Applying Process Mining and RTLS for Modeling, and Analyzing
Patients’ Pathways
Sina Namaki Araghi
1
, Franck Fontanili
1
, Elyes Lamine
1
, Ludovic Tancerel
2
and Frederick Benaben
1
1
Industrial Engineering Center of Ecole des Mines d’Albi-Carmaux,
University of Toulouse, Allée des science, Albi, France
2
Maple High Tech, Toulouse, France
Keywords: Business Process Management, Process Mining, Real Time Location Systems.
Abstract: Purpose: This paper aims at introducing a generic approach for visualizing, analyzing and diagnosing
patients’ pathways. This approach could be categorized as a business intelligence approach to extract
knowledge for decision makers in healthcare organizations. The analyses provided by this approach are based
on the location data which are being recorded in the information system (IS) by indoor-Real-Time Location
Systems (RTLS). Findings: Healthcare organizations are getting more eager to learn from the execution of
their processes. They seek different tools and approaches to analyze the processes and visualize the problems.
This paper presents one of the possibilities to provide more understanding of process executions and it is
based on the locations of the patients inside the organization. Approach: Business intelligence approaches
provide new technical and technological solutions for business analysts to improve the quality of products
and services within organizations. The approach of this work helps to visualize patients’ pathways and analyze
them by associating real-time localization and process mining. This approach consists of four phases in which
several functionalities have been defined. These phases are Data, Information, Awareness, and Governance
(DIAG). Additionally, a case study has been designed to illustrate the DIAG approach.
1 INTRODUCTION
The clinical pathways or patients’ pathways consist
of several activities and different steps with the
objective of receiving a service which is the health
treatment. A clinical pathway is a complex
intervention for the mutual decision-making and
organization of care processes for a well-defined
group of patients during a well-defined period
(Vanhaecht et al., 2010). It is desirable to visualize
these pathways as the business processes, which have
the objectives and consist of different tasks and actors
to reach those objectives.
Many initiatives have been introduced within the
last decade to improve the management of clinical
processes. The clinical pathways aim at enhancing the
quality of healthcare services by improving the risk-
adjusted patients’ outcomes, promoting patient
safety, increasing patient satisfaction, and optimizing
the use of resources. These organizational
enhancements can be only justified on the basis of a
relevant diagnosis of the reality behind the processes’
executions and their management on the field. Hence,
equipping decision-makers with tools and methods to
facilitate and support their actions could beneficiate
the organization and its clients.
This paper aims at describing a study case which
illustrates a developing approach named as DIAG.
This method investigates different aspects of the
patients’ pathways and uses multiple sets of
techniques to visualize and analyze the performance
level of each pathway. DIAG has four different
phases; Data, Information, Awareness, and
Governance. This paper focuses on the “information”
phase to highlight the core of this method. It describes
how a proper set of location data from patients’
movements could beneficiate healthcare
organizations by acquiring qualitative and
quantitative analysis.
In the following, section 2 presents the features of
two main tools and techniques in DIAG method. The
third section explains the DIAG through exhibiting a
summary of a study case, which has been performed
at a hospital in France. Finally, the last section shows
the summary of the works and the perspective for the
future works.
540
Araghi, S., Fontanili, F., Lamine, E., Tancerel, L. and Benaben, F.
Applying Process Mining and RTLS for Modeling, and Analyzing Patients’ Pathways .
DOI: 10.5220/0006651605400547
In Proceedings of the 11th International Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2018) - Volume 5: HEALTHINF, pages 540-547
ISBN: 978-989-758-281-3
Copyright © 2018 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
2 STATE OF THE ART
This section presents the notion of designing business
process models, the functionality of indoor-RTLS and
process mining.
To analyze the performance level of the
operational processes, organizations are trying to
move from the “data-aware” information systems to
process-awareinformation systems (Aalst, 2004).
This motivates organizations to use business process
management approaches, which consists of modeling
processes and performing quantitative analysis on top
of the process models.
To discover and analyze the business processes
several actions must be taken. To clarify, one should
understand the life cycle of process modeling”. In
order to design business processes, different activities
should be taken into consideration such as gathering
information, clarification of data and designing the
process flows. After acquiring such models experts
should define criteria in accordance with their
strategies, then a performance measurement should
be defined (Looy and Shafagatova, 2016).
