Partner Selection in Formation of Virtual Enterprises using Fuzzy
Logic
Shahrzad Nikghadam
1
, Bahram Lotfi Sadigh
1
, Ahmet Murat Ozbayoglu
2
, Hakki Ozgur Unver
3
and
Sadik Engin Kilic
4
1
Department of Mechanical Engineering, Middle East Technical University, Ankara, Turkey
2
Department of Computer Engineering, TOBB University of Economics and Technology, Ankara, Turkey
3
Department of Mechanical Engineering, TOBB University of Economics and Technology, Ankara, Turkey
4
Department of Mechanical Engineering, Atilim University, Ankara, Turkey
Keywords: Virtual Enterprise, Partner Selection, Fuzzy Logic.
Abstract: Virtual Enterprise (VE) is a temporary cooperation among independent enterprises to build up a dynamic
collaboration framework for manufacturing. One of the most important steps to construct a successful VE is
to select the most qualified partners to take role in the project. This paper is a survey of ranking the
volunteer companies with respect to four evaluation criteria, proposed unit price, delivery time, quality and
enterprises’ past performance. Fuzzy logic method is proposed to deal with these four conflicting criteria,
considered as input variables of the model. As each criterion is different in nature with the other criterion,
various membership functions are used to fuzzify the input values. The next step is to construct the logical
fuzzy rules combining the inputs to conclude the output. Mamdani’s approach is adopted to evaluate the
output in this Fuzzy Inference System. The result of the model is the partnership chance of each partner to
participate in VE. A partner with highest partnership chance will be the winner of the negotiation.
Implementation of this model to the illustrative example of a partner selection problem in virtual enterprise
and comparing it with fuzzy-TOPSIS approach verifies the feasibility of the proposed approach and the
computational results are satisfactory.
1 INTRODUCTION
In today’s increasingly competitive dynamic global
market, traditional manufacturing concepts cannot
satisfy the diverse customer demands. Small
companies are suffering from limited resources
while large companies are inflexible (Huang, et al.,
2004). Providing adequate resources for Small and
Medium Sized Enterprises (SMEs) are often very
costly and time consuming. Constructing a synergic
cooperation between these enterprises will aid
companies to share their resources without losing the
flexibility. Virtual Enterprise (VE) is proved to be
one of the effective cooperation platforms.
VE is a network based temporary alliance
between independent and geographically dispersed
enterprises to share skills, core competencies and
resources, in order to catch business opportunities
(Camarinha-Matos & Afsarmanesh, n.d.).This kind
of consortium will help companies for responding
quickly to unanticipated demands from customers.
Lifecycle of VE consists of three main phases;
Formation, Operation and Dissolution. The
Formation phase of a VE is usually triggered by a
request for quote from customer. Based on the
project, design specifications and manufacturing
requirements, production processes are decomposed
into individual task(s). The main step of VE
formation phase is to select the best partners to
participate in forthcoming VE consortium. In order
to fulfil the project, each individual task should be
completed by selected VE partner(s). After the
operation phase of VE which includes
manufacturing and assembly processes, getting
customer’s consent and achieving the goal(s) VE
project is finalized and it can be dissolved.
The most important part of VE formation phase
is the partner selection step. In order to form up a
successful VE consortium it is crucial to select the
most appropriate partners from list of potential
partners registered in virtual breeding environment.
This is why there are lots of researches conducted in
this field. However, due to neglecting the dynamic
82
Nikghadam S., Lotfi Sadigh B., Murat Ozbayoglu A., Ozgur Unver H. and Engin Kilic S..
Partner Selection in Formation of Virtual Enterprises using Fuzzy Logic.
DOI: 10.5220/0005293000820088
In Proceedings of the International Conference on Operations Research and Enterprise Systems (ICORES-2015), pages 82-88
ISBN: 978-989-758-075-8
Copyright
c
2015 SCITEPRESS (Science and Technology Publications, Lda.)
nature of VE and heterogeneity of customer
preferences (decision making criteria), much of the
proposed methods are not generic solutions and
cannot be implemented directly in different decision
making problems.
Partner selection is not a simple optimization
problems (Sari, et al., 2007). Regarding the fact that,
it is very difficult to express the qualitative criteria
with precise values in digits and considering the
nature of quantitative criteria which are represented
in numbers, handling the quantitative criteria
mathematically is much easier than including
qualitative criteria in mathematical models (Ye,
2010).
