore, St George’s Cathedral was selected as the focal 
point of this research due to its prominent position in Cape 
Town’s urban core and central business district (Gibb, 2007). 
As shown in Figure 1, a ten-minute walking distance isochro-
ne from St George’s Cathedral circumscribes the study area, 
taking into account the real street network and not a straight 
line (Boisjoly et al., 2018).
3 Materials and methods
The proposed method aims to support planners and decision-
-makers in prioritizing investments for more pedestrian-frien-
dly streets by examining the restrictions that urban planning 
imposes on pedestrians (Wood, 2022). This method combines 
multiple aspects of the built environment, represented by space 
syntax measures and microscale walkability attributes. Data 
collection is based on pedestrian streetscape observations, col-
Figure 2: Proposed methodology (illustration: authors).
R.-M. STEFANIDIS , A. BARTZOKAS-TSIOMPRAS 
Urbani izziv, volume 33, no. 2, 2022
119
lected virtually via the Google Street View service. The new 
street-level indicators for the central Cape Town area and the 
assessment method formulate an alternative way to quantify 
and map problematic public spaces in urgent need of feasi-
ble, cost-effective solutions. The process is briefly depicted in 
Figure 2.
3.1 Street connectivity (syntactic measure of 
integration)
According to Su et al. (2019), connectivity could be described 
as the extent to which routes inside a network are interconnect-
ed and the degree of various directional connections from ori-
gins to destinations. This study expresses connectivity through 
space syntax theory, which uses topological approaches to ana-
lyse how pedestrians move through public space (Hillier et al., 
1993). A variety of parameters can express space syntax analy-
sis, but the most important is arguably the syntactic measure 
of integration, as suggested by several studies (Hillier et al., 
1987, 1993). Space syntax integration is a topological measure 
of centrality that interprets the mean number of changes of 
direction needed to move from one place to all other places. 
Therefore, it produces a more complete sense of space depth, 
rather than metric distance. In other words, per Koohsari et 
al. (2019), space syntax integration expresses the accessibility 
of street segments to all other street segments in a given area 
(i.e., “to” movement) and estimates how many people are likely 
to be in a given space. High space syntax integration values 
indicate a well-connected segment, and low space syntax in-
tegration values an isolated one (Hillier & Hanson, 1984). 
Because the case study area includes several neighbourhoods, a 
local scale was applied to calculate the space syntax integration 
values within a 250 m radius, thereby relating the character-
istics of neighbourhood structure to pedestrian mobility. The 
QGIS Space Syntax Toolkit (https://plugins.qgis.org/plugins/
esstoolkit/) was used to calculate space syntax integration val-
ues. This is a QGIS plug-in for spatial network and statistical 
analysis; it provides a front-end for the essential depthmapX 
software within QGIS and offers user-friendly space syntax 
analysis workflows in a GIS environment.
3.2 Street-level walkability framework
A brief modified version of the original Microscale Audit of 
Pedestrian Streetscapes (MAPS-Mini) tool was selected to per-
form the prolific task of street auditing (Sallis et al., 2015). The 
original tool contains fifteen items (mostly binary or frequency 
questions) that measure crosswalk features, active uses, access 
to parks or plazas, transit facilities, public seats, streetlight in-
tensity, building condition, graffiti, the presence of pavements, 
pavement conditions, pavement buffers, bike lanes, and shade 
(Geremia & Cain, 2015). Physical activity studies in US cities 
have validated the composite scores of the original MAPS-Mi-
ni tool, finding a positive and statistically significant correla-
tion with increased active travel outcomes for all ages (Sallis 
et al., 2015). In addition, researchers from Europe have used 
MAPS-Mini to map and quantify street-level walkability at-
tractiveness and inequities in urban design (Bartzokas-Tsiom-
pras et al., 2020, 2021; Bartzokas-Tsiompras & Photis, 2021).
This study adds four extra variables to the original tool to 
produce new layers of microscale information, which are 
relevant either to Cape Town’s local context or to potential 
street-level redevelopment schemes. The first added variable 
concerns pavement accessibility (S9_1) and asks whether 
the pavement is continuous. The second relates to pavement 
width (S13). Both pavement continuity and pavement width 
provide insight into walking comfort levels. The third added 
variable describes road characteristics and assesses the number 
of traffic lanes (S14), which is a crucial parameter in road diet 
and placemaking programmes. Finally, the fourth relates to 
street vibrancy by capturing the intensity of shopping streets 
(S15) and assessing whether a given street segment is purely 
commercial.