Currently, to gather data related to the process
executions an interview-based process discovery
approach is being used (Marlon Dumas, 2013.). To
succeed in such approach, it necessitates to carry out
a huge load of works to do the on-field observations
and perform interviews with processes’ actors.
Eventually, the quality of the gathered data is in doubt
and it is dependent on the experience of the
interviewer and the process analysts.
The evidence-based process discovery is another
approach which helps to automatically perform
process discovery from the information systems.
However, there are several inconsistencies in the case
of gathered data in the hospital information systems.
For example in the case of patients’ pathways, one
could extract the data from hospital information
system to observe the amount of time that each patient
has spent in the hospital sectors. Since people are in
charge to record the patients’ data, there are lots of
inaccuracies with the registered data.
This research work seeks for an efficient way of
gathering accurate data for visualizing the patients’
pathways. The final results should be a process
diagnosing platform which is able to visualize and
analyze the activities within patients’ pathways. In
addition to the process awareness, the platform could
provide an awareness of the location of each event.
This platform could support the transformation of
current information systems to process and location-
aware information system. The approach in this
research work aims at supporting this transformation
of the information systems by the application of I-
RTLS and process mining. In the following, these two
fields (indoor localization and process mining) will be
explained.
2.1 Indoor Localization Systems
The objective of these systems is to track objects
inside indoor environments. Their functionality is
similar to Global Positioning Systems (GPS) (Drawil
et al., 2013). GPS works by using NAVSTAR
satellites. The GPS functionality does not suit the
indoor localization and the corresponding signals are
not capable of finding an object inside buildings with
accurate coordinates (x, y, z). Therefore, indoor
localization technology is being used for this matter.
These systems consist of two main parts. First, mobile
nodes or tags which are attached to objects that need
to be located. Second, sensors or readers which find
the position of the tags or mobile nodes.
Multiple communication technologies are being
used for indoor positioning of objects in healthcare
and industry. RFID (Radio Frequency
Identification), and Wireless Local Area Networks
(Wi-Fi, ZigBee, Z-Wave, Bluetooth, etc.) are playing
a huge role in these organizations. RFID is an
electronic identification technology used for tracking
goods and people (Curran et al., 2011). This
technology uses radio frequency waves to transfer
data between tags and readers. RFID tags function in
three different states; active, semi-passive, and
passive. Active tags are using an internal battery, or
sometimes they are connected to an external power
source. These tags offer a wide range of hundred feet
or more. Passive tags do not have any energy source,
and their accuracy and readability are limited (Want,
2006). On the other hand, semi-passive tags use
batteries and they need an external power source to
communicate with readers (Lai et al., 2005). The
Readers have the role of transferring radio frequency
signals to the tags and receiving them back in
regulated version (Jin et al., 2008). Thanks to the
semantic event processing, the system could translate
the signals of the tags to the location data (Bok and
Yoo, 2017).
In the context of locating objects, RFID is being
used mainly in manufacturing sectors (Lu et al.,
2006). In the case of healthcare organizations, RFID
could not satisfy all the needs. It could identify the
tagged objects which are passing nearby the different
stations, but the tags should be moving through a very
well structured operation. Also, RFID systems do not
necessarily display the real-time location data. The
real-time information could be very useful in
Applying Process Mining and RTLS for Modeling, and Analyzing Patients’ Pathways
541
manufacturing and hospitals, especially in emergency
situations. Consequently, in some cases, researchers
have integrated RFID with WLAN to acquire real-
time data (Adame et al., 2016).
The other localization systems are classified as
Indoor-Real Time Localization Systems. These
systems have three main parts. Tags, which are
attached to the objects. These tags are active and they
emit signals continuously. Sensors or beacons; these
devices would receive the signals and send them to
the third part of the system which is the location
engine. This part would use different algorithms and
techniques to calculate the exact locations of the tags.
Some of these algorithms are Triangulation,
Trilateration, Angle of Arrival (AOA), Time
Difference of Arrival (TDOA), and Received Signal
Strength Indicator (RSSI) (Luo et al., 2011). Multiple
wireless local area networks have been introduced in
markets for indoor-RTLS, some of them are Wi-Fi,
and ZigBee which has been seen in previous works
that this technology could be applicable in service
sections. It has low energy consumption and multi-
channel control systems, alarm systems, and lighting
control (Cheng, 2009). Ultra-Wide Band (UWB),
these systems have short period pulses as a result
UWB is suitable for indoor positioning technologies.
