IMPROVEMENT OF BUSINESS PROCESS SURGERY USING
SIMULATION
Nadja Damij
Faculty of Information Studies, Sevno 13, pp 299, 8000 Novo mesto, Slovenia
Talib Damij
Faculty of Economics, University of Ljubljana, Kardeljeva ploscad 17, 1000 Ljubljana, Slovenia
Keywords: Business process, Simulation, Process improvement.
Abstract: This paper discusses the possibility of finding a better solution for the problem of business process im-
provement using simulation technique. Most of problems of organisations are originated in fact that their
business processes are neither well defined nor particularly efficient. Business process modelling is done by
identifying a certain business process, defining its activities, and using a modelling technique to develop its
model. Process improvement is carried out by precise analysis of the process, suggesting changes and im-
provements, and giving solutions for existing problems. To achieve this, we concentrate our work on ana-
lysing and simulating the business process discussed. This means that the simulation results need to be ana-
lysed and understood in order that the analyst is able to suggest necessary changes. A complete
understanding of the results of process simulation is an essential precondition to move forward with busi-
ness process improvement. The problem of conducting a surgery is used as an example to carry out business
process improvement using simulation technique.
1 INTRODUCTION
The aim of this paper is to introduce the importance
of using simulation technique in the field of business
process improvement. The purpose of using simula-
tion is to analyse the current or the alternative ver-
sion of the business process discussed in order to de-
termine its behaviour and carry out further
improvements by solving problems, removing ob-
stacles and identifying bottlenecks existing in the
process.
A process model, which represents a true reflec-
tion of the business process discussed, is essential
for carrying out business process improvement and
information system development successfully. Busi-
ness process improvement became a very important
way of ensuring changes in an organisation's struc-
ture and functioning in order to create a better, more
competitive and successful enterprise.
In Section 2, different definitions and explana-
tions of business process published by well-known
authors are presented. In Section 3, business process
modelling is discussed. In Section 4, business proc-
ess simulation as a technique for business process
improvement is introduced. The last section contains
some useful remarks and conclusions. In this work,
the problem of business process Surgery is used to
illustrate the use of simulation to improve business
processes.
2 BUSINESS PROCESS
Most of problems faced by enterprises concern in-
ternal business procedures that are neither well de-
fined nor particularly efficient (Hales, 1993; Lavery,
1992; Medina-Mora et al., 1992).
Business processes come within our scope in that
they potentially add value to the organisation and as
such are attracting attention (examples given in Mar-
tinez et al. 2001; Aguilar-Saven, 2001; Chan, 2002;
Hammer, 1990; Hammer and Champy, 1993; Dav-
enport and Short, 1990 and so forth). Consequently,
business process modelling is on the increase as only
434
Damij N. and Damij T. (2009).
IMPROVEMENT OF BUSINESS PROCESS SURGERY USING SIMULATION.
In Proceedings of the International Conference on Health Informatics, pages 434-437
DOI: 10.5220/0001536604340437
Copyright
c
SciTePress
a thorough comprehension of the business processes
within the organisations can lead to effective, effi-
cient and value-adding systems. According to Agui-
lar-Saven and Olhager (2002), it is the business
processes that are the key element when integrating
an enterprise.
A process is defined as structured, measured sets
of activities designed to produce a specified output
for a particular customer or market (Davenport,
1993). Hence, a process converts inputs by summing
their value through various activities into outputs.
However, Aguilar-Saven (2003) stressed that a busi-
ness process is related to the enterprise, as it defines
the way in which the goals of the enterprise are
achieved.
To sufficiently define a process, firstly the proc-
ess activities need to be identified, and then the se-
quence order of the identified activities needs to be
established. Resources are origins of supply, mate-
rial assets required to activate process activities and
are consequently twofold; capital assets and labour
(Laguna and Marklund, 2005). They are exploited
within the process but not consumed.
To identify business processes, we organize in-
terviews with the management at strategic and busi-
ness levels. The purpose of the interviews with stra-
tegic management is to define the strategic goals and
objectives of the enterprise. After that, we continue
conducting interviews with the management at busi-
ness level. Actually, the results of these interviews
are valuable information, which enable us to create a
list of business processes of the organization dis-
cussed. In addition, the interviews are also useful in
discovering the organizational scheme of the enter-
prise.