Regarding the street observation method, we apply a hybrid 
method employing GIS and Google Street View (Lee & Talen, 
2014) in a fifteen-day auditing process. Every street segment 
is audited virtually using imagery data from either 2015 or 
2017 (based on availability), and the result is recorded with 
a single observer in the GIS database (i.e., ArcGIS 10.3). For 
each street segment, each of the nineteen variables receives 
either 0 points or 1 point; some variables can receive up to 2 
points. Of the nineteen variables, sixteen evaluate the street 
segment itself, and the rest evaluate the street crossing (see 
Figure 3). There are 1,025 audited street segments with a total 
length of approximately 78.6 km. Table 1[1] briefly summarizes 
the variables and their scores.
The Total Walkability Score (TWS) of each street segment 
and crossing is equal to the sum of the individual scores of the 
evaluation of each variable divided by the maximum possible 
sum (26 points) that an evaluated segment can obtain. The 
equation is as follows:
 (1)
where  TWS is the Total Walkability Score, and xi is the 
segment’s variable.
TWS varies from 0 to 1, with 0 indicating the lowest possible 
walkability and 1 the highest.
Where to improve pedestrian streetscapes: Prioritizing and mapping street-level walkability interventions in Cape Town’s city centre
Urbani izziv, volume 33, no. 2, 2022
120
3.3 Street segment suitability (SSS)
Having obtained street-level connectivity measures (i.e., space 
syntax integration) and walkability scores, the next step in 
the methodology is to multiply them, after converting the di-
mensionless values to a 0–1 scale via min-max normalization. 
The resulting value, SSS, depends on the initial space syntax 
integration and walkability values being at most equal to or 
less than the normalized space syntax integration value. The 
combination of these factors represents the actual state of the 
pedestrian infrastructure (Delso et al., 2019). The equation 
is as follows:
 (2)
where SSSi is street segment suitability, xi is the normalized 
space syntax integration value, and yi is the normalized value 
of walkability (TWS).
3.4  Street-level redevelopment priority (SRP)
The final step of the proposed method is to extract and map 
street-level redevelopment priority (SRP). SRP is obtained by 
subtracting the suitability (SSS) score of each segment from 
the space syntax integration value, which represents street-level 
centralities. The result is the difference between the actual and 
ideal pedestrian environment, indicating the need for street 
interventions to improve pedestrian mobility. The higher the 
SRP value, the further the street environment is from ideal 
conditions (as represented by the normalized space syntax in-
tegration value). The final step is severing the street segments 
of highest priority (i.e., the first quantile) and recategorizing 
them into three classes. The Jenks natural breaks classifica-
tion algorithm is used because it provides greater emphasis 
on low-frequency data. The outcome is the identification of the 
highest-SRP areas requiring immediate pedestrian interven-
tions. These top SRPs are denoted as street segment immediate 
priorities (SSIP). The equation is as follows:
 (3)
where SRPi is the street-level redevelopment priority, xi is the 
normalized space syntax integration value, and SSSi is the street 
segment suitability.
4 Results
The aggregated results of the collected data for each of the 
microscale variables are presented in Table 2.[2] Public transit 
stops (S3 = 6.5%) and public seating (S4 = 14.2%) are limited 
in most parts of the city. The widespread presence of street-
lights (S5 = 96.7%) and pavements (S9 = 93.5%) across the 
city centre, satisfactory building maintenance (S6 = 81.6%), 
sufficient pavement width (S13 = 74.8%), absence of graffiti 
vandalism (S7 = 92.3%), and the presence of mostly single traf-
fic lane roads (S14 = 39%) are considered positive elements of 
Figure 3: Example of street segment and crossing (source: Google Street View; illustration: authors).
R.-M. STEFANIDIS , A. BARTZOKAS-TSIOMPRAS 
Urbani izziv, volume 33, no. 2, 2022
121Where to improve pedestrian streetscapes: Prioritizing and mapping street-level walkability interventions in Cape Town’s city centre
Figure 4: Maps of audited street segments and crossings for each variable (illustration: authors).