UWB performance seems to be better than other
technologies as well as in terms of accuracy (less than
30 cm) and of course the range which is up to 200
meters within an open space. The weakness of this
system is inside buildings with thick walls and full
metal structures, due to the fraction and reflection of
signals in those types of buildings. Bluetooth or
Bluetooth Low Emission (BLE) is the other
technology which is being used in similar approaches
and it has a very low consumption level.
Some aspects of indoor localization have been
discussed in this section. The next part will introduce
process mining and highlights its association with I-
RTLS in the context of healthcare.
2.2 Process Mining
It is obvious that quality of services in hospitals could
directly influence the lives of people. Thus, it is
inevitable that hospitals should plan and act on the
improvement of their processes. The quality of
healthcare processes is highly dependent upon the
way they are being executed. This idea is motivating
researchers to provide healthcare organizations with
new approaches such as process mining to illustrate
the execution of the processes. In addition, execution
of medical and non-medical processes within the
healthcare organizations would result in numerous
recorded events within information systems. These
data would be displayed as a log file. A log file would
consist of a multiple information such as case id,
timestamp start, timestamp end, details of activities,
resources, and other types of information. One of the
challenges for organizations is to extract meaningful
information from these log files (Mans et al., 2013).
Process mining is a set of techniques and methods
which are subjected to discover the business
processes from event logs. Process mining consists of
three main activities: (i) process discovery, (ii)
conformance checking, (iii) enhancement (Aalst,
2016). By using this method information systems are
capable of translating raw log files into usable sets of
information. This information could be the process
models, general statistical analysis of processes,
bottleneck analysis, analysis of a variety of cases in
event logs and etc. There are multiple advantages for
organizations in applying process mining techniques.
In the context of healthcare, study cases show that
process mining could beneficiate directors by
providing several perspectives for decision-making
(Rojas et al., 2016). A control-flow perspective could
show the execution of the processes. A performance
perspective highlights the problems and bottlenecks
while executing the processes. Currently, these
analyses are basically related to analyzing the time-
oriented data (Fernandez-Llatas et al., 2015).
Additionally, conformance checking would help
organizations to see where the deviations are in a
process. The resource usage analysis is the other
perspective offered by process mining (Caron et al.,
2014).
Process mining techniques and algorithms are
being developed in many tools. ProM (http://www.
processmining.org/), Disco (https://fluxicon.com),
QPR (https://www.qpr.com), Celonis (https://www.
qpr.com) are front-runners in the market. Most of the
healthcare cases are being developed by ProM (Rojas
et al., 2016), which is extremely powerful in applying
multiple techniques on event logs (Dongen et al.,
2005). Disco is a user-friendly and powerful tool,
however, it does not contain all the analyzing
techniques like ProM. On the other hand, Celonis and
QPR are two tools which are known and being used
mainly in manufacturing industries.
Applying process mining and indoor localization
systems did not receive sufficient amount of
attention, however, it shows promising results in
healthcare. For instance, Fernandez-Llatas et al used
this idea in order to monitor the behavior of the
patients in a nursing home by analyzing the pathways
of the patients (Fernández-Llatas et al., 2013). In
another case, they presented an approach for applying
HEALTHINF 2018 - 11th International Conference on Health Informatics
542
RTLS and process mining in a hospital in Valencia
which also shows intriguing outcomes in case of
observing the movement of patients and to analyze
the time aspect of the process execution (Fernandez-
Llatas et al., 2015). In both cases, they have used
PALIA ILS suits which is a web-based process
mining tool to discover the process maps. PALIA
stands for Parallel Activity-based Log Inference
Algorithm and is able to infer workflows from
activity log samples. And ILS is for Indoor
Localization Systems. Also, they have introduced a
methodology which supports their application. This
methodology consists of several steps as ILS
installation, ILS data gathering, a semantic
aggrupation of areas, process filtering, process
discovery, process conformance, process
enhancement, and process improvement. In their
methodology the difference between process
enhancement and process improvement is vague.
In this paper, the process improvement actions are
outside the application of process mining and indoor
localization systems because the resolution to
improve and change a process is only feasible by
decisions coming from human knowledge.