The other difficulty of decision making is that it
involves conflicting criteria. If there is a potential
partner with best score in all criteria surely that
company is the best; however generally this is not
the case in practical applications. For instance a high
quality product usually comes with expensive price.
Hence there is an inevitable trade-off between
criteria which is done on the basis of customer’s
preferences.
Importance of partner selection problem along
with complexity of this subject drew the attention of
many researchers. Some approaches use Artificial
Intelligence techniques such as Genetic Algorithm to
solve the partner selection’s mathematical model
(Fuqing, et al., 2005), where Sari et al. propose
Analytic Hierarchy Process (AHP) to perform
pairwise comparisons between criteria and
alternatives (Sari, et al., 2007). In these
methodologies quantitative criteria are assigned with
a crisp value, neglecting the subjective nature of
them. In contrast, most of the papers in the literature
are hybrid fuzzy approaches which are capable of
handling the imprecision of input data. Mikhailov
and Fei propose Fuzzy-AHP and Fuzzy-TOPSIS
methods respectively (Ye, 2010), (Mikhailov, 2002).
In a study conducted by Bevilacqua and Petroni
fuzzy logic is employed in specifying the relative
importance (weight) given to criteria and in
determining the impact of each supplier on the
attributes considered (Bevilacqua & Petroni, 2010).
Yet this study is conducted in the field of supplier
selection of supply chain management (SC) and
there is insufficient research for applying fuzzy logic
approach in partner selection problem of VE.
Selection of partner enterprises in creation of
virtual enterprise has much in common with supplier
selection of supply chain management. They both
evaluate the companies and try to find the best
alternative with respect to number of factors.
However they are not completely identical. VE is
more dynamic in comparison to SC. Supplier
selection of SC designed for a specific set of
processes, while VE can emerge for fulfilling
different types of projects and customers so VE is
more dynamic in comparison to SC.
The method proposed in this paper is based on
applying fuzzy logic to deal with uncertainty of the
problem; in addition it considers “criteria-specific
membership functions” which is a fact neglected in
the literature to the best of our knowledge.
The remainder of this paper is organized as
follows: Section 2 reviews some background
information about fuzzy logic. Section 3 explains
and discusses the developed model in details. An
illustrative example is presented in section 4 and the
results of proposed model is compared with fuzzy-
TOPSIS model. Conclusions are discussed and
future research scopes are recommended in the last
section.
2 FUZZY LOGIC
Lotfi A. Zadeh published the theory of fuzzy set
mathematics in 1965 and fuzzy logic by extension.
(Zadeh, 1965). Fuzzy set is a valid supporting tool to
overcome uncertainty (Bevilacqua & Petroni, 2010).
Fuzzy Inference system is a popular reasoning
framework based on the concepts of fuzzy set
theory, fuzzy logic and fuzzy IF-THEN rules. Fuzzy
Inference systems make decisions based on inputs in
the form of linguistic variables derived from
membership functions. These variables are then
matched with the preconditions of linguistic IF-
THEN rules called fuzzy logic rules, and the
response of each rule is obtained through fuzzy
implication as a crisp value (Shing & Jang, 1993).
Mamdani fuzzy inference is the most commonly
used inference method introduces by Mamdani in
1975 (Mamdani & Assilian, 1975). The fuzzy
inference involves four steps: 1. Fuzzification of
input variables, 2. Rule Evaluation, 3. Aggregation
of the rule outputs, 4. Defuzzification.
The first step of fuzzy inference system is
calculating the membership degree of inputs to their
belonging fuzzy sets. In the second step fuzzified
values of inputs are used to evaluate fuzzy rules.
Fuzzy rules are contain fuzzy operators (AND or
OR). The next step is aggregating the fuzzy outputs
of all rules. The last step of fuzzy inference process
is defuzzifying the output, conclude the final crisp
value and rank the results.
PartnerSelectioninFormationofVirtualEnterprisesusingFuzzyLogic
83
3 PARTNER SELECTION
MODEL
Among tens of aspects to evaluate the partners to
join virtual enterprise, in this research, four main
criteria are taken into account; proposed unit price,
proposed delivery time, company’s products quality
and its past performance. According to the industry
experts, these four criteria are believed to be the
most essential aspects to evaluate the enterprises.
