Business Intelligence Reporting by Linguistic Summaries for Smart
Cities: A Case on Explaining Bicycle Sharing Patterns
Erika Min
´
arikov
´
a
1 a
, Galena Pisoni
2 b
, B
´
alint Moln
´
ar
3 c
and Hanna Krist
´
ın Skaftadottir
4 d
1
Faculty of Economic Informatics, University of Economics in Bratislava, Bratislava, Slovakia
2
York Business School, York St. John University, Lord Mayor’s Walk, YO31 7EX, York, U.K.
3
E
¨
otv
¨
os Lor
´
and University, ELTE, IK P
´
azm
´
any P
´
eter 1/C, 1117, Budapest, Hungary
4
Department of Business, Bifrost University, Iceland
Keywords:
Linguistic Summaries, Smart Cities, Enterprise Architectures, Business Intelligence Reporting, Drill-Down
and Roll-up Summaries.
Abstract:
An increasing number of intelligent urban services rely on the use of Information and Communication Tech-
nologies (ICT). Data-driven approach is often considered for supporting sustainable cities, provided the per-
vasive nature of the Internet of Things (IoT) like sensors, and their capabilities to collect data for elaborating
to the cities. This paper focuses on an intelligent business reporting approach explaining the bicycle sharing
patterns by linguistic summaries in order to provide relevant insights for decision makers and citizens. We ex-
plored the developments in bicycle sharing stations in different periods of the day for months and seasons. The
business intelligence query operations of drill-down and roll-up are often used in data reporting and analysis.
In this work, these operations are realized by linguistic summaries. The main aim is to propose an approach for
analysis and visualization in an understandable and interpretable way for diverse user categories. Experiments
were conducted on the Dublin bicycle sharing data set. Finally, a way how cities can set in place the collection
of data coming from different sources, as well as relevant enterprise infrastructures and data analytic pipelines
for such service are discussed.
1 INTRODUCTION
The fast and undeniable growth of urban mobility ser-
vices put us in the front of new challenges. New sus-
tainable and on-demand mobility solutions have un-
preceded growth, producing therefore also lots of data
to work within this field (Kong et al., 2020; Mayer-
Sch
¨
onberger and Cukier, 2013; Provost and Fawcett,
2013). These developments require: on one hand
(i) adequate enterprise architectures and solutions to
properly transform and processes data coming from
multiple sources, and therefore provide the basis for
data analysis, and on the other hand (ii) adequate so-
lutions for data analysis and interpretations of data to
diverse respondents groups.
Smart cities should not only offer sustainable mo-
bility services, but also work towards their success-
a
https://orcid.org/0000-0002-4230-2109
b
https://orcid.org/0000-0002-3266-1773
c
https://orcid.org/0000-0001-5015-8883
d
https://orcid.org/0000-0001-5228-8294
ful implementation and optimization of resources al-
located to them (Lim et al., 2018; Torre-Bastida et al.,
2018). In this work, we tackle the problem of bicycle
sharing, and the explaining use of bicycle stations that
recently appear in different cities as a possible solu-
tion for the mobility problems (Midgley, 2009; Midg-
ley, 2011). Various contemporary questions / prob-
lems that cities should tackle for the mobility services
exists. For instance, which stations are usually very
busy? In which time of the day considered bicycle sta-
tions are full? Does the number of tourists influence
the availability of bicycles? Are bicycle stations less
busy during the summer? The answers to such ques-
tions support the local authority in improving services
by, for instance, adjusting capacities of the bicycle
stations. For this task, the relevant data should be col-
lected, analyzed and presented in an understandable
way for local authorities (to manage improvements -
adjust the capacity of the stations accordingly), cit-
izens (to understand changes), journalists (to report
developments), etc.
Digitization and data processing developments of
762
Mináriková, E., Pisoni, G., Molnár, B. and Skaftadottir, H.
Business Intelligence Reporting by Linguistic Summaries for Smart Cities: A Case on Explaining Bicycle Sharing Patterns.
DOI: 10.5220/0012748200003690
Paper published under CC license (CC BY-NC-ND 4.0)
In Proceedings of the 26th International Conference on Enterprise Information Systems (ICEIS 2024) - Volume 2, pages 762-768
ISBN: 978-989-758-692-7; ISSN: 2184-4992
Proceedings Copyright © 2024 by SCITEPRESS – Science and Technology Publications, Lda.
the past decades have transformed the field of smart
cities and urban mobility profoundly. Diverse data
sources are available and therefore can be handled for
improving informativeness and support decision mak-
ing. Internet of Things (IoT)/sensors, and information
systems of the transport enterprises are examples of
the mobility data.