In modern businesses, due to the challenges of
designing and monitoring business processes, there is
a necessity of using suitable analysis techniques
(Aalst, 1998). Also, it has been inferred from other
works that analyzing business processes with
exclusive criteria is necessary in order to classify the
business processes’ attributes, identify the
bottlenecks, and compare process variants (Vergidis
et al., 2008). Additionally, Vergidis et al have
classified process analysis into three groups of
diagrammatic models, business process languages,
and mathematical models. Needless to say, their
approach is based on the primary analysis of
processes which is the method one could use to
visualize the processes.
It has been seen in the work of Zakarian in
(Zakarian, 2001) that using diagrammatic process
modeling techniques provide a qualitative notation on
the process executions. However, these techniques
suffer from the lack of tools which show the
quantitative analysis and performance level of
processes. Furthermore, generating business process
models is impractical without diagnosis based on
relevant key performance indicators. This analysis
should be in line with the main objective, which is
improving the performance of physical processes.
Improving business processes is only feasible by
understanding the features of each activity and events
in the process in accordance with customer and
process owner’s perspectives. For example, a task
such as recording the history of patient’s treatment
could be a non-value added activity from patient’s
perspective. But from the hospital’s point of view,
this task should be identified as a value-added
activity. As Dumas et al define in (Marlon Dumas,
2013) we could have three types of activities, value-
added, non-value added, and business value-added
activities. This research work aims at analyzing
business processes based on this classification of
activities. However, the question is how to discover
the activities in the business processes and how to
distinguish them.
3 DETAILED PROPOSAL
It has been shown that business intelligence (BI)
approaches in healthcare present new solutions for
business analysts within the organizations especially
the healthcare sector for improving the quality of
medical care and patient’s quality of life (Machado
and Abelha, 2001). It could be inferred that BI
approaches encompass the strategies and
technologies used by enterprises to help business
analysts to understand and improve the quality level
of business processes (Dedić and Stanier, 2016). It’s
been proven that BI tools are working efficiently with
healthcare data and they are able to generate real-time
information and knowledge relevant to the success of
healthcare organizations. Moreover, BI approaches
profit healthcare professionals in making vital
decisions inside hospitals, clinics, paramedics’
circulation and management of the administrative
works.
This paper aims at suggesting DIAG approach
which is embracing the BI notion and tries to generate
knowledge from the location data for decision makers
in hospitals. DIAG stands for four levels which could
transform the raw data into knowledge and awareness
for healthcare experts. These levels are Data,
Information, Awareness, and Governance.
The IDEF0 model presented in figure1 gives an
overview of the DIAG approach. In the first phase,
one function has been defined as gathering. This
function is mainly concerned with monitoring the
movements of the objects and receiving the primary
data come from localization systems. As it has been
explained before, these systems use the positioning
algorithms to locate the tags. The log refining
function executes different data mining techniques in
the context of RIO-DIAG platform. This function
cleans and transforms the collected data in the first
function into the proper event logs which suit the
process mining techniques in the following function
Applying Process Mining and RTLS for Modeling, and Analyzing Patients’ Pathways
543
Figure 1: The DIAG methodology.
modeling. The modeling function uses the process
discovery algorithms and illustrates the execution of
a processes based on the qualitative process analysis.
Fourth, in analyzing function, different techniques are
being used in order to provide a quantitative analysis
for users. The performance level of processes will be
evaluated in this function, and one could see and
comprehend the way patients are circulating in the
organization to receive their treatment.
In the diagnosing function, multiple sets of
techniques will be used to highlight the real cause
behind the problems and weaknesses in the
performance of processes. Last but not least, in the
prognosing by using queuing theory and other
simulation techniques different scenarios and
improvement actions will be suggested. RIO-DIAG is
the platform which is working based on these
functions, and by fulfilling four different phases of
DIAG approach provides opportunities to apply BI on
monitoring patients’ pathways. Describing all the
functionalities is out of the scope of this paper,
however, modeling and analyzing, two of the main
functions of this approach will be illustrated.
To clarify this method a study case has been
developed to show how one could visualize and
analyze the patients’ pathways. In this experiment, an
indoor-RTLS had been used to collect the location
data. After installing the sensors and calibrating the
location systems, patients received the tags. These
tags communicate with sensors by UWB technology.
The transmitted signals would be calculated in the
location engine by using TDOA and AOA
measurement techniques. In this experiment, fourteen
patients have been monitored. Each patient has a case
ID based on the tag identification. In this case, there
was no return of the same patient to the hospital.
Twelve different activities have been identified based
on the name of the zones in the hospitals. Each time a
patient went inside or outside a section an event had
been registered in the primary log file. The entities in
the log file are related to the type of indoor-RTLS.