Urbani izziv, volume 33, no. 2, 2022
122
walkability. As far as street crossings are concerned, pedestrian 
walk signals (32.2% of crossings have a pedestrian walk signal), 
kerb ramps (52.9% of crossings have pre- and post-kerb ramps), 
and marked crosswalks (39.3% of crossings have a marked pe-
destrian crossing) are not widespread enough across the city, 
leaving room for further improvements.
As illustrated in Figure 4, most of the active uses (S1) are 
located in the central business district northeast of St George’s 
Cathedral. Parks (S2) and public seating (S4) are chiefly con-
centrated northeast and southwest of the city centre. Transit 
stops (S3) are sited mainly to the east, across the large avenues 
(e.g., Strand St.). Poorly lit streets (S5), buildings with graffiti 
(S7), and streets with no pavements (S9) are concentrated in 
the western and northwestern area of the Bo-Kaap district. 
The same pattern follows the variables of building condition 
(S6) and pavement continuity (S9_1), with dilapidated build-
ings and non-continuous pavements clustered to the west (i.e., 
the Bo-Kaap district). Bike lanes (S8) are less prevalent in the 
area, except in the central business district area northeast of St 
George’s Cathedral. High-quality pavements (S10) and pave-
ment buffers (S11) tend to be located around the focal point, 
whereas problematic pavement sections are found in the east-
ern and western districts. Shadier pavements (S12) and streets 
with fewer than two road lanes (S14) are dispersed across the 
study area. However, pavements of insufficient width (S13) 
(< 2 m) are observed mainly in the western area of the Bo-
Kaap district. Purely commercial pedestrian streets (S15) are 
sparse in the city centre; they can only be found northeast of 
St George’s Cathedral; namely, St. George’s Mall Street. Re-
garding crosswalk facilities, we observe many in the northern 
and eastern parts of the study area. However, it is clear that 
most of the least safe and comfortable crossings are sited to 
the west and southeast, in the Bo-Kaap and Zonnebloem dis-
tricts, respectively.
Figure 5 illustrates the space syntax integration and TWS 
values. Integration values are directly related to the geometry 
of the street network, with higher values generated at three 
discrete clusters north, west, and northwest of St George’s Ca-
thedral. Meanwhile, the highest TWS values are concentrated 
along an axis running through the cathedral focal point in a 
northeast–southwest direction. Most of TWS’s lowest values 
Figure 5: a) Space syntax integration (connectivity) map; b) TWS map (illustration: authors).
Figure 6: SSS map (illustration: authors).
a b
R.-M. STEFANIDIS , A. BARTZOKAS-TSIOMPRAS 
Urbani izziv, volume 33, no. 2, 2022
123
Figure 7: a) SRP map; b) SSIP map (illustration: authors).
a b
Figure 8: a) Bryant St, a first-priority street; b) Buitengracht St, a 
second-priority street; c) Jordaan St, a third-priority street (source: 
Google Street View).
a
b
c
are focused on the northwestern edge of Cape Town’s city cen-
tre (the Bo-Kaap district), at the location where connectivity 
shows the highest values.
The SSS map (Figure 6) indicates that the most suitable seg-
ments for pedestrians are mostly those northeast and south-
west of the focal point, where the highest values of walkability 
are concentrated. Other high SSS values are observed in several 
areas in the western part of the city centre area. A large cluster 
of high SSS values is located around Greenmarket Square, a 
vivid hub of Cape Town only three blocks northeast of St 
George’s Cathedral. Another smaller cluster of high SSS values 
is located southwest of the focal point, in a park area between 
the Iziko South African Museum and the South African Na-
tional Gallery and South African Jewish Museum.
After subtracting the SSS scores from each corresponding seg-
ment’s normalized space syntax integration value, the SRP in-
dex was derived. Cape Town’s areas with the highest SRP values 
are located on the city’s western side; these are the segments 
that need immediate attention in urban renovation projects. 
Two discrete pockets of high SRP values (i.e., where the SSS 
values are moderate to low and the corresponding space syntax 
integration values are extremely high) are concentrated in the 
Bo-Kaap district. A similar, but less severe, pattern is also found 
in a small pocket of the southeast with high SRP values (Fig-
ure 7). Ultimately, the segments with the highest SRP values 
coincide with the most degraded regions of the study area.