One of the aspects of human reasoning and deci-
sion is searching for information that is not immedi-
ately seen in the collected data (Trillas, 2015), prefer-
ably in an understandable way. When we focus on
the interpretation of information from data, we should
bear in mind that diverse urban stakeholder categories
differ in the levels of the statistical and IT literacy
(Hudec et al., 2018). Thus, the information should
be digested and interpreted in the most suitable way,
e.g., by linguistic summaries.
In this contribution, we explore the concept known
as linguistic summaries (see, e.g., (Boran et al.,
2016)) to reveal, whether these summaries are benefi-
cial and how we can improve business intelligence re-
porting with the linguistic summaries supporting the
usual business intelligence operations of drill-down
and roll-up.
From what discussed above, we set the following
research questions
• RQ1. How can relevant enterprise architectures
be set to collect and transform urban mobility data
coming from different sources?
• RQ2. Could short quantified sentences improve
explainability of data?
The article is organized as follows. Section 2
briefly explains preliminaries of linguistic summaries
and data set used for experiments. Section 3 is de-
voted to the procedure, experiments and mining sum-
marized sentences from the data set, whereas Sec-
tion 4 is devoted to the enterprise architecture for sup-
porting summaries. Section 5 discusses obtained re-
sults, perspectives and future tasks. Finally, Section 6
concludes the article.
2 METHODS, METHODOLOGY
AND DATA SET
This section introduces linguistic summaries and data
set.
2.1 Preliminaries of Linguistics
Summaries
Linguistic summarization of data is a topic which oc-
cupies scientists and practitioners since Yager’s sem-
inal work (Yager, 1982). Linguistic summaries have
been improved and applied in diverse fields, e.g., (Bo-
ran et al., 2016; Smits et al., 2018; van der Heide
and Trivino, 2009; Wilbik et al., 2020). A summary
like: in the morning the bike station is very busy, or
the most of young citizens commute large distances to
offices is understood at first glance. Linguistic sum-
maries have not been applied only to interpret data,
but also for revealing dependencies between data and
satellite images in smart cities images (Hudec et al.,
2020) among others.
Two main structures of the classic prototype forms
are so-called basic structure of linguistic summaries
(LS) and structure with restriction (Lesot et al., 2016).
The basic structure is Q records have S. Quantifier
Q and summarizer S are usually formalized by fuzzy
sets.
The proportion (relative cardinality) of entities in
a data set X that fully and partially satisfies the sum-
marizer (predicate) S is (Yager, 1982)
y
LS
(X) =
1
n
n
∑
i=1
µ
S
(x
i
) (1)
where n is the number of entities and the member-
ship function µ formalizes summarizer S. The validity
(truth value) of the summary is calculated as
v
LS
(X) = µ
Q
(y
LS
(X)) (2)
where the function µ
Q
formalizes fuzzy relative quan-
tifier Q for the summary.
The structure with restriction is Q R records have
S. The proportion of entities in data set that meet the
summarizer S and restriction R is (Yager, 1982)
y
LS
(X) =
∑
n
i=1
t(µ
S
(x
i
), µ
R
(x
i
))
µ
R
(x
i
)
(3)
where the membership functions µ formalize summa-
rizer S and restriction R. The validity (truth value) of
the summary is calculated as (2).
2.2 Datsets
For our experiments we used the open
data set of the bicycle sharing in Dublin,
Ireland. This data set is accessible at
https://data.smartdublin.ie/dataset/dublinbikes-api.
The considered data set contains collected data re-
lated to the accessibility of bicycles on the bicycles
station points within the city of Dublin on five minute
interval for the year 2021. The following attributes
are available:
station id, date time, last updated, name, bike stands,
available bike stands, available bikes, status, address,
latitude, longitude.
Business Intelligence Reporting by Linguistic Summaries for Smart Cities: A Case on Explaining Bicycle Sharing Patterns
763
In the pre-processing steps the time was extracted
from the date time attribute and adjusted for the lin-
guistic terms explained later on. The availability of
bicycles was calculated as a ratio between the bicy-
cle stands capacity and and the available bicycles for
every collected record. The Python libraries numpy
pandas and datetime are used for prepossessing. All
calculations of summaries are also realized in Python.