In this experiment, the log file consists of patients
ID, activities’ details, timestamp start, and timestamp
end. Figure 2 shows a part of the event log related to
the patient 171. The primary event log consists of one
hundred events, and it is transformed and prepared for
the modeling function. As it has been shown, the first
and last events related to the case 171 have the
duration of “00:00”. This indicates that these events
are only instants while the process is being executed
and they have been seen as a “passage” in the facility.
Figure 3 shows that the longest event for the
patient 171 was staying in the “Consultation Box 1”
to meet with the doctor. In addition to this data, the
distance of the whole pathway was two hundred and
sixty-two meters. In addition, it has been shown that
the patient has spent approximately 54 minutes in the
facility. Ability to reach such analysis is the result of
HEALTHINF 2018 - 11th International Conference on Health Informatics
544
applying RTLS and acquiring the accurate data
related to the processes’ executions. Now, the
question is the value classification of these activities
and which share of the process duration was value-
added for the patients. This knowledge of the value
class of activities is being provided by the healthcare
experts. Furthermore, there is a need to select the data
about one specific patient’s pathway and to analyze it
separately.
Figure 2: The event log for the case 171.
Figure 3: The basic analysis for patient 171.
To analyze the patient’s pathways as the business
processes, it would be formidable to acquire a
qualitative analysis by displaying the process map
and a quantitative analysis based on different aspects
of the performance of the process. Thanks to process
mining, figure 4 shows the process map related to the
patient 171. Such process map provides a care-flow
perspective on the patient’s pathways. Explanations
regarding the discovery algorithms are broader than
the scope of this paper since the core and possible
outcomes of DIAG approach is being illustrated in
this article.
To acquire a performance perspective on process’
execution, a Critical To Quality (CTQ)
(Montgomery, 2007) has been defined for this
experiment as Process Efficiencyin the hospital. A
quantitative indicator has been proposed as “Length
of Stay or duration to analyze the performance level
of the processes based on the CTQ. The analysis
related to the indicator has been shown in table 1.
These analyses are based on the value-class of the
activities and the data coming from localization
systems. By looking at the process efficiency, one
could observe that the 85% of the process duration
was related to executing the value-added activities
and close to 15% of process duration was associated
with the waiting time and staying in the queue. The
decision-making actions are now dependent on the
knowledge of the healthcare experts to determine how
they can improve the non-value added parts of the
process. Although, the simulation step could be a
compatible solution to see several options for
enhancing the situation.
Indeed, one could infer that a logical decision
could be made only by receiving the proper
knowledge which is the aim of this approach. As it
has been presented, this approach could support the
quality of the decisions by providing the care-flow
and performance perspectives on the processes.
Figure 4: The process map for patient 171.
Applying Process Mining and RTLS for Modeling, and Analyzing Patients’ Pathways
545
Table 1: Process efficiency analysis based on Length of
Stay.
Activities (patient
171)
Duration
VA/ NVA
Process
Efficiency
Consultation
Department
0
PASSAGE
85.2 %
Waiting Room
4:39
NVA
Registration Desk
9:02
VA
Waiting Room 3
1:11
NVA
Pre-Consultation Box
6:01
VA
Waiting Room 3
0
PASSAGE
Consultation Box1
29:17
VA
Registration Desk
2:37
VA
Gate
2:19
NVA
Exit area
0
PASSAGE
4 CONCLUSION
This paper aimed at presenting the possibilities and
advantages of applying process mining on location
data to provide more awareness regarding the
patientspathways. This paper identified the DIAG
approach which uses the indoor-RTLS, process
mining, and business process management techniques
to visualize, analyze and diagnose the patients’
pathways. This approach embraces the hierarchy of
data, information, awareness, and knowledge which
extract the location data from the movements of the
patients and transform these data to the knowledge.
The real-time location data provide more accuracy in
tracking patients’ activities in the hospitals and
process mining permits to model those activities as
business process models. The advantage in this
approach is in providing the quantitative and
qualitative analysis based on the value class of the
activities in the organizations.
To illustrate the possible outcomes of this
approach an experiment has been performed at a
hospital in France. Additionally, an overview has
been provided for the major techniques and
technologies in this approach.
To evolve this research work, the upcoming works
are oriented towards refining this approach and
providing the details about the rules and regulations
for transforming the location data into prepared event
logs for process mining tools.
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