Next, to calculate the SSIP, the SRP quantile with the highest 
priority (i.e., the first quantile) is reclassified into three classes 
by way of the natural breaks classification algorithm. The first 
Where to improve pedestrian streetscapes: Prioritizing and mapping street-level walkability interventions in Cape Town’s city centre
Urbani izziv, volume 33, no. 2, 2022
124
class indicates first-priority streets; these are the most critical 
segments in the network with the greatest potential for pe-
destrian infrastructure improvements. As expected, the SSIP 
is concentrated in the west of the city centre and in the Bo-
Kaap neighbourhood.
To better understand street conditions, Figure 8 shows three 
example segments: one for every SSIP category. Each street 
segment has a high space syntax integration value but low pe-
destrian suitability due to a relatively low TWS.
Case a (Bryant St) belongs to the first-priority category. Here, 
most of the streetscape-level variables are absent. Well-engi-
neered pedestrian crossings are missing, with buildings and 
pavement in poor condition. Pavement shading and buffers 
are non-existent, as are transit stops, active façades, bike lanes, 
parks, and public seating. These factors combine to produce a 
low TWS score. A similar pattern is found in Case b (Buiten-
gracht St), except that this segment exhibits good building 
maintenance and ample lighting, resulting in a slightly higher 
TWS score. Consequently, Case b is classified as a second-pri-
ority segment. Finally, Case c ( Jordaan St) has a slightly lower 
space syntax integration value than Cases a and b, but its low 
TWS value creates a gap between integration and suitability 
wide enough to classify this segment as third-priority as far as 
renovation projects are considered.
This case study identifies street segments of low pedestrian 
quality. After classification by priority categories, planning au-
thorities can implement urban renovation projects to enhance 
the quality of the streets in a logical order. Attention to some 
inadequate microscale variables can potentially increase TWS 
and SSS values, consequently decreasing SRP, without con-
suming excessive amounts of time or resources. For example, 
public seating, streetlights, and pavement buffers constitute 
small-scale interventions that are neither time- nor resource-in-
tensive. Streetscape audits provide detailed information about 
inadequate or missing walkability variables, allowing for tar-
geted alterations to the built environment to enhance the 
pedestrian experience. Improving the microscale features that 
directly affect pedestrians, such as pavements, crossings, and 
street equipment, has a significant positive impact on leisure 
walking and physical activity (Steinmetz-Wood et al., 2020). 
Thus, focusing on the street segments of highest priority can 
greatly improve Cape Town’s pedestrian mobility.
5 Conclusion
The methodology proposed in this study offers a novel way to 
prioritize and map street-level walkability interventions. This 
approach generates new insights regarding microscale walka-
bility issues in the Cape Town city centre by integrating nine-
teen spatial indicators for the pedestrian environment. For cit-
ies and countries where street-level data are either non-existent 
or sporadically collected, strengthening public space findings is 
vital for addressing complex sustainability issues and designing 
data-driven policies for healthier and more inclusive transpor-
tation systems and communities. For every street segment of 
the study area, the space syntax integration measure was com-
puted (the initial intent was to use OpenStreetMap data, but 
the originally produced network of pavements and crosswalks 
was much more comprehensive and topologically at the scale 
of interest). This helped map urban centralities in the study 
area and identify the most critical streets requiring immediate 
pedestrian interventions. Under this framework, planners and 
policymakers can better distribute limited investment resourc-
es to optimize improvements in pedestrian mobility. Similar 
geospatial concepts have profound applicability in local stra-
tegic plans and are ideal for old neighbourhoods that cannot 
alter their urban structure or struggle to preserve their local 
identity, while simultaneously attracting significant pedestri-
an activity. For example, this framework could be applied to 
walled towns like the Spanish city of Lugo or Manila’s Intra-
muros district, or to historical districts like the Plaka in Athens.
The findings of this research demonstrate that streets with the 
greatest need for immediate action are predominantly concen-
trated in the western parts of the city centre of Cape Town 
and particularly in the Bo-Kaap district, which lacks the nec-
essary infrastructure to support safe and comfortable pedes-
trian trips. Improving pedestrian facilities and comfort in the 
streets of this neighbourhood could increase pedestrian traffic 
and satisfaction, as well as overall quality of life. However, 
any potential redevelopment programme should consider the 
existing social pressures of the district, especially the impacts of 
racial segregation and gentrification processes (Kotze, 2013). 
Furthermore, redevelopment schemes should preserve special 
architectural features, such as colourful houses, mosques, and 
cobbled streets. When pedestrian interventions align with the 
socioeconomic features of the region, the assimilation process 
for the local population is easier (Forouhar & Forouhar, 2020). 