First two criteria are proposed by each enterprise
during negotiation process. The values of last two
criteria are imported from quality and performance
evaluation models which are available in the system.
The proposed values of price and delivery time are
normalized using Euclidean normalization method.
After calculating the values of enterprises for each
criterion, these values are fuzzified with respect to
the corresponding membership functions. Due to
different nature of each criterion, different sets and
membership functions are defined.
3.1 Input Variables of Fuzzy Logic
First step to implement the model is to translate the
linguistic variables into fuzzy numbers through
defining the appropriate membership functions.
Using different membership functions to calculate
the value of each criterion is the novelty introduced
in this paper, compared to the researches in the
literature. i.e. different types of membership
functions are selected in order to fit the actual
pattern of each factor.
3.1.1 Unit Price
Since the price proposals are absolute values, the
corresponding membership functions must be linear
in order to maintain the competitiveness between
candidates. Even a dollar less, means cheaper price.
This should not be ignored in fuzzification process.
So, three triangular membership function are used to
model the fuzzy behaviour of unit price proposed by
enterprises, as shown in Fig.1.
Figure 1: Unit Price’s membership functions.
The membership function are as follows:
Inexpensive (0; 0; 0.5)
Moderate (a
1
; 0.5; b
1
)
Expensive (0.5; 1; 1)
3.1.2 Delivery Time
The membership functions of delivery time are also
linear. However, they consist of domains which,
within that range, the fuzzified values of scores are
equal. Generally Project Evaluation Review
Technique (PERT) is used to calculate the Earliest
Finish and Latest Finish. The range between these
two due dates is a favourable domain.
If a task cannot be completed on time it will be
back order charging some penalties (Nikghadam, et
al., 2011). If lateness exceeds, the order will be lost
and it cannot be compensated, this is a domain
which membership function has a constant value
equal to one. As too early delivery imposes storage
costs its trend is similar to late delivery. Trapezoidal
membership function is providing all the
characteristics required to model the delivery time.
The membership functions are shown in Figure 2.
Too Early (0; 0; a
2
; c
2
)
Favourable (b
2
; d
2
; e
2
; g
2
)
Late (f
2
; h
2
; 1; 1)
3.1.3 Quality
Similar to delivery time, there are constant-valued
domains for membership functions of quality.
Quality specifications are generally defined by an
acceptable “range”, all the values within these limits
are satisfactory. Furthermore, considering the
marginality of human decisions bell-shaped
membership function are most suitable to model the
problem as shown in Figure 3. Parameters of a
3
and
b
3
are determining the shape of the curves.
Less than Required (a
3
; b
3
; 1.5; 0)
Satisfactory (a
3
; b
3
; 0.5)
More than Required (a
3
; b
3
; 1)
Figure 2: Delivery time’s membership functions.
ICORES2015-InternationalConferenceonOperationsResearchandEnterpriseSystems
84
Figure 3: Quality’s membership functions.
3.1.4 Past Performance
Past performance of a company is a criterion
representing the customer’s satisfaction degree,
which is influenced by several factors such as after
sale service; respond to changes; communication
openness and etc. Similar to the nonlinear trend of
quality, past performance’s membership function is
not linear due to marginality. Increasing customer’s
consent is more demanding at higher scores. So two
simple Gaussian membership functions are defined.
These membership functions are shown in Fig. 4.
Parameter a
4
is specifying the shape of the curves.
Poor (a
4
; 0)
Good (a
4
; 1)
Figure 4: Past performance's membership functions.
3.2 Output Variable of Fuzzy Logic
Output variable of this model is partner’s acceptance
chance to join VE consortium. This model reveals a
method to calculate this value by getting two
bidding proposals (price and delivery time) and two
performance evaluation value from enterprise
background (quality and enterprise past
performance). An enterprise with competitive
proposals and good background will have higher
chance to be picked out as a winner to take role in
virtual enterprise rather than other rival enterprises.
3.2.1 Partnership Chance
As shown in Fig. 5 three triangular membership
functions are used to define fuzzy set of the output.
