Smart Cities: The Role of Entrepreneurship for Urban Leftover
Spaces
Jasim Azhar
1a
and Sidra Ahmed Qureshi
2
1
Department of Architecture, King Fahd University of Minerals and Petroleum, Dhahran, Saudi Arabia
2
Department of Computing, National University of Science and Technology, Islamabad, Pakistan
Keywords: Smart Cities, Entrepreneurship, Urban Leftover Spaces.
Abstract: Smart City focuses on smarter solutions for the future to promote quality of life. Thus, the role of ICT
interventions, innovations and creativity are emphasised to sustain economic and urban growth. The literature
highlights business-led urban development is a major aspect of smart cities for entrepreneurship and identifies
their inter-dependent role in economically efficient solutions. A barrier would be unused urban spaces as an
inefficient allocation of resources. Entrepreneurship encourages innovation while smart cities adopt
interventions that provide opportunities and a supporting environment for entrepreneurial activities. This
paper explores the prospective relationship of using urban leftover spaces for entrepreneurial activities in
smart cities. The study evaluates and analyses key attributes of entrepreneurship as to develop smart spaces
for social sustainability.
1 INTRODUCTION
According to World Bank, urban population is
expected to double by year 2030. With this rise in
urbanization, globally researchers have started to talk
about time-relevant solutions. One such attempt is the
concept of smart cities, which has gained more
attention in recent times. Smart city has been defined
in various perspectives having multiple dimensions
by respective stakeholders. Overall, a smart city can
be defined as one that wisely uses natural and
economic resources enhancing the social and human
capital, employing tech-based solutions, to deliver
improved quality of life by dealing with public issues
and providing sustainable environmental solutions
(Fernandez-Anez, 2016). Urban leaders have argued
that smart cities have a lot more to do with “people”
and not just “technological advancements”. Whereas,
the aim is to make cities more sustainable achieving
improved quality of life with the smart and efficient
use of modern technology (Stimmel, 2015). Woetzel
et al., (2018) argues that smartness cannot be
achieved by just installing an Information and
Computer Technology (ICT) based infrastructure,
rather a purposeful use of technology has to be
ensured. To achieve this purposefulness, the role of
a
https://orcid.org/0000-0001-9047-7467
human capital and urban planning is repeatedly
emphasized for smart cities. The words “smart” and
“purposeful” here indicate the value and necessity of
human element that complements the employed
technologies for smart cities. Thus, a smart city can
assist and interest entrepreneurs, not just a digital city
with high technological advancements. In fact,
research has highlighted how digital cities differ from
smart cities, focusing on the role of human capital for
latter (Kummitha, 2019; Neirotti et al., 2014).
Various researchers have divided broader objectives
of a smart city into several components, such as smart
governance, smart living, smart economy and smart
environment (Giffinger and Gudrun, 2010; Lombardi
et al., 2012). Yin et al. (2015) has defined a domain
for smart cities that focuses at achieving growth for
governments, citizens, businesses and sustainable
environment. The importance of human capital and
urban planning is highlighted for smart cities.
Entrepreneurship encouragement is seen as a key
attribute of a smart city to fuel innovation, which can
lead to greater use of technology. Besides, Kummitha
(2019) has highlighted the lack of attention in prior
research on the relationship and potential of
entrepreneurship to urban planning and as how it can
be exploited.
Azhar, J. and Qureshi, S.
Smart Cities: The Role of Entrepreneurship for Urban Leftover Spaces.
