Research Challenges of Open Data as a Service for Smart Cities
Leonard Walletzk
´
y
1
, Franti
ˇ
ska Romanovsk
´
a
1
, Angeliki Maria Toli
3
and Mouzhi Ge
1,2
1
Faculty of Informatics, Masaryk University, Brno, Czech Republic
2
Institute of Computer Science, Masaryk University, Brno, Czech Republic
3
Bartlett School of Construction and Project Management, University College London, London, U.K.
Keywords:
Open Data, Data Life Cycle, Open Data as a Service.
Abstract:
The open data are considered to be an important building block of Smart City services. Based on the data
availability in the cities, companies are building innovative smart services to facilitate the city development.
However, most of the practitioners are focusing only on the open data usage but paying little attention to the
processes related to the data publication. Thus, there is a lack of understanding the whole process of open data
life cycle such as before the data can be open, when they are published and when they need to be archived.
Those phases in the open data life cycle are critical for assuring the data accuracy, availability and relevance
because the data are analysed, changed, anatomized or generally processed during the whole life cycle. This
also creates a set of research challenges for open data. Therefore, in the context of smart cities, this paper
proposes to consider Open Data as a Service and identifies the research challenges along with the open data
life cycle.
1 INTRODUCTION
The term smart city gained popularity in the early
2010s to demonstrate how technological advances
along with data that have the significant potential
to improve city planning and management (Step
´
anek
et al., 2017). There is a variety of data sources that can
be used in smart city services. For example, smart city
projects regularly collect data via Internet of Things
(IoT) platforms, where the collected data can further
be published as open data. Thus, while the develop-
ment of smart cities increases the open data, open data
also facilitate the smart city applications. In smart
cities, open data can be defined as data that are avail-
able and accessible for use and reproduction by any
party (Lindman et al., 2013). Those open data can
bring various advantages to smart cities, for example,
governmental open data will promote transparency
and accountability (McDermott, 2010), improve the
decision making capacity and create innovation op-
portunities for both governmental and private actors.
Moreover, open data can also improve the provision
of public services and lead to the improvement of cit-
izens’ quality of life (Pereira et al., 2017). Due to high
utility of open data, open data initiatives in smart cit-
ies are considered to have a significant impact on the
domains of governance, economy and transport and
mobility (Ojo et al., 2015b). However, literature sug-
gests that the actual effect of open data on ongoing
smart city projects has been elusive to assess. For ex-
ample, the smart city program of Rio de Janeiro has
been slow in achieving its goals regarding the open
data (Angelidou, 2017).
Open data can help to increase the positive im-
age and motivate the creation of the innovative ap-
plications. For example, in the Brno city (second
largest city in Czech Republic with 380.000 inhab-
itants), open data show that total length of the roads
of bikers was around 63km in 2018 and Brno is an-
nouncing that is having about 136km of the roads for
bikers in 2019 open city data. This helps the city to
build an image that the city is planning more cycling
lanes and thus more and more applications are de-
veloped to support bikers in Brno in 2020. From this
real-world scenario, it can be seen that open data can
help citizens and organizations to understand the city
and build the smart city together. With the increas-
ing importance of open data, most organizations are
considering the open data only as a data source and
usually ignore how the life cycle of the open data and
how to help to improve the healthy life cycle of open
data. Therefore, this paper views the open data as a
service and discusses how to create Open Data as a
Service in smart cities.
468
Walletzký, L., Romanovská, F., Toli, A. and Ge, M.
Research Challenges of Open Data as a Service for Smart Cities.
DOI: 10.5220/0009578604680472
In Proceedings of the 10th International Conference on Cloud Computing and Services Science (CLOSER 2020), pages 468-472
ISBN: 978-989-758-424-4
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
The rest of the paper is organized as follows, Sec-
tion 2 reviews the open data and its life cycle. Then
from the service perspective, Section 3 discusses the
open data process, related service and value propos-
itions. Section 4 proposes a set of research chal-
lenges of Open Data as a Service for Smart Cities,
finally, section 5 concludes the paper and outlines fu-
ture works.