Such efforts help improve the urban environment and preserve 
local identity, which in this case is the Cape Malay Muslim 
culture (Kotze, 2013). Therefore, the proposed street-level pri-
orities could combat the inner-city inequalities of Cape Town’s 
central area, creating more opportunities for the local people, 
and leading to a more sustainable urban development.
Of course, the findings of this study have some limitations. 
First, because the microscale audit was made using online 
Google Street View imagery data, the outcomes were deter-
mined by the period of image capture, which in some cases 
differed. In rare instances, some segments lacked images al-
together, thus limiting the reliability of the auditing process. 
R.-M. STEFANIDIS , A. BARTZOKAS-TSIOMPRAS 
Urbani izziv, volume 33, no. 2, 2022
125
Second, regarding space syntax integration, the scores on the 
edges of the designated study area suffer from the edge effect 
because street segments and crosswalks outside the designated 
area were not considered. Finally, a significant limitation of 
this work is that walkability scores have not been correlated 
with local pedestrian counts or physical activity data. Future 
research could address these limitations by considering more 
environmental and social variables (e.g, cleanliness and secu-
rity) in walkability modelling or by analysing a larger, more 
heterogeneous study area. In addition, disseminating a survey 
about walking perceptions could help quantify the importance 
of urban design features in local mobility patterns, as well as 
the health and environmental benefits of a more pedestrian-
-friendly Cape Town.
Roussetos-Marios Stefanidis, School of Rural, Surveying and Geo-
informatics Engineering, National Technical University of Athens, 
Athens, Greece
e-mail: marios_stefanidis@hotmail.gr
Alexandros Bartzokas-Tsiompras, School of Rural, Surveying and 
Geoinformatics Engineering, National Technical University of Athens, 
Athens, Greece
e-mail: abartzok@mail.ntua.gr
Notes
[1] Available at https://figshare.com/s/838b7c93fb6f187b0880.
[2] Available at https://figshare.com/s/37780a5dbdc821dda717.
References
Adams, M. A., Ryan, S., Kerr, J., Sallis, J. F., Patrick, K., Frank, L. D., et al. 
(2009) Validation of the neighborhood environment walkability scale 
(NEWS) items using geographic information systems. Journal of Physical 
Activity & Health, 6(Suppl. 1), pp. 113–123. doi:10.1123/jpah.6.s1.s113
Bartzokas-Tsiompras, A. (2022) Utilizing OpenStreetMap data to meas-
ure and compare pedestrian street lengths in 992 cities around the 
world. European Journal of Geography, 13(2), 127–141.  
doi:10.48088/ejg.a.bar.13.2.127.138
Bartzokas-Tsiompras, A. & Bakogiannis, E. (2022) Quantifying and visual-
izing the 15-minute walkable city concept across Europe: A multicrite-
ria approach. Journal of Maps. doi:10.1080/17445647.2022.2141143
Bartzokas-Tsiompras, A. & Photis, Y. N. (2021) Microscale walkability 
modelling. The case of Athens city centre. International Journal of Sus-
tainable Development and Planning, 16(3), pp. 413–426.  
doi:10.18280/ijsdp.160302
Bartzokas-Tsiompras, A., Photis, Y. N., Tsagkis, P. & Panagiotopoulos, G. 
(2021) Microscale walkability indicators for fifty-nine European central 
urban areas: An open-access tabular dataset and a geospatial web-
based platform. Data in Brief, 36, 107048. doi:10.1016/j.dib.2021.107048
Bartzokas-Tsiompras, A., Tampouraki, E. M. & Photis, Y. N. (2020) Is 
walkability equally distributed among downtowners? Evaluating the 
pedestrian streetscapes of eight European capitals using a micro-scale 
audit approach. International Journal of Transport Development and 
Integration, 4(1), pp. 75–92. doi:10.2495/TDI-V4-N1-75-92
Boakye, K., Bovbjerg, M., Schuna, J., Branscum, A., Mat-Nasir, N., Baho-
nar, A., et al. (2023) Perceived built environment characteristics associ-
ated with walking and cycling across 355 communities in 21 countries. 
Cities, 132, 104102. doi:10.1016/j.cities.2022.104102
Boisjoly, G., Wasfi, R. & El-Geneidy, A. (2018) How much is enough? 