DOI: 10.5220/0011104500003203
In Proceedings of the 11th International Conference on Smart Cities and Green ICT Systems (SMARTGREENS 2022), pages 165-172
ISBN: 978-989-758-572-2; ISSN: 2184-4968
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
165
City characteristics are defined by urban
development (Snieska & Zykiene, 2015). Urban
design and planning concentrate not only at
operational, structural planning and land usage but
also on designing the physical features of the city to
establish a relationship between the built environment
and people (Shahreen & Voghera, 2019). Between
stages of formal development, there are often spaces
left unused, with unassigned functions, such spaces
are generally termed as loose, vacant or leftover and
are often perceived negatively (Azhar & Gjerde,
2016). These are indicative of inefficient usage of the
physical infrastructure in a city, posing a socio-
economic threat. Depending on the nature of such
spaces, they have been classified into different
categories, one of these leftover spaces after planning
phase. Such leftover spaces emerge as a consequence
of planning practices that leave gaps between urban
fabrics. As a result, prior research has highlighted the
potential of urban leftover private and public (semi)
spaces which further raise questions to ensure their
optimal use to minimise their potential negative threat
due to staying idle. This paper attempts to fill this gap
by focusing on urban planning and design as a tool
for facilitating entrepreneurial activities in smart
cities. It not only suggests a path for exploiting the
relationship between the two, but also helps in
stepping towards the goals of smart cities. This study
will specifically focus on the goal to make businesses
prosperous by creating enabling environment for
entrepreneurs. There is an extant literature on smart
cities, but it evidently leaves a void for research to
explore more on how the human element in smart
cities can further be utilised. Thus, this exploratory
study attempts to explore the prospective relationship
of urban leftover spaces and entrepreneurial activities
for smart usage.
The paper begins by explaining a step-by-step
method on how the study aims are achieved and
followed by a comprehensive review of smart city
definitions. To establish context, first it highlights the
role of entrepreneurship for smart cities, the restricted
role of ICT to facilitate entrepreneurship and literary
evidence on urban planning and design as a tool for
developing smarter city. This is followed by
highlighting the need for optimal utilization of a
city’s built environment and leftover spaces in smart
cities. In light of all these points, the paper
consolidates the idea and presents how “smarter
urban entrepreneurship” can be facilitated in smarter
economies.
1.1 Research Methods
The study is elaborated in the following steps as:
Step 1 – Identifying the Aim of Research: the aim
for this research is to propose the utilization of urban
leftover spaces for entrepreneurial activities in smart
cities.
Step 2 – Review of Extensive Literature: search
engines are used as a starting point to search articles,
several keywords related to the subject i.e., need for
smart cities, resource management, entrepreneurship,
economic growth and urban leftover spaces. After
reviewing the abstracts/introductions/conclusions,
relevant articles were shortlisted.
Step 3 – Identifying the Gap: there is sound
literature on urbanism, entrepreneurship and how
much entrepreneurship is stressed upon in relation to
smart cities. However, there is a limited research on
how this relationship can be exploited. As far as the
tools of achieving smart city objectives are
concerned, a majority of the emphasis is laid on ICT
interventions, little focus is laid on the role of urban
planning and human capital for the purpose. Research
also establishes that even though entrepreneurship
has key importance in smart cities, use of modern
technology alone has a restricted part to play for it.
This leaves behind ample space to explore the role of
urban planning and design to encourage or facilitate
entrepreneurship in smart cities.
Step 4 – Filling the Gap: this study focuses on the
potential of urban planning and design as a
mechanism to fill the gap identified in Step 3 by
proposing the smart use of urban leftover spaces for
entrepreneurial activities in future cities.
2 REVIEW OF EXISITING
LITERATURE
The section briefly examines the existing literature
and relationship of smart cities, entrepreneurship and
urban leftover spaces.
2.1 Defining Smart Cities
There is no conclusive definition of smart cities,
however, prior research shows researchers have
defined smart cities from various perspectives. The
definitions proposed by researchers have evolved
over time and these definitions vary depending on
fields in which the researcher is involved in (Wenge
et al., 2014). Researchers (Giffinger & Gudrun, 2010
and Lombardi et al., 2012) comprehensively
SMARTGREENS 2022 - 11th International Conference on Smart Cities and Green ICT Systems
166
identified six characteristics of a smart city. The six
characteristics are related to smart economy, smart
human capital, smart governance, smart mobility,
smart environment, and smart living. Here, the
smartness implies an ambition to move toward an
improved efficient urban development by wisely
combining the existing planning tools. The term
“smart” is referred to smarter planning, industry,
inhabitants and use of technology.