2 SERVICE VIEW TO OPEN DATA
In order to understand the relations between smart cit-
ies and open data, the British Standards Institution
envisions smart city as a city that is citizen-centred,
collaborative, digital and defined by open data (BSI,
2014). Open data can be defined as data and con-
tent that can be used, modified and shared with no re-
strictions, by anyone and for any scope (ODI, 2017).
Data can be characterized as open when they meet
the following criteria: accessible -thus typically pub-
lished on the web- , provided in a machine-readable
format and under a license that allows to access, use
and share them (Transport Systems Catapult, 2017).
Open data initiatives support the smart city objectives
and are considered to have a significant impact on the
domains of governance, economy and transport and
mobility (Ojo et al., 2015a). They can be viewed as
a way to restore the separation between government
and civic society by stimulating public organizations
to act as a more open system (Janssen et al., 2012).
Smart city projects regularly collect data via IoT
platforms, which are frequently made open (Ahlgren
et al., 2016). These data are often sourced by govern-
mental bodies from citizens through sensors, kiosks,
meters, smart phones and smart appliances (Harrison
et al., 2010) and are made available by numerous
cities through open data portals, based on the inter-
net and connected to data hubs (Caird and Hallett,
2019). An example of such cities is London, UK.
London offers a number of open data sources such
as the London Datastore, Transport for London (TfL)
and data.gov.uk, the main themes of which are: demo-
graphics, employment and skills, environment, trans-
parency, housing, health, transport, business and eco-
nomy and education (Ghahremanlou et al., 2019).
Literature suggests that open data operate in smart
city ecosystems (Hall et al., 2012; Poikola et al.,
2011; Zuiderwijk et al., 2014), characterized by in-
terdependencies between issues (Zuiderwijk et al.,
2014). Such issues may be related to pre-existing net-
works, power and information asymmetries and vari-
ance of training and capacity (Hall et al., 2012).
(Zuiderwijk et al., 2014) present an open government
data scenario to demonstrate how open data ecosys-
tems operate, which correlates to data lifecycle man-
agement. This demonstrates how governmental or-
ganizations can create or collect, subsequently store
and curate, then verify and remove sensitive inform-
ation from the data that are then made available to
users. These data are frequently made available, via
data integrating actors referred to as infomediaries.
Subsequently, users can return to the governmental
organizations with further data requests or to discuss
the datasets.
According to (Zuiderwijk et al., 2012) the process
of opening the data can be split up into five steps. The
first two steps are focusing on the responsibilities of a
city/organization, such as creating the data and open-
ing the data. The next two steps focus on users (find-
ing the open data and using them) and the last step
closes the cycle on a border between user and organ-
ization in which they discuss and provide feedback on
the open data (see Figure 1). This describes the open
data as an ongoing process with a constant need for
improvement of the service they provide for the users;
however, it does not discuss closing the open data.
By that is meant the withdrawal of the published
data due to various reasons, e.g., change in legisla-
tion. Only one (Demchenko et al., 2013) of the ten
models describing the data life cycle in (Charalabidis
et al., 2018) mentions a step after sharing/publishing
the data.
3 OPEN DATA LIFE CYCLE AND
VALUE PROPOSITION
From the perspective of Open Data as a Service, we
propose to simplify the open data life cycle into three
stages: before open data, open data and after open
data. although it is important to describe the open
data in each of the three stages, we found that most
literature is focused on the open data application and
lacking to pay attention to before open data and after
open data stage.
From the perspective of Service dominant logic
(Lusch and Vargo, 2014), we conduct our analysis
from product view to service view in order to identify
the value of the data and their usefulness to their
users. The important characteristic of open data ser-
vice is the value proposition. The value proposition
refers to the potential value the customer can obtain
by usage of particular service. Therefore, considering
the three basic steps of open data life cycle, we can
investigate the value proposition that is designed for
Open Data as a Service.
