Supplier selection using AHP methodology extended by D numbers


Supplier selection using AHP methodology extended by D numbers

Xinyang Deng a,1, Yong Hu b,1, Yong Deng a,c,⇑, Sankaran Mahadevan c
a School of Computer and Information Science, Southwest University, Chongqing 400715, China
b Institute of Business Intelligence and Knowledge Discovery, Guangdong University of Foreign Studies, Sun Yat-Sen University, Guangzhou 510006, China
c Department of Civil and Environmental Engineering, School of Engineering, Vanderbilt University, Nashville, TN 37235, USA

a r t i c l e i n f o

Keywords:
Supplier selection
D numbers
D-AHP
Analytic hierarchy process
Fuzzy preference relation

a b s t r a c t

Supplier selection is an important issue in supply chain management (SCM), and essentially is a
multi-criteria decision-making problem. Supplier selection highly depends on experts’ assessments. In
the process of that, it inevitably involves various types of uncertainty such as imprecision, fuzziness
and incompleteness due to the inability of human being’s subjective judgment. However, the existing
methods cannot adequately handle these types of uncertainties. In this paper, based on a new effective
and feasible representation of uncertain information, called D numbers, a D-AHP method is proposed
for the supplier selection problem, which extends the classical analytic hierarchy process (AHP) method.
Within the proposed method, D numbers extended fuzzy preference relation has been involved to repre-
sent the decision matrix of pairwise comparisons given by experts. An illustrative example is presented to
demonstrate the effectiveness of the proposed method.

� 2013 Elsevier Ltd. All rights reserved.

1. Introduction

Supply chain management (SCM) has emerged as an important
element in improving the global competitiveness of companies in
the highly competitive global economy (Othman & Ghani, 2008;
Gunasekaran & Ngai, 2005). One of the key problems in SCM is sup-
plier selection (Wu and Barnes, 2011; Huang and Keskar, 2007, i.e.,
find the best supplier among several alternatives according to var-
ious criteria, such as cost, service, risk and others. This is a compli-
cated multi-criteria decision-making problem (Chai, Liu, & Ngai,
2013). The identification of criteria and integration of experts’
assessments are two components of the supplier selection
problem.

With respect to the identification of criteria, selection of criteria
and calculation of priority weights both should be considered. Lee,
Kang, Hsu, and Hung (2009) investigated the green supplier selec-
tion problem for high-tech industry, and identified six criteria,
namely quality, technology capability, pollution control, environ-
mental management, green production and green competency. In
the automobile industry, Govindan, Kannan, and Haq (2010) devel-
oped a framework to identify and rank the associated criteria, for
instance asset specificity and supplier performance. Aksoy and
Ozturk (2011) explored the problem of supplier selection in
just-in-time (JIT) production environments. It is worth noting that

environmental criteria have gradually begun to attract increasing
attention in supplier selection. Humphreys, Wong, and Chan
(2003) identified seven environmental categories, including envi-
ronmental costs (pollutant effects), environmental costs (improve-
ment), management competencies, ‘‘green’’ image, design for
environment, environmental management systems, and environ-
mental competencies.

Generally speaking, the criteria for supplier selection highly de-
pend on individual companies and industries. On the one hand, dif-
ferent companies have different organizational structure,
management strategy, enterprise culture and others. All of these
influence the determination of supplier selection criteria. On the
other hand, industry background causes huge difference and
greatly impacts the selection of suppliers. Therefore, the identifica-
tion of supplier selection criteria are on the basis of specific envi-
ronments, and largely requires domain experts’ assessment and
judgement.

After identifying the criteria, a methodology is needed to inte-
grate experts’ assessments in order to find the best supplier. At
present, various methods have been applied to supplier selection,
such as the analytic hierarchy process (AHP) (Chan, 2003; Wang,
Chin, & Leung, 2009), fuzzy set theory (Ordoobadi, 2009; Labib,
2011), fuzzy extended AHP method (Chan & Kumar, 2007; Chan,
Kumar, Tiwari, Lau, & Choy, 2008; Kilincci & Onal, 2011), TOPSIS
method (Boran, Genc, Kurt, & Akay, 2009; Deng, 2006; Wang,
Cheng, & Kun-Cheng, 2009; Zouggari & Benyoucef, 2012),
Dempster–Shafer evidence theory (Deng & Chan, 2011) and others
(Chen & Chao, 2012; Ferreira & Borenstein, 2012; Ng, 2008; Sana-
yei, Mousavi, & Yazdankhah, 2010). Among these methods, AHP

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http://dx.doi.org/10.1016/j.eswa.2013.07.018

⇑ Corresponding author at: School of Computer and Information Science, South-
west University, Chongqing 400715, China.