2.2 Significance of Entrepreneurship
Although there is widespread consensus that ICT
adoption would assist cities in becoming smart cities,
there is no model to adopt or a smart city which has
completely established as such. Yin et al. (2015)
categorises the definition of smart cities into four
perspectives i.e., technical infrastructure, application
domain, system integration and data processing.
Whereas, the application aspect focuses on providing
sustainable solutions for governments, businesses,
citizens, and environment. In making businesses
more prosperous, one of the key sub-domains is to
facilitate and promote entrepreneurship, with better
logistics and encourage innovation. Problems of
current era require time-based solutions, therefore,
the role of innovation as a tool for smarter solutions
has gained more focus (Dirks et al., 2010).
Caragliu et al., (2011) highlights six
characteristics of utilizing networked infrastructure to
achieve improved economic growth and urban
development, business led urban development, social
inclusion of urban growth, the use of technology and
innovation for long run growth, importance of dealing
with social and relational issues and finally, achieving
social and environmental sustainability. Kummitha &
Crutzen (2019) argues that key stake holders need to
be brought together to achieve inclusiveness in smart
cities. This can be done through (a) the government
that has to formulate an effective plan to distribute
resources and form market policies, (b) corporate
entrepreneurship can be enhanced by providing
technological expertise and knowledge, (c) Small and
Medium Enterprises (SMEs) and social enterprises
can be created through small-scale developmental
interventions, and lastly, (d) citizens not only have to
smart but an active participation for entrepreneurial
activities is needed to address local problems with
innovative but sustainable strategies. According to
(Luke et al., 2007), the entrepreneurial activities can
take place at an individual and organisational level.
The individual entrepreneurs implement certain
activities which can be innovative, and grows with
time but involves risk in case of SMEs. However, in
the organizational level, the entrepreneurship can be
viewed from two perspectives – individual business
entities within an organization or ‘intrapreneurship’
and the organization as a whole or ‘corporate
entrepreneurship’. Business-led urban development
focuses on providing a suitable enabling environment
for businesses. Cities with a higher level of business
activity show better socio-economic performance.
Under the broader aim of smart cities to achieve
sustainable growth, one of key objectives is to
achieve it through promoting innovation and
facilitating entrepreneurship (Bjørner, 2021).
2.3 Restricted Use of ICT for
Entrepreneurship
Neirotti et al., (2014) classifies smart cities into hard
domains and soft domains, this classification is based
on the importance of ICT (see Table 1). Hard domains
are the ones for which sustainable solutions rely
significantly on ICT systems, along with urban
planning and policy interventions, also includes
transport, natural resources, buildings, environment,
and energy grids. Soft domains are the ones for which
ICT system has a limited part to play and includes
areas such as education, culture, policies that foster
entrepreneurship, innovation and social inclusion, as
well as communication between local public
administrations and the citizens (e-government).
Table 1: Neirotti et al. (2014)’s characterization of smart
city domains based upon role of ICT.
Hard Domains Soft Domains
Ener
gy
g
rids Education and culture
Public lighting, natural
resources and water
management
Entrepreneurship,
innovation, social
inclusion and welfare
Waste Management Public administration
and
(
e-
)
g
overnment
Environment Econom
y
Transport, logistics and
mobilit
y
Office and residential
b
uildings
Healthcare
Public security
2.4 Urban Planning as a Tool for
Encouraging Entrepreneurial
Activities
Kourtit and Nijkamp (2012) highlights the
importance of smart urban planning and defines as a
promising mix of human, social and entrepreneurial
Smart Cities: The Role of Entrepreneurship for Urban Leftover Spaces
167
capital. This structure ought to be supported by
adequate government interventions and citizens who
look forward to innovation driven growth. The urban
theory put forward by International Business
Machines (IBM) explains that the smart city concept
stands on three pillars i.e., people, management, and
infrastructure. ‘People’ is categorised to provide
human services in education, social programs and
healthcare for citizens. Management and planning
services are further divided into urban planning and
smarter buildings, public safety, and governance
(Söderström et al., 2014). To sum up, smart cities are
distinct from digital cities, the role of ICT is to
develop a city’s digital nervous system that obtains
and manages data centrally. Research highlights the
importance of human capital and planning, to ensure
“smart” use of ICT for transforming cities (Neirotti et
al., 2014). Caragliu et al., (2011) argue that a city can
be characterized as smart, where efficient allocation
of social and human capital along with use of ICT
ensures sustainable solutions for the future having
government’s monitoring role. Overall, smart cities’
space can be defined as using ICT interventions,
policy mediation and urban planning procedures for
wiser management of resources to attain sustainable
socio-economic solutions.