Before Open Data: value proposition is based on
Research Challenges of Open Data as a Service for Smart Cities
469
Figure 1: Open data interactions between organizations and users (Zuiderwijk et al., 2012).
the possibility and ability of the data to be trans-
formed into Open Data.
Open Data: value proposition is focused on the
ability of data to create value, for example, to be an in-
put to some innovative application or provide relevant
information to stakeholders.
After Open Data: value proposition is about sav-
ing historical values and being able to provide retro-
spective analyses.
It can be seen that each part of open data life
cycle has different value proposition, also focused
to the different stakeholders. Therefore, the service of
open data, its features and aspects, must be analysed
separately, because the consequences and results are
different in each phase of life cycle.
4 OPEN DATA AS A SERVICE
According to (Zuiderwijk et al., 2014), the following
aspects of open data has been identified:
• Availability and Access: collecting data; deciding
what to collect, when and by whom it should be
collected; not opening the data
• Find Ability: the ability of data and metadata to
be easily found by users, as well as easily browsed
and searched
• Usability: Ensuring the correctness of the data
and trustworthiness of the source. The right
amount of services to use the data.
• Understand Ability: The ability of the data to be
understood by users (e.g., visualisation) suppor-
ted by good and user friendly API. Knowledge of
users to use the data.
• Quality: Reliable and accurate data.
• Linking and Combining Data: The ability of the
data to be linked and combined.
• Comparability and Compatibility: Unified and
standardized format of data for easier comparison.
Uniform policy for publishing.
• Metadata: Commonly agreed metadata with re-
cognizable structure, their extent and provision.
From our applied research results, based on cooper-
ation with public authorities and city representatives,
we identified three critical aspects:
Security and Privacy. This aspects is mostly underes-
timated by municipalities and stakeholders. This is a
very complex problem, combining issues of data pri-
vacy, authorization and availability. As the data are
public available, the data privacy and data anonymiz-
ation become very important to protect the citizen’s
personal information (Mbarek et al., 2020).
Quality. Data quality research can be traced back to
two decades ago (Ge and Helfert, 2006; Helfert et al.,
2009b), in the context of open data, while the open
data facilitate to share the information and knowledge
among the Internet peers, it also suffers from a large
variety of the data quality problems (Helfert et al.,
2009a; Ge et al., 2011). Consider the Wikipedia as
an example, (Lewoniewski et al., 2017) report that
for the same fact number such population of certain
city, different language versions of the same Wikipe-
dia articles can be different. Further, the contents for
the same topic in different language versions also vary
significantly.
CLOSER 2020 - 10th International Conference on Cloud Computing and Services Science
470
Quantity or Volume. Not only data quality is import-
ant, but also data quantity plays a critical role. For
the most of the people from municipalities, open data
are represented only in the form of tables (more spe-
cifically in csv format). However there are more con-
cerns, for example, we can have a data streams where
only part of the data is relevant, or we can have the
Big Data, where only some of data are important for
decision-making (Ge et al., 2018). To further refine
this research issue, it is also hard to identify which
part of Big Data is important for a specific applica-
tion or use case. Compared to other Vs of Big Data,
the volume of big open data should be prioritized.
It can be seen that each aspect can play an im-
portant role in the life cycle of the open data. Along
the open data life cycle, data access and usability may
vary. Before open data, the critical aspect is to cre-
ate and process open data, we need to assure to ob-
tain the right data in the right time. When the data is
opened, it is important to concern the usability for the
city and third-party organizations. It is representing
the feature to be used to create a value for the users of
applications, linked to open data. After opening the
data, the related questions can be that what data can
be stored and what data can be deleted? If they are
stored, for how long they should be available?
We found that the research of open data for smart
cities can be done in the cooperation with municipalit-
ies in the different stages of Open Data development.