Assessing the influence of neighborhood walkability on undertaking 
10-minute walks. Journal of Transport and Land Use, 11(1), pp. 143–151. 
doi:10.5198/jtlu.2018.1059
Brownson, R. C., Hoehner, C. M., Brennan, L. K., Cook, R. A., Elliott, M. B. 
& McMullen, K. M. (2004) Reliability of 2 instruments for auditing the 
environment for physical activity. Journal of Physical Activity and Health, 
1(3), pp. 191–208. doi:10.1123/jpah.1.3.191
Cerin, E., Sallis, J. F., Salvo, D., Hinckson, E., Conway, T. L., Owen, N., et al. 
(2022) Determining thresholds for spatial urban design and transport 
features that support walking to create healthy and sustainable cities: 
Findings from the IPEN Adult study. The Lancet Global Health, 10(6), pp. 
895–906. doi:10.1016/S2214-109X(22)00068-7
Cervero, R. & Kockelman, K. (1997) Travel demand and the 3Ds: Densi-
ty, diversity, and design. Transportation Research Part D: Transport and 
Environment, 2(3), pp. 199–219. doi:10.1016/S1361-9209(97)00009-6
City of Cape Town (2022) Five-year integrated development plan. Availa-
ble at: https://resource.capetown.gov.za/documentcentre/Documents/
City%20strategies%2c%20plans%20and%20frameworks/IDP_2022-2027.
pdf (accessed 4 Oct. 2022).
Deloitte (2019) Deloitte City Mobility Index: Cape Town. Available at: 
https://www2.deloitte.com/content/dam/insights/us/articles/4331_
Deloitte-City-Mobility-Index/CapeTown_GlobalCityMobility_WEB.pdf 
(accessed 4 Oct. 2022).
Delso, J., Martín, B. & Ortega, E. (2018) A new procedure using network 
analysis and kernel density estimations to evaluate the effect of urban 
configurations on pedestrian mobility. The case study of Vitoria-Gasteiz. 
Journal of Transport Geography, 67, pp. 61–72.  
doi:10.1016/j.jtrangeo.2018.02.001
Delso, J., Martín, B., Ortega, E. & Otero, I. (2017) A model for assessing 
pedestrian corridors. Application to Vitoria-Gasteiz City (Spain). Sustain-
ability, 9(3), 434. doi:10.3390/su9030434
Delso, J., Martín, B., Ortega, E. & Van De Weghe, N. (2019) Integrating 
pedestrian-habitat models and network kernel density estimations 
to measure street pedestrian suitability. Sustainable Cities and Society, 
51(4), 101736. doi:10.1016/j.scs.2019.101736
D’Orso, G. & Migliore, M. (2020) A GIS-based method for evaluating the 
walkability of a pedestrian environment and prioritised investments. 
Journal of Transport Geography, 82(102555).  
doi:10.1016/j.jtrangeo.2019.102555
Fonseca, F., Ribeiro, P. J. G., Conticelli, E., Jabbari, M., Papageorgiou, G., 
Tondelli, S., et al. (2022) Built environment attributes and their influ-
ence on walkability. International Journal of Sustainable Transportation, 
16(7), pp. 1–40. doi:10.1080/15568318.2021.1914793
Forouhan, N. & Forouhan, A. (2020) Quality of life in neighbourhoods 
undergoing renewal: Evidence from Mashhad, Iran. Urbani izziv, 31(2), 
pp. 101–113. doi:10.5379/urbani-izziv-en-2020-31-02-004
Forsyth, A. (2015) What is a walkable place? The walkability debate 
in urban design. URBAN DESIGN International, 20(4), pp. 274–292. 
doi:10.1057/udi.2015.22
Frank, L. D., Sallis, J. F., Saelens, B. E., Leary, L., Cain, K., Conway, T. L., et 
al. (2010) The development of a walkability index: Application to the 
Neighborhood quality of life study. British Journal of Sports Medicine, 
44(13), pp. 924–933. doi:10.1136/bjsm.2009.058701
Where to improve pedestrian streetscapes: Prioritizing and mapping street-level walkability interventions in Cape Town’s city centre
Urbani izziv, volume 33, no. 2, 2022
126
Geremia, C. & Cain, K. (2015) Microscale audit of pedestrian streetscapes 
(MAPS), mini version. Training manual & picture guide. Available at: 
https://drjimsallis.org/Documents/Measures_documents/MAPS-Mini%20
Field%20Procedures%20%20Picture%20Guide_090815.pdf (accessed 4 
Oct. 2022).