Figure 1: Detailed outlook of Smart Cities.
Above figure 1 summarizes the definition of
smart cities, where the broader aim of a smart city is
attaining higher and sustainable growth. The focus is
to ensure all major stakeholders of a city i.e., the
government, citizens, businesses, and environment
are better off in the future. In literature, the
connection that is made between these three, from a
smart city perspective is, to focus on the use of
modern technologies and innovation to encourage
entrepreneurship for steady growth, having citizens
who open-mindedly accept and adapt to it. This setup
further needs a government’s contributory and
monitoring role to be played efficiently through urban
planning and policy interventions. The growth in
context of a smart city thus must be smart,
sustainable, and inclusive (Arroub et al., 2016).
3 EFFICIENT UTILIZATION OF
PHYSICAL INFRASTRUCTURE
Smart cities claim to provide solutions for emerging
city problems, especially the increased pressure on
environment and economic infrastructure. This
suggests sustainable solutions imply minimum
wastage of resources (Bjørner, 2021) and efficient use
of abandoned land. Stimmel (2015) introduces the
concept of smart city that focuses on most efficient
utilization and management of resources, while
ensuring minimum wastage. As it is expensive to
build smart cities (Ejaz and Anpalagan, 2019), the
analysis suggested that the emphasis on utilization of
resources in the most efficient ways can be a part of
the core vision of smart cities. A key component of
smart cities is a well-integrated ICT infrastructure for
which urban planning and urban design play an
important role. Urban planning for smart cities
suggests little about green urban spaces and
consequently how environmental sustainability will
be achieved (Anguluri & Narayanan, 2017). As
discussed earlier, along with an integrated ICT
structure, a smart city also needs adequate
governance and inhabitants with open and growth
mindset, but relatively little focus is laid on
governance and change in mindset of human resource
(Tay et al., 2018). Chourabi et al., (2012) discusses
the role of ICT for smart cities but pinpoints the need
to explore the importance of organization and
management of smart cities. The limited research on
perceived challenges associated with smart cities
highlight the technical issues, economic costs, and
threats to natural environment. Even though smart
cities promise to put forward sustainable solutions,
but the question stands, are they really sustainable?
The beautification of built environment at the cost of
deteriorating natural environment may not lead to the
desired results of improving quality of life for people.
Where broad research can be found on the
architecture of smart cities, little is known about the
geography and spatial planning for them (Yigitcanlar,
2015).
Smart cities promise efficient utilisation of the
physical infrastructure, encouraging citizen
participation, learning to innovate and adapt, hence
responding to changing environments and situations
swiftly (Jaššo & Petríková, 2019). This implies it is
important to ensure urban spaces are most efficiently
SMARTGREENS 2022 - 11th International Conference on Smart Cities and Green ICT Systems
168
utilized in a smart city. The study urges urban leaders
to concentrate especially on such spaces which
emerge amid planning and design of city, are
obsolete, having no use. This is where the concept of
place branding comes in which entails assigning some
significance to a place. Strategic branding of a place
can lead to generation of its economic value and
contribution to the city (Bašová & Štefancová, 2017).
3.1 Connecting the Dots
The definition of smart cities can be divided into two
components: their objectives and the tools that can be
employed to attain smart city goals (see figure 1).
Broadly discussing, the objective of a smart city is to
enhance the quality of life by providing smarter
answers for the future and attaining efficient and
sustainable social, economic and environmental
solutions. Specifically, the aim is to take advantage of
technology to help all major stakeholders of an
economy, i.e., government, businesses, and citizens
cope better with the challenges of tomorrow.