If the research would be done in the municipality of
the same level, some of critical aspects of problems
can be missed or ignored. If this analysis can be done,
it will clarify the process of Open Data publication,
help the developers of Open Data platforms to design
their products more precisely and feed the data ser-
vice need of all relevant stakeholders during whole
data life cycle.
5 CONCLUSION
In this position paper, we have proposed to underpin
the importance of the open data life cycle and con-
sider open data as a service. We have revisited how
the open data are generated and used along its life
cycle in smart cities. From the service perspective,
we have investigated the value proposition of the open
data in the phase of before open data, open data and
after open data. Based on studying the open data from
service perspective, we have reviewed and identified
as a set of research issues for open data as a service,
where we especially propose to focus on three critical
aspects for open data in smart cities: security, quality
and quantity. Each aspects have been discussed to fa-
cilitate the future research of open data in smart cities,
and also help to develop the concept of Open Data as
a Service for smart cities.
ACKNOWLEDGEMENTS
The work is supported from European Regional De-
velopment Fund Project CERIT Scientific Cloud (No.
CZ.02.1.01/0.0/0.0/16 013/0001802).
REFERENCES
Ahlgren, B., Hidell, M., and Ngai, E. (2016). Internet of
things for smart cities: Interoperability and open data.
IEEE Internet Computing, IEEE, 20(6):52–56.
Angelidou, M. (2017). Angelidou, m. (2017), ”smart
city planning and development shortcomings”, tema.
journal of land use, mobility and environment, vol. 10
no. 1, pp. 77-94. TeMA - Journal of Land Use, Mobil-
ity and Environment, 10:77–93.
BSI (2014). PAS 181:2014 Smart City Framework – Guide
to Establishing Strategies for Smart Cities and Com-
munities. BSI Group.
Caird, S. and Hallett, S. (2019). Towards evaluation design
for smart city development. Journal of Urban Design,
Routledge, 24(2):188–209.
Charalabidis, Y., Zuiderwijk, A., Alexopoulos, C., Janssen,
M., Lampoltshammer, T., and Ferro, E. (2018). The
multiple life cycles of open data creation and use.
In Charalabidis, Y., Zuiderwijk, A., Alexopoulos, C.,
Janssen, M., Lampoltshammer, T., and Ferro, E., edit-
ors, The World of Open Data, page 20 – 21. Springer
International Publishing. Online]. Available:.
Demchenko, Y., Grosso, P., De Laat, C., and Membrey, P.
(2013). Addressing big data issues in scientific data
infrastructure. In Proceedings of the 2013 Interna-
tional Conference on Collaboration Technologies and
Systems, CTS 2013.
Ge, M., Bangui, H., and Buhnova, B. (2018). Big data for
internet of things: A survey. Future Gener. Comput.
Syst., 87:601–614.
Ge, M. and Helfert, M. (2006). A framework to assess de-
cision quality using information quality dimensions.
In Proceedings of the 11th International Conference
on Information Quality, MIT, Cambridge, MA, USA,
November 10-12, 2006, pages 455–466.
Ge, M., Helfert, M., and Jannach, D. (2011). Information
quality assessment: validating measurement dimen-
sions and processes. In 19th European Conference on
Information Systems, ECIS 2011, Helsinki, Finland,
June 9-11, 2011, page 75.
Ghahremanlou, L., Tawil, H., Kearney, A., Nevisi, P., Zhao,
H., X., and Abdallah, A. (2019). A survey of open
data platforms in six uk smart city initiatives. The
Computer Journal, 62(7):961–976.
Research Challenges of Open Data as a Service for Smart Cities
471
Hall, W., Shadbolt, N., Tiropanis, T., O’Hara, K., and Dav-
ies, T. (2012). Open data and charities. a state of the
art review.
Harrison, C., Eckman, B., Hamilton, R., Hartswick, P.,
Kalagnanam, J., Paraszczak, J., and Williams, P.