Surgery: The management of a Clinic of ab-
dominal surgery wished to improve this process of
conducting a surgery by making it more efficient
and less time consuming. As a result of conducting
interview with the management, one business proc-
ess was identified called Surgery, which covers the
whole problem discussed.
3 PROCESS MODELLING
Conceptual modelling of business processes is de-
ployed on a large scale to facilitate the development
of software that supports the business processes, and
to permit the analysis and re-engineering or im-
provement of them (Aguilar-Saven, 2003).
The business process modelling system is a
computer-based, potential solution to these prob-
lems. It is a system for managing a series of tasks
(actions) defined for one or more procedures
(Scholz-Reiter and Sticker, 1996). Business process
modelling generates a model to describe a certain
business process in an enterprise using different
techniques. A model is a representation of a business
process, which reflects its reality by capturing all the
necessary information on process behaviour. The
modelled process is then analysed and improved in-
stead of the real business process.
To model a business process, we continue with
organizing interviews with the employees of de-
partments corresponding to the plan of interviews
developed earlier. The aim of these interviews is to
define in detail the work processes of the process
identified and their activities.
Work processes are the sets of procedures or ac-
tivities, tasks, and steps where the real work of the
organization is accomplished to produce the eco-
nomic output that generates the profitable return on
the capital employed (Watson, 1994). There are
many methods and techniques used in the field of
business process modelling. In the framework of this
paper the flowchart technique was chosen to model
business process Surgery. A flowchart is a simple
diagram, which is used to model business processes
in software packages such as iGrafx. In addition to
process modelling, iGrafx also enables us to perform
simulation of the modelled processes. The paper
does not discuss simulation; as such a discussion
would exceed the scope of this paper.
The flowchart technique defines a flowchart as a
formalised graphical representation of a program
logic sequence, work or manufacturing process, or-
ganisation chart, or similar formalised structure
(Lakin et al., 1996). A flowchart is commonly used
to show the flow of a process from its start to its end.
It usually consists of different symbols connected by
lines, arranged in such a way to lead us through a se-
ries of steps in the correct sequence order.
Process flow is traced by following the connect-
ing lines between the symbols drawn. These sym-
bols include: start and end, activity, input and out-
put, decision, and department. A flowchart begins
with a starting point and finishes with an ending
point. The terminus symbol is commonly used in
flowcharting to designate the beginning and the end.
An activity is represented by a rectangle and
means an elementary task. An input is indicated by
an arrow, which enters an activity. An output is
shown by an arrow, which leaves an activity. An ar-
row connects one activity to another, showing the
movement of the diagram. A decision specifies al-
ternative paths based on some Boolean expression
and is shown by a diamond. There can be only one
IMPROVEMENT OF BUSINESS PROCESS SURGERY USING SIMULATION
435
path to a decision, but there can be many output
paths (Arlow, Neustadt, 2002).
According to Aguilar-Saven (2003) flowcharts
are built to offer an enhanced comprehension of the
processes, which is a requirement for process im-
provement. By grouping tasks into logical areas of
activity (processes) and drawing flowcharts of the
events which occur, it is possible to get a concise
picture of the way particular processes are com-
pleted within the organisation
1
. The flexibility of the
flowchart technique is argued by many to be its ad-
vantage as it allows each modeller to unite various
pieces of the process together to gain the overall pic-
ture as he/she feels they fit best. On the other hand,
some argue that the technique is too flexible, de-
scribing large models without illustrating the hierar-
chy of different layers.
4 PROCESS SIMULATION
Business processes are modelled with the aim of
analysing their current states within the organization,
as well as improving them through the execution of
potential “what-if” simulation scenarios (Aguilar-
Saven and Olhager, 2002). Simulation modelling ac-
cording to Pidd (1998) is based on very simple prin-
ciples: the analyst builds a model of the system of
interest, writes a computer program which embodies
the model and uses a computer to initiate the sys-
tem’s behaviour when subject to a variety of operat-
ing policies. Simulation is the imitation of the opera-
tion of a real-world process or system over time
(Banks et al., 2001). A simulation model enables the
analyst to observe and study the system’s behaviour
as it advances through time.
The aim of using simulation is to analyse the cur-
rent or the alternative version of the business process
discussed in order to determine its behaviour and
carry out further improvements by solving problems,
removing obstacles and identifying bottlenecks ex-
isting in the process.