3.1.1 Smarter Entrepreneurship
It is important to understand that the concept of smart
city is not only confined to the existence of a well-
integrated ICT infrastructure, rather the planning and
use of this infrastructure is also important for
enabling smarter solutions. Thus, “smart” in smart
cities is an indicative of use of technology to provide
better solutions for futuristic problems, it is important
to establish that having a well-integrated ICT system
is a part of the smart city concept and not the entire
concept. Innovation and entrepreneurship are the key
contributors to discovery of sustainable solutions.
Most of the literature lays great emphasis on both to
develop smart cities. Smart cities and
entrepreneurship in fact have a bi-directional
relationship, where each complements the other. The
aim of smart cities provides better, time relevant
solutions for tomorrow through efficient utilization of
ICT that needs to be backed by innovation and
entrepreneurship. In return, establishment of smarter
cities promises to provide an enabling environment
for entrepreneurs. In a smart city, whether it is social
inclusion, social and environmental sustainability,
business-led development, use of ICT, high-tech
industries or relational capital, all contribute to
encouraging entrepreneurship (Yin et al., 2015;
Neirotti et al., 2014; Dirks et al., 2010; Hollands,
2008; Richter et al., 2015).
Figure 2: The bi-directional relationship between smart
cities and entrepreneurship established in literature and
proposed by this study (in blue color).
Henderson & Weiler (2010) put forward
empirical evidence validating that the advantages of
entrepreneurship in urban economies are more
eminent. Among a few major reasons for this are low
transaction costs and bigger markets in urbanized
cities. Greater number of skilled individuals in cities
means a greater chance of entrepreneurial activities.
The role of human capital is highlighted for urban
development, as entrepreneurship attracts skilled
labour by creating greater labour demand, this is why
higher skill levels could lead to more growth in cities
(Caragliu et al., 2011; Berry & Glaeser, 2005). As
discussed earlier, a distinction can be made of the
things that rely heavily on ICT and those that rely on
ICT to a much lesser extent. Among the latter are
innovation and entrepreneurship, which even though,
hold great importance in the futuristic problem-
solving approach, have limited role of ICT to
influence from. Figure 2 illustrates the relationship
established in literature of smart cities and
entrepreneurship. However, the opportunity for
finding a relationship can be exploited.
3.1.2 Smarter Usage as Tactical Approach
In cities, the tactical urban movement can be seen as
a smart solution for individual entrepreneurs, wherein
people improve urban design and bringing about a
positive change in their surroundings by providing
certain functions, culminating in cities
to become even more sustainable (Planning Tank,
2016). Minor improvements to vacant urban spaces
might be the first step in this direction. This method,
which would be low risk but potentially highly
rewarding, becomes a deliberate or phased strategy to
instigate change by offering local ideas for local
planning challenges, short-term commitment, and
realistic outcomes, and it could become a deliberate
or phased approach to instigate transformation by
offering local ideas for local planning challenges,
Smart Cities: The Role of Entrepreneurship for Urban Leftover Spaces
169
short-term commitment, and realistic outcomes
(Pfeifer, 2013). The tactical approach provides low-
cost, adaptable processes that transform the cityscape
into such an urban laboratory where people could test
out their differing ideas. Making gradual changes in
voids could result in a new opportunity for the
entrepreneurs and planners to explore and experiment
with multiple ideas. There are primarily two types of
this approach. Temporary interventions are lighter,
quicker, and less expensive, but they are nevertheless
effective tool for creating better urban settings
(Turner, 2013). Most of these initiatives are small in
scale, such as impromptu seating along roadways and
tiny parks, but some have converted whole parking
lots and roads into temporary green spaces, offering
users a glimpse of what is possible (Voigt, 2015).
These bottom-up approach may appear to become a
coordination issue for municipalities and other
agencies, but they could potentially coincide with
long-term planned policies and last at least a year.