Usually enterprises violating the project
requirements belong to the first membership
function and their partnership chance are low. The
third membership function members are those which
can satisfy almost all the necessities of four inputs
and the enterprises belonging to this set are most
likely to be accepted as partner. While the members
of second membership function, are potential partner
enterprises which cannot be classified in first or
third membership function groups and have the
medium partnership chance.
Low (0; 0; 0.5)
Medium (a
5
; 0.5; b5)
High (0.5; 1; 1)
3.3 Fuzzy Logic Rules
Once the inputs are fuzzified, fuzzy rules should be
defined. Fuzzy rules are made up of linguistic
statements which describe how to make decisions
considering the inputs.
If (input 1 is membership function1) AND/OR
(input 2 is membership function 2) THEN (Output n
is membership function n)
Figure 5: Partnership chance’s membership functions.
Rules are established based on customer
preferences. By asking the decision maker(s) to fill
the questionnaire, the relative importance of each
criterion is extracted.
For instance an enterprise producing the low
quality product which do not met the system
predefined specifications or unable to get customer
consent about delivery time is not competitive, has
low partnership chance.
All the possible combinations should be
considered for constructing fuzzy rules to ensure the
validity of the model. More descriptive fuzzy rules
will be presented for the case of our study.
Establishing the IF-THEN rules are the most
important step of the method since even a single
improper rule will cause untrustworthy results.
According to these fuzzy rules, fuzzy inputs will
be combined and evaluated by Mamdani’s fuzzy
inference system to find the partnership chance as
this model’s output.
PartnerSelectioninFormationofVirtualEnterprisesusingFuzzyLogic
85
4 ILLUSTRATIVE EXAMPLE
In order to illustrate the application of fuzzy logic
method to partner selection problem in formation of
virtual enterprise a simplified example is considered.
A virtual enterprise has received an order from a
customer to manufacture the component shown in
Figure 6. There are four candidate enterprises eager
to take role in project. Bidding starts in order to
identify the best proposal from the best company.
The evaluation procedure is based on fuzzy logic
approach presented in previous section.
Bidding Proposals and candidates’ scores are
shown in Table 1. The values of input variables,
price and delivery time are proposed by each
company, while the scores of quality and past
performance which are feedback-oriented are out of
10. Table 2 shows the normalized values of Table 1.
Figure 6: Component sketch for illustrative example.
Table 1: Scores of enterprises with respect to criteria.
Unit Price
($)
Delivery Time
(days)
Quality
(Out of 10)
Past
Performance
(Out of 10)
Co. A 1700 8 4 5
Co. B 1700 10 5 4
Co. C 2000 12 5 3
Co. D 1500 10 6 5
Table 2: Normalized scores of enterprises with respect to
criteria.
Unit Price
Delivery
Time
Quality
Past
Performance
Co. A 0.49 0.396 0.396 0.577
Co. B 0.49 0.495 0.495 0.346
Co. C 0.577 0.594 0.495 0.462
Co. D 0.432 0.495 0.594 0.577
These values are fuzzified according to the
membership functions specified for each criterion.
Regarding the customer preference based- fuzzy
rules shown in Table 4, companies’ partnership
chance is evaluated and tabulated in Table 4.
With three levels for unit price, delivery time,
quality and two levels for past performance there are
total of 3×3×3×2=54 possible combinations if all the
rules are defined by ‘AND’ operator. Though, to
simplify the rule list, one rule is defined as below;
If (Delivery time is Late) OR (Quality is Less
than Required) THEN (Partnership Chance is Low)
Table 3: Set of fuzzy rules.
IF
THEN
Price
Delivery
Time
Quality
Past
Performance
Partnership
Chance
- Late OR Less than req. - Low
inexpensive And too early And satisfactory And poor medium
inexpensive And too early And satisfactory And good medium
inexpensive And too early And more than req. And poor medium
inexpensive And too early And more than req. And good medium
inexpensive And favorable And satisfactory And poor high
inexpensive And favorable And satisfactory And good high
inexpensive And favorable And more than req. And poor high
inexpensive And favorable And more than req. And good high
average And too early And satisfactory And poor low
average And too early And satisfactory And good low
average And too early And more than req. And poor low
average And too early And more than req. And good medium
average And favorable And satisfactory And poor medium
average And favorable And satisfactory And good medium
average And favorable And more than req. And poor High
average And favorable And more than req. And good high
expensive And too early And satisfactory And poor low
expensive And too early And satisfactory And good medium
expensive And too early And more than req. And poor low
expensive And too early And more than req. And good medium
expensive And favorable And satisfactory And poor low
expensive And favorable And satisfactory And good medium
expensive And favorable And more Than req. And poor low
expensive And favorable And more Than req. And good medium
By doing this, just two levels are left for delivery
time and quality. As (3×2×2×2)+1= 25, all the
ICORES2015-InternationalConferenceonOperationsResearchandEnterpriseSystems
86
possible combinations are included by defining 25
rules to build up a reliable model for the case of our
study.