Gibb, M. (2007) Cape Town, a secondary global city in a developing 
country. Environment and Planning C: Politics and Space, 25(4), pp. 
537–552. doi:10.1068/c6p
Hasan, M. M., Oh, J.-S. & Kwigizile, V. (2021) Exploring the trend of walk-
ability measures by applying hierarchical clustering technique. Journal 
of Transport & Health, 22, 101241. doi:10.1016/j.jth.2021.101241
Hillier, B., Burdett, R., Peponis, J. & Penn, A. (1987) Creating life: Or, does 
architecture determine anything? Architecture and Behaviour, 3(3), pp. 
233–250.
Hillier, B. & Hanson, J. (1984) The social logic of space. Cambridge, Cam-
bridge University Press. doi:10.1017/CBO9780511597237
Hillier, B., Penn, A., Hanson, J., Grajewski, T. & Xu, J. (1993) Natural 
movement: Or, configuration and attraction in urban pedestrian move-
ment. Environment and Planning B: Planning and Design, 20, pp. 29–66. 
doi:10.1068/b200029
Horn, A. (2018) The history of urban growth management in South 
Africa: Tracking the origin and current status of urban edge policies 
in three metropolitan municipalities. Planning Perspectives, 34(6), pp. 
959–977. doi:10.1080/02665433.2018.1503089
Knight, J., Weaver, R. & Jones, P. (2018) Walkable and resurgent for 
whom? The uneven geographies of walkability in Buffalo, NY. Applied 
Geography, 92, pp. 1–11. doi:10.1016/j.apgeog.2018.01.008
Koohsari, M. J., Oka, K., Owen, N. & Sugiyama, T. (2019) Natural move-
ment: A space syntax theory linking urban form and function with 
walking for transport. Health & Place, 58, 102072. doi:10.1016/j.health-
place.2019.01.002
Kotze, N. (2013) A community in trouble? The impact of gentrifica-
tion on the Bo-Kaap, Cape Town. Urbani izziv, 24(2), pp. 124–132. 
doi:10.5379/urbani-izziv-en-2013-24-02-004 
Lee, S. & Talen, E. (2014) Measuring walkability: A note on auditing 
methods. Journal of Urban Design, 19(3), pp. 368–388. doi:10.1080/1357
4809.2014.890040
Lloyd, C. D., Bhatti, S., McLennan, D., Noble, M. & Mans, G. (2021) Neigh-
bourhood change and spatial inequalities in Cape Town. The Geograph-
ical Journal, 187(4), pp. 315–330. doi:10.1111/geoj.12400
Lofti, S. & Koohsari, M. J. (2011) Neighborhood walkability in a city 
within a developing country. Journal of Urban Planning and Develop-
ment, 137(4), pp. 402–408. doi:10.1061/(ASCE)UP.1943-5444.0000085
Loo, B. P. Y. (2021) Walking towards a happy city. Journal of Transport 
Geography, 93, 103078. doi:10.1016/j.jtrangeo.2021.103078
Marshall, J. D., Brauer, M. & Frank, L. D. (2009) Healthy neighborhoods: 
Walkability and air pollution. Environmental Health Perspectives, 117(11), 
pp. 1752–1759. doi:10.1289/ehp.0900595
Odendaal, N. & McCann, A. (2016) Spatial planning in the Global South: 
Reflections on the Cape Town spatial development framework. Interna-
tional Development Planning Review, 38(4), pp. 405–423.  
doi:10.3828/idpr.2016.23
Opuni, F. F., Asiamah, N., Danquah, E., Ricky-Okine, C. K., Ocloo, E. C. 
& Quansah, F. (2022) The associations between pro-environment be-
haviours, sustainability knowingness, and neighbourhood walkability 
among residents of Accra Metro in Ghana: A cross-sectional analysis. 
Journal of Transport & Health, 25, 101375. doi:10.1016/j.jth.2022.101375
Ordor, U. & Michell, K. (2022) Exploring interdisciplinary cooperation in 
the relationship between urban management strategies, modes of pro-
duction and the production of urban space in Cape Town, South Africa. 