The 'planned' approach, on the other hand,
involves strategically modifying spaces and
concentrates on initiatives such as infill development
and drafting of guidelines. Permanent projects, have
far greater expenditures and require a longer and
more sophisticated approach. One of the most
difficult obstacles that the strategically planned
method faces is actively engaging the community
(Voigt, 2015). The idea is primarily a collaborative
one, in which local residents must discover
possibilities for tiny moves or projects rather than
introducing fundamentally new forms of
transformation on a wider scale. Letting space, City
Lab, Street-Plans New York, Do-It-Yourself
urbanism, and City repair are all projects that
highlight the importance of empty spaces by creating
spaces that are designed to be used by the public.
Thus, the urban landscape should not be considered
as something static, but as something vital with the
need to achieve a coherent design solution at each
change point that is considered beneficial for the
community and generates economy.
Bjerke (2010) discusses the connection between
spaces and entrepreneurship, and also identifies three
types of entrepreneurial situations and their
respective spatial needs. There is entrepreneurship
going in market, institutions and public. Azhar et al.
(2020) highlights a potential of public and private
urban leftover spaces that may pose a threat to the
social, spatial and environmental setting of a city and
identifies several positive uses of them by classifying
them into different types. Leftover spaces are defined
and seen as abandoned spaces, which have no
particular use or functionality. The threat they pose
and the potential they hold may vary for each. The
existence of public and private leftover spaces in
cities would indicate inefficient spatial management.
Specific to the context of smart cities, leftover spaces
can be seen as spaces of potential to contribute
positively due to limited land in cities. This proposal
of utilising such obsolete spaces present in a smart
city would yield the following benefits:
1) Better resource management: Categorizing
leftover spaces as a resource in smart cities, their
positive utilization through design interventions
would mean lesser wastage and more efficient
resource management.
2) Cost-effective solution: As the solutions smart
cities offers are critiqued to be expensive, utilisation
of leftover spaces could provide much cost-effective
solution. It could, in-fact become a source of income
generation for whoever holds property rights to the
spaces.
3) Support entrepreneurship: Entrepreneurs need
space to operate, availability of leftover spaces for
them could provide them a lost-cost space to operate
in. Further research needs to done on what type of
leftover spaces would be preferred for supporting
entrepreneurial activities.
The proposal laid forward by this study not only
directs a phenomenal way of utilising wasted
resources in smart cities to attain their objectives but
also paves the way for a whole new area of research
related to smart usage of urban leftover spaces. Some
of the eminent research agendas related to this are
given below:
1. First, the entrepreneurs and their preferences
towards the features and specific types of
leftover spaces need to be tapped. These
preferences are related to design transformation
of the vacant spaces to make them useful for
entrepreneurial activites.
2. Second, considering smart cities and what they
aim to achieve, the uses of smart urban vacant
spaces can further be explored in multiple
dimensions. This will be especially insightful if
the leftover spaces are categorized into different
types according to their potential usage for
entrepreneurship.
3. Needs of entrepreneurial spaces and the
perception of urban leftover spaces needs to be
further exploited.
SMARTGREENS 2022 - 11th International Conference on Smart Cities and Green ICT Systems
170
4 CONCLUSION
Smart city is a concept that has gained significant
attention by researchers in recent times, however the
focus as majorly been on the ICT side. The role of
urban planning has been emphasized and the need to
dig deeper into exploring potential of urban planning
and its contribution to smart cities has been raised.
This paper reviews literature on smart cities
particularly highlighting the objective of smart cities
to provide improved quality of life by employing
efficient and sustainable means. In addition, it focuses
on the need to utilise resources, particularly the
physical infrastructure as an urban planning strategy
for smart cities. Among the characteristics of smart
cities is to encourage entrepreneurship and
innovation, this study suggests the use of obsolete
urban spaces in efficient ways for entrepreneurship.
This will not only ensure proper utilization of smart
urban leftover spaces but will also facilitate
entrepreneurial activities. They paper concludes on
highlighting the significance of urban planning and
urban design as contributors for achieving smart city
objectives and paves way for future research in the
area.
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