3 SUMMARISING BICYCLE
SHARING DATA
This section focuses on summarizing data and report-
ing revealed patterns compatible to the usual business
intelligence queries.
3.1 Procedure
Generally, LSs provide validity of any summary
posed on data. However, the usual business intel-
ligence queries supports operations of roll up and
drill down (Kimball, 2011). The former gives a
global overview, e.g., for top managers or sharehold-
ers, whereas the latter provides details on lower hier-
archical level, e.g., for a region with a poor behavior
to see, which districts are the most problematic ones,
or whether poor behavior is in all districts.
In our procedure for summarising bicycle shar-
ing data, we focuses on summarizing developments
in stations by seasons. The roll up operation gives a
global overview of a station for citizens or journalists
for the entire year. The drill down operation is applied
for seasons without a recognized pattern. The aim is
to reveal, whether we can find patterns on the months
or days levels.
3.2 Experiments
In order to proceed with revealing all relevant linguis-
tic summaries from the afore explained data set (Sec-
tion 2.2), we defined fuzzy sets for linguistic terms
morning, around lunch, evening and night on the time
attribute as is shown in Figure 1. We emphasize, that
these fuzzy sets cover an usual vague separation of
these parts of the day. When in a particular city or re-
gion is a different meaning of these terms, fuzzy sets
can be adjusted accordingly.
The next linguistic variable is availability of bicy-
cle in stations. The number of bicycle stands in sta-
tions differ. Thus, instead of of number of bicycles we
adopted the proportion of available bicycles, which is
the ratio of the number of stands and available bicy-
cles. This ratio is fuzzified into three fuzzy sets few,
Figure 1: Part of days fuzzified into four fuzzy sets.
about half and most of bicycles are available. The
next required concept is an elastic quantifier most of
to express sentence like the most of mornings (in the
considered time period) few bikes is available.
In the next step, we executed summaries for each
combination of time and bicycle availability and
select the most relevant quantified sentences. We
calculated summaries for two stations. For the other
stations, the calculations are straightforward. In order
to shorten sentences, we excluded quantifier most
of, i.e., instead of the most of mornings few bikes is
available we write mornings is available few bikes.
The results (the sentences with the highest validity)
for stations ID(117) and ID(38) are as follows.
Season:01-04 (Winter)
Station ID(117)
morning is available few bikes t= 0.9748
around lunch is available few bikes t= 0.9875
evening is available few bikes t= 0.9852
night is available few bikes t= 0.9820
Season:01-04 (Winter)
Station ID(38)
morning is available around
half bikes t= 0.5023
around lunch is available few bikes t= 0.5277
evening is available around half bikes t= 0.5635
night is available around half bikes t= 0.5372
Season:07-10 (Summer)
Station ID(117)
morning is available few bikes t= 0.9592
around lunch is available few bikes t= 0.9740
evening is available few bikes t= 0.9666
night is available few bikes t= 0.9628
Season:07-10 (Summer)
Station ID(38)
morning is available many bikes t= 0.3975
around lunch is available few bikes t= 0.4227
evening is available around half bikes t= 0.4764
night is available many bikes t= 0.4494
Summaries revealed that the station ID(117) is
very busy during both seasons, whereas for station
ID(38) the dominant bicycles availability pattern does
SEC-SCIS 2024 - Special Session on Soft Computing in Ethicity and Smart Cities Services
764
not exist. Thus, we try by the drill down operation to
the months level to find, whether we can recognize
patterns in respective months.
Drill down to months (Station ID 38 summer):
July
morning is available many bikes t= 0.4246
around lunch is available around half bikes t= 0.451
evening is available many bikes t= 0.5129
night is available many bikes t= 0.5189
No recognised dominant pattern, we continue
with drill down on days:
01.07.2021
morning is available around half bikes t= 0.0
morning is available few bikes t= 1.0
02.07.2021
morning is available around half bikes t= 0.8537
morning is available few bikes t= 0.0269
03.07.2021
morning is available many bikes t= 0.9944
morning is available around half bikes t= 0.0083
morning is available few bikes t= 0.0009
etc.
This drill down operation is realizable due to the
data availability for each minute.
For each day summaries recognised different be-
haviour. This is the reason, why with the aggregated
data no dominant pattern is recognised.