Urban Forum, 33(2), pp. 153–171. doi:10.1007/s12132-021-09439-3
R.-M. STEFANIDIS , A. BARTZOKAS-TSIOMPRAS 
Ortega, E., Martín, B., Lopez-Lambas, M. E. & Soria-Lara, J. A. (2021) Eval-
uating the impact of urban design scenarios on walking accessibility: 
The case of the Madrid “Centro” district. Sustainable Cities and Society, 
74, 103156. doi:10.1016/j.scs.2021.103156
Oyeyemi, A. L., Conway, T. L., Adedoyin, R. A., Akinroye, K. K., Aryeetey, 
R., Assah, F., et al. (2017) Construct validity of the neighborhood en-
vironment walkability scale for Africa. Medicine & Science in Sports & 
Exercise, 49(3), pp. 482–491. doi:10.1249/MSS.0000000000001131
Ramakreshnan, L., Aghamohammadi, N., Fong, C. S. & Sulaiman, N. M. 
(2021) A comprehensive bibliometrics of “walkability” research land-
scape: Visualization of the scientific progress and future prospects. 
Environmental Science and Pollution Research, 28, pp. 1357–1369. 
doi:10.1007/s11356-020-11305-x
Sallis, J. F., Cain, K. L., Conway, T. L., Gavand, K. A., Millstein, R. A., Ger-
emia, C. M., et al. (2015) Is your neighborhood designed to support 
physical activity? A brief streetscape audit tool. Preventing Chronic 
Disease, 12, 150098. doi:10.5888/pcd12.150098
Sallis, J. F., Cerin, E., Conway, T. L., Adams, M. A., Frank, L. D., Pratt, M., 
et al. (2016) Physical activity in relation to urban environments in 14 
cities worldwide: A cross-sectional study. The Lancet, 387(10034), pp. 
2207–2217. doi:10.1016/s0140-6736(15)01284-2
Scheba, A., Turok, I. & Visagie, J. (2021) Inequality and urban densi-
ty: Socio-economic drivers of uneven densification in Cape Town. 
Environment and Urbanization ASIA, 12(Suppl. 1), pp. 107–126. 
doi:10.1177/0975425321998026
Steinmetz-Wood, M., El-Geneidy, A. & Ross, N. A. (2020) Moving to 
policy-amenable options for built environment research: The role of 
micro-scale neighborhood environment in promoting walking. Health & 
Place, 66, 102462. doi:10.1016/j.healthplace.2020.102462
Su, S., Zhou, H., Xu, M., Ru, H., Wang, W. & Weng, M. (2019) Auditing 
street walkability and associated social inequalities for planning impli-
cations. Journal of Transport Geography, 74, pp. 62–76.  
doi:10.1016/j.jtrangeo.2018.11.003
Trichês Lucchesi, S., Larranaga, A. M., Bettella Cybis, H. B., Abreu e 
Silva, J. A. de & Arellana, J. A. (2020) Are people willing to pay more 
to live in a walking environment? A multigroup analysis of the impact 
of walkability on real estate values and their moderation effects in 
two Global South cities. Research in Transportation Economics, 100976. 
doi:10.1016/j.retrec.2020.100976
UN-Habitat (2013) Planning and design for sustainable urban mobility: 
Global report on human settlements 2013. Abingdon, UK, Routledge. 
doi:10.4324/9781315857152
UN-Habitat (2022) Walking and cycling in Africa: Evidence and good 
practice to inspire action.  Available at:  https://unhabitat.org/walking-
and-cycling-in-africa-evidence-and-good-practice-to-inspire-action 
(accessed 4 Oct. 2022).
Western, J. (2002) A divided city: Cape Town. Political Geography, 21(5), 
pp. 711–716. doi:10.1016/s0962-6298(02)00016-1
Wilkinson, P. (2000) City profile Cape Town. Cities, 17(3), pp. 195–
205.doi: 10.1016/S0264-2751(99)00059-1
Wood, A. (2022) Problematizing the concept of walkability in Johannes-
burg. Journal of Urban Affairs, pp. 1–15.  
doi:10.1080/07352166.2022.2043159
Wysling, L. & Purves, R. S. (2022) Where to improve cycling infrastruc-
ture? Assessing bicycle suitability and bikeability with open data in the 
city of Paris. Transportation Research Interdisciplinary Perspectives, 15, 
100648. doi:10.1016/j.trip.2022.100648