To run the simulation, we have to transform the
content of the activity table into a flowchart or other
diagram depending on the simulation software used.
In our example, we used the flowchart diagram be-
cause iGrafx software was used to run the simulation
of the process. Furthermore, the information stored
about the activities of the business process was used
to define the characteristics of the activities and de-
velop the process model as is required by iGrafx
1
http://www.hci.com.au/hcisite2/toolkit/flowchar.htm
software. The step of process simulation could be
summarized by using the following algorithm:
a. create the process diagram (flowchart);
b. develop the process model by defining the
properties of each activity;
c. define process simulation parameters and run
the simulation;
d. analyse carefully the simulation results;
e. make changes to improve the process if pos-
sible; and
f. return to c if changes have been made.
Surgery: To carry out simulation of the business
process “Surgery”, the process model was built by
using the information stored about the process and
its activities to define the model’s characteristics.
The simulation of the process “Surgery” was run
taking into consideration a Clinic for abdominal sur-
gery with a capacity of 30 beds; 20 patients were al-
ready in the Clinic in different phases of the process,
and 30 patients were scheduled for different forms
surgeryIn addition to this, we postulated that 3 pa-
tients from the planned 30 patients were hospitalized
every day. To do that, a standard calendar was used,
that is, 8 hours/day, 5 days/week and 22 days/month.
And the following resources were defined: 1 Nurse
and 1 Doctor in the Reception Office, 4 Nurses and
4 Surgeons in the Clinic, 1 Nurse in the Laboratory,
1 Nurse and 1 Doctor in the X-Ray unit, 1 Nurse and
1 Doctor in Anaesthesia, 2 Anaesthetists and 2
Nurses for performing anaesthesia in the Surgery
block, 2 Anaesthetists and 2 Nurses for waking up
patients and post-surgery recovery in the Surgery
block, and 2 Nurses working with the Surgeons to
carry out operations in the Surgery Block.
The results of running the simulation of the busi-
ness process “Surgery” were as follows:
Average cycle time for one patient is 14.68 days;
Elapsed time for carrying out surgery for 30 pa-
tients is 25.57 days. This is understandable be-
cause the software needed 10 days to enter 30
patients into the Clinic (3 patients per day);
Average time for performing different activities
before surgery is 2.94 days. This is 1.43 days for
performing various medical examinations in the
Reception Office and Clinic, and 1.51 days wait-
ing for surgery;
Average time for performing anaesthesia, sur-
gery and post-surgery recovery in the Surgery
block is 7.1 hours;
HEALTHINF 2009 - International Conference on Health Informatics
436
Average time for recovery in Intensive care is
4.26 days;
Average time for recovery in the Clinic is 6.39
days;
Average time for creating a release form is 0.78
hour.
These results show that the process “Surgery”
could be improved by considering the following
suggestions:
The time for performing different activities be-
fore surgery (average is 2.94 days) could be
shortened by carrying out most of these activities
before the patient’s hospitalization or organizing
them better;
The recovery time in Intensive care (average is
4.26 days) should be reduced when possible;
The recovery time in Clinic (average is 6.39
days) should be shortened when possible.
5 CONCLUSION
Developing a visible and comprehensible model,
which represents a true reflection of the real busi-
ness process, is essential in making the task of proc-
ess analysis and identification of the necessary
changes possible. The aim of this work was to study
the possibility of using simulation technique for car-
rying out business process improvement.
To carry out the improvement of the business
process “Surgery”, process model was developed as
a flowchart diagram of iGrafx software to run a
simulation of the process. The results of the process
simulation are very encouraging and show that the
process “Surgery” is well planned and does not have
major problems. Nevertheless, the process could be
improved by shortening the time of 2.94 days spent
before surgery; this is 1.43 days for performing dif-
ferent medical examinations in the Reception Office
and Clinic and 1.51 days waiting for surgery. Some
of the medical examinations could be done before
hospitalization and also the time of waiting for sur-
gery could be shortened. Furthermore, the recovery
time in Intensive care (4.26 days) and the Clinic
(6.39 days) could be reconsidered.
We are aware that these suggestions cannot be
generalized for all patients, but they are good points
for the medical staff to rethink. This fact proves that
using simulation in the field of business process im-
provement could be very important.
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