August
morning is available many bikes t= 0.4351
around lunch is available few bikes t= 0.4834
night is available many bikes t= 0.4671
September
morning is available few bikes t= 0.3718
around lunch is available few bikes t= 0.4597
evening is available around half bikes t= 0.5172
No significant pattern for both months - another
drill down is required.
October
morning is available many bikes t= 0.5701
around lunch is available around half bikes t=
0.5968
evening is available many bikes t= 0.9583
night is available many bikes t= 1.0
In the last month, we recognized that many bicy-
cles are available in evening and night.
The opposite operation in roll up to the year 2021
for this station (ID38):
morning is available around half bikes t= 0.382
around lunch is available around half bikes t=
0.4699
evening is available around half bikes t= 0.4722
night is available around half bikes t= 0.4175
Again, not a dominating pattern is recognized. In
our experiments, we considered pattern to be domi-
nant when its validity is greater than or equal to 0.75.
For station ID117 there is not a significant differ-
ence between the considered sessions. The revealed
patterns indicate that constantly only few bicycles is
available. This station is very busy during the entire
year. Thus, the increasing in capacity should be con-
sidered, or at least the focus of business intelligence
dashboard should be on this station.
Contrary, station ID38 is rarely busy. Thus, stands
can be reduced and moved to another station. The
most relevant sentence has validity slightly above 0.5.
4 ENTERPRISE ARCHITECTURE
FOR DATA COLLECTION AND
MINING SUMMARIES
Recently, the fields of smart mobility became one of
the primary sources of data through the applications
of various sensors and IoT-s. In the ecosystem of
smart cities and its smart mobility, the efficient and
effective utilization of data become an essential is-
sue. Transformation of data collection from the sim-
ple substantiated IoT data to data that originate from
large-scale monitoring led to the requirement of dis-
ciplined data analytic. Data can be listed as a tradi-
tional data coming from the city operation, and op-
erational data of transport originated from different
devices. The latter data are usually unstructured and
heterogeneous; either we consider their structure or
their content. Data should be accompanied by meta-
data that describe the essential information about the
content and can be utilized to categorize and organize
data to exploit them for the advanced data mining.
When focusing on the bicycle sharing, it depends
on various aspects like weather, restrictions (e.g., pan-
demic or events). Such data are usually not available
in the data collected from sensors on the stations.
Previous research has shown that analysis of data
that originated from structured databases and exter-
nal sources of a clear relation to structured data is
Business Intelligence Reporting by Linguistic Summaries for Smart Cities: A Case on Explaining Bicycle Sharing Patterns
765
relatively straightforward with the use of data ware-
houses (Golfarelli and Rizzi, 2009; Kimball, 2011;
Kimball and Ross, 2013). In the bicycle sharing, such
data can be from the meteorological data sets explain-
ing weather conditions near each station, or whether
events appear near the stations. The essential function
of the data warehouse is to integrate data and trans-
form them into the confirmed structure, relevant for
the domain of interest. In this case, the domain of the
urban sustainable mobility to support reporting and
interpreting for the diverse urban stakeholders groups.
In Section 3.2, linguistic summaries are applied
on the bicycle sharing data to reveal patterns. Bene-
ficially, the Key Performance Indicator (KPI) for the
stakeholders should be expressed linguistically (Vais-
man and Zim
´
anyi, 2022). The reporting with linguis-
tic summaries gives a reliable, trustable, and easy-to-
understand overview of the actual state regarding the
stations (see Section 3.2). This interpretations provide
the basis for supporting effective decision-making for
the city (see Figure 2). In our case, KPI is expressed
by linguistic terms: few, about half and most of.
In order to generate the linguistic insights as afore
computed, the relevant ”data ingestion” framework,
or the way how the data are fed to the data ware-
house, should be set in place. Relevant levels of secu-
rity should be treated in line with existing regulation
(foremost GDPR) for data management.
The benefit of implementing an approach as pro-
posed in this work, is that a local authority can, if of
interest, extend the reporting of the collected data by
the other internal and external data and adjust report-
ing to diverse user categories. For instance, citizens
and users with disabilities benefit of LS, which pro-
vide an easy way to communicate mined patterns. For
advanced users, like traffic experts, external data cov-
ering, e.g., traffic densities of cars, weather conditions
and organized events can reveal how these parame-
ters influence bicycle sharing in the affected stations.