The output of the model is calculated using fuzzy
logic toolbox of MATLAB software. And tabled in
Table 4.
Table 4: Companies’ partnership chance based on fuzzy
logic.
Partnership Chance (%)
Co. A 53.5
Co. B 51.8
Co. C 39.9
Co. D 61.0
In order to verify the fuzzy logic based model,
the results are compared with Fuzzy-TOPSIS
method developed by Chen et al. (Chen & Tsao,
2008). Customer preferences are calculated using
pairwise comparisons and allocating fuzzy numbers
for their subjective terminations. The final results of
criteria weights for our sample are set to be 0.394,
0.277, 0.257, and 0.106 for unit price, delivery time,
quality and past performance respectively (The rules
of fuzzy logic are also constructed considering these
preferences). Using the normalized values of Table 2
and multiplying them by their corresponding
weights are results in weighted performance matrix.
Then applying the TOPSIS procedure step by step
companies are ranked based on their closeness to the
ideal solution as shown in Table 5. The closest
candidate to the positive ideal solution has higher
partnership chance.
Regarding Table 6 the ranking lists proposed by
these two methods are same and both choose
Company D as a winner. However, their partnership
chances are not equal. There are two main reasons
which explains these differences. First, for
constructing fuzzy logic model different types of
functions; constant, linear and nonlinear are used.
Table 5: Companies’ partnership chance based on fuzzy
TOPSIS.
Distance from
Positive Ideal
Solution
Distance from
Negative Ideal
Solution
Closeness
(%)
Co. A 0.056 0.069 55.3
Co. B 0.05 0.051 50.2
Co. C 0.084 0.028 25.2
Co. D 0.027 0.085 75.5
This ability makes the model to be more sensitive to
changes in specific domains. Moreover, for criteria
such as delivery time and quality which have the
predefined “acceptable domain” all of the values
within this domain are identically same and does not
affect the overall score of candidate. These are the
facts neglected in Fuzzy-TOPSIS approach.
Table 6: Candidates ranking based on Fuzzy Logic and
Fuzzy TOPSIS methods.
Fuzzy Logic
Ranking List
Fuzzy TOPSIS
Ranking List
1
st
Co. D Co. D
2
nd
Co. A Co. A
3
rd
Co. B Co. B
4
th
Co. C Co. C
5 CONCLUSIONS
In this study, a fuzzy logic based model is proposed
for formation of virtual enterprise. The developed
approach provides an effective tool for ranking the
enterprises with respect to both quantitative and
qualitative criteria and selecting the best partner to
participate in virtual enterprise.
Unless many other techniques in literature,
specific membership functions are defined for each
criterion regarding their characteristics in order to
acquire more reliable outcomes. Besides, the other
strength of this method is; it provides a flexible
model to change the policies in a way decision
maker prefers. Not only fuzzy rules can be edited
considering customer preferences, but also
membership functions of four inputs and output can
be modified corresponding to bidding properties. In
contrast, models reliability is highly dependent on
stablishing reasonable fuzzy rules. Thus, the way to
get more accurate results and enhanced models
trustworthy is to define precise fuzzy rules by
consulting experienced industrial experts.
This study is a preliminary validation of the
model for further implementations in industry. The
verified model will be implemented in partner
selection process of forthcoming VE platform which
is going to be established in OSTIM organized
industrial park in Ankara.
ACKNOWLEDGEMENTS
This study is being funded by SAN-TEZ project No.
00979.stz.2011-12 of Turkish Ministry of Science,
PartnerSelectioninFormationofVirtualEnterprisesusingFuzzyLogic
87
Technology and Industry. Authors are sincerely
thankful for continuous support of OSTIM Industrial
Park management.
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