(2010). Foundations for smarter cities”. IBM Journal
of Research and Development, 54(4):1–16.
Helfert, M., Foley, O., Ge, M., and Cappiello, C. (2009a).
Analysing the effect of security on information quality
dimensions. In 17th European Conference on Inform-
ation Systems, ECIS 2009, Verona, Italy, 2009, pages
2785–2797.
Helfert, M., Foley, O., Ge, M., and Cappiello, C. (2009b).
Limitations of weighted sum measures for informa-
tion quality. In Proceedings of the 15th Americas Con-
ference on Information Systems, AMCIS 2009, San
Francisco, California, USA, August 6-9, 2009, page
277.
Janssen, M., Charalabidis, Y., and Zuiderwijk, A. (2012).
Benefits, adoption barriers and myths of open data
and open government, volume 29. Information Sys-
tems Management, Taylor & Francis.
Lewoniewski, W., We¸cel, K., and Abramowicz, W. (2017).
Relative quality and popularity evaluation of multilin-
gual wikipedia articles. Informatics, 4(4):43.
Lindman, J., Rossi, M., and Tuunainen, V. K. (2013). Open
data services: Research agenda. In 46th Hawaii In-
ternational Conference on System Sciences, HICSS
2013, Wailea, HI, USA, January 7-10, 2013, pages
1239–1246.
Lusch, R. F. and Vargo, S. L. (2014). The service-dominant
logic of marketing: Dialog, debate, and directions.
Routledge.
Mbarek, B., Ge, M., and Pitner, T. (2020). An efficient
mutual authentication scheme for internet of things.
Internet of Things, 9:100160.
McDermott, P. (2010). Building open government. Govern-
ment Information Quarterly, 27(4):401–413.
ODI (2017). Using Open Data to Deliver Public Services.
Open Data Institute, London.
Ojo, A., Curry, E., and Zeleti, F. (2015a). A tale of open data
innovations in five smart cities”. In Proceedings of
the Annual Hawaii International Conference on Sys-
tem Sciences, IEEE, page 2326–2335.
Ojo, A. K., Curry, E., and Zeleti, F. A. (2015b). A tale
of open data innovations in five smart cities. In 48th
Hawaii International Conference on System Sciences,
HICSS 2015, Kauai, Hawaii, USA, January 5-8, 2015,
pages 2326–2335.
Pereira, G. V., Macadar, M. A., Luciano, E. M., and Testa,
M. G. (2017). Delivering public value through open
government data initiatives in a smart city context. In-
formation Systems Frontiers, 19(2):213–229.
Poikola, A., Kola, P., and Hintikka, K. (2011). Public
data—an introduction to opening information re-
sources, Ministry of Transport and Communications.
Http://Www. Scribd. Com/Doc/57392397/Public-
Data, Helsinki.
Step
´
anek, P., Ge, M., and Walletzk
´
y, L. (2017). It-enabled
digital service design principles - lessons learned from
digital cities. In Information Systems - 14th European,
Mediterranean, and Middle Eastern Conference, EM-
CIS 2017, Coimbra, Portugal, September 7-8, 2017,
Proceedings, pages 186–196.
Transport Systems Catapult (2017). In THE CASE FOR
GOVERNMENT INVOLVEMENT TO INCENTIVISE
DATA SHARING IN THE UK INTELLIGENT MO-
BILITY SECTOR.
Zuiderwijk, A., Janssen, M., Choenni, S., Meijer, R., and
Alibaks, R. (2012). Socio-technical impediments of
open data. Electronic Journal of Electronic Govern-
ment, 10(2):156–172.
Zuiderwijk, A., Janssen, M., and Davis, C. (2014). Innov-
ation with open data: Essential elements of open data
ecosystems. Information Polity, 19(1–2):17–33.
CLOSER 2020 - 10th International Conference on Cloud Computing and Services Science
472