With an approach as is under the development in this
work, local authorities would have a better overview
of cycling in the city. Next, suited LSs can be adopted
for informing cyclists about their riding behaviour in
comparison to the average values, for instance. How-
ever, a summary of structure your length of ride is
around average is not informative enough. This sum-
mary is the same for person who use bicycle every
working day (but not during weekends) and for some-
one who rarely cycle on working days, but is a heavy
bicycle user during weekends. The better option are
quantified linguistic summaries like few days your
length of rides is slightly under average, and about
half of days your length of rides is about average.
5 DISCUSSION
The proposed approach has a significant applicability
potential. This holds especially when informing di-
verse urban stakeholders groups (including disabled
citizens) should be realized by a robust and compact
approach.
In our data intense society, we face the problems
of explaining mined patterns (Smits et al., 2018). A
promising way is by linguistic summaries. In order to
contribute, we raised two research questions. The first
research question is How can relevant enterprise ar-
chitectures be set to collect and transform urban data
coming from different sources? The answer is that the
processing data by the linguistics summaries requires
a clear data warehouse model for storing data coming
from diverse sources. Such data are relevant for ad-
vanced explaining summaries and revealed patterns.
The second research question is Could short quan-
tified sentences improve explainability of data? The
answer depends on the structure of the sentences. If
it is a basic structure of summary (1), then histograms
and the other charts are suitable when visual attention
is not disturbed (i.e., it should not be focused else-
where) (Arguelles and Trivi
˜
no., 2013), or summary
is not for visually impaired citizens. Regarding, the
summary with restriction, the situation is different. It
is more convenient to express it by sentences like in
Section 3.2 than on series of graphs covering more at-
tributes. Anyway, linguistically summarized sentence
is convenient for all urban stakeholders groups.
The next perspective is merging summaries with
maps. Either by using map features in summa-
rized sentences (Hudec et al., 2020), like whether a
particular proportion of objects influences the other
attributes, or interpreting summarized sentences on
maps. The positions of two stations used in exper-
iments (Section 3.2) are shown on map in Figure 3.
The very busy station is located near the river and
canal.
The main problem of mining all relevant summa-
rized sentences is the computational cost, when we
consider all stations and all possible summaries in a
large city. In the future work, we focus our work on
the optimisation in this direction.
6 CONCLUSIONS
A smart and sustainable mobility should rely on a
heavier use of bicycles. One possibility is by the bi-
cycle sharing concept. This work has shed light on
summarizing the bicycle sharing patterns of the bicy-
cle stations.
SEC-SCIS 2024 - Special Session on Soft Computing in Ethicity and Smart Cities Services
766
Figure 2: Sources of data and usage, figure composed by the authors, the creation of the figure was inspired by (Kimball,
2011; Mayer-Sch
¨
onberger and Cukier, 2013; Provost and Fawcett, 2013; Kong et al., 2020).
Figure 3: Location of the two stands used in experiments.
In business intelligence reporting a well-known
way is by drill down and roll up query operations
(e.g., in MDX query language). In this work, we cre-
ated these operations by linguistic summaries. Next,
we demonstrated summaries (including drill down
and roll up) on the real world open dataset coming
from the bicycle sharing service in Dublin, Ireland.
In this paper, we also proposed an architecture
design required for collecting and transforming data
coming from different sources as a support for reveal-
ing and interpreting patterns by linguistic summaries.
It is an explainable way how to provide insights into
the bicycle sharing data, a relevant support for deci-
sion makers, local authorities and citizens.
This position work requires further investigation
in the field of effective data collection and integration
Business Intelligence Reporting by Linguistic Summaries for Smart Cities: A Case on Explaining Bicycle Sharing Patterns
767
due to diversity of required data, as well as in the op-
timization of mining relevant patterns of bicycle shar-
ing by linguistic summaries. Linguistic summariza-
tion copes with the high computational demand due
to a larger number of data expressing bicycle sharing
stations and variety in summarized sentences.
ACKNOWLEDGEMENTS
This research was supported the Thematic Excellence
Programme TKP2021-NVA-29 (National Challenges
Subprogramme) funding scheme, the COST Action
CA19130 - ”Fintech and Artificial Intelligence in Fi-
nance Towards a transparent financial industry” (Fi-
nAI), and the FBR-PDI-021 - The cooperation in the
fields of business intelligence and artificial intelli-
gence for science and education - BICISEDU.
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