E-mail addresses: ydeng@swu.edu.cn, prof.deng@hotmail.com (Y. Deng).
1 These authors contributed equally to this work.

Expert Systems with Applications 41 (2014) 156–167

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(Ngai & Chan, 2005; Saaty, 1980) is popular and extensively used to
deal with complex decision problem due to its simplicity in con-
cept and convenience in operation. Even so, its inability to ade-
quately handle the inherent uncertainty and imprecision in the
data is also often criticized. The fuzzy extended AHP method (Buy-
ukozkan, Cifci, & Guleryuz, 2011; Chan & Kumar, 2007; Chan et al.,
2008; Sadiq & Tesfamariam, 2009; Wang, Luo, & Hua, 2007) pro-
vides the ability to handle the fuzziness in the experts’ subjective
judgment with the aid of fuzzy set theory. However, the inconsis-
tency of the fuzzy evaluation comparison matrix is still an open is-
sue (Leung & Cao, 2000; Wang & Chen, 2008). Some researchers
have studied the concept of fuzzy preference relation (Chen &
Chao, 2012; Garcia, del Moral, Martinez, & Herrera-Viedma,
2012; Herrera-Viedma, Herrera, Chiclana, & Luque, 2004; Herre-
ra-Viedma, Alonso, Chiclana, & Herrera, 2007; Lee, 2012; Tanino,
1984; Wang & Fan, 2007; Xu, 2007) which directly enables the fuzz-
iness of preference relation to be represented in the form of mem-
bership function. Yet the method of fuzzy preference relation is
still unable to handle situations when the information is incomplete.

Supplier selection highly depends on large amounts of domain
knowledge, where experts’ assessments play an important role.
However, various uncertainties are present in domain experts’ sub-
jective and qualitative judgment, such as imprecision, fuzziness,
incompleteness and so on. Therefore it is necessary to develop a
more effective method for supplier selection, which should be able
to handle various types of uncertainties (Kara, 2011; Li & Zabin-
skys, 2011; Wu, 2009).

In order to effectively handle various uncertainties involved
in the supplier selection problem, a new representation of uncer-
tain information, called D numbers (Deng, 2012), is presented in
this paper. The concept of D numbers extends the Dempster–
Shafer evidence theory (Dempster, 1967; Shafer, 1976), and is
more effective in representing uncertain information, as dis-
cussed later. Secondly, a D numbers-based preference relation
is proposed by extending the fuzzy preference relation approach.
The proposed D numbers preference relation overcomes the defi-
ciency of fuzzy preference relation. Finally, the AHP method is
extended using the D numbers-based preference relation, leading
to the proposed D-AHP method for decision-making under
uncertain information.

The rest of this paper is organized as follows. Section 2 gives a
brief introduction to the classical AHP method. Section 3 develops
the proposed D-AHP method for supplier selection. It contains the
introduction of D numbers and fuzzy preference relation, the con-
cept of D numbers preference relation, the calculation of priority
weights and inconsistency degree in D numbers preference rela-
tion, and the D-AHP method. After that, an illustrative example
of supplier selection is given to show the effectiveness of the pro-
posed D-AHP method in Section 4. Finally, Section 5 concludes the
paper.

2. Analytic hierarchy process (AHP)

AHP Saaty (1980) is a structured technique for handling com-
plex decision problems. Both qualitative and quantitative factors
are combined by using AHP in the decision-making process.

Generally, the process of applying AHP can be divided into three
steps. First, establish a hierarchical structure by recursively decom-
posing the decision problem. Second, construct the pairwise com-
parison matrix to indicate the relative importance of alternatives. A
numerical rating including nine rank scales is suggested, as shown
in Table 1. Third, calculate the priority weights of alternatives
according to the pairwise comparison matrix by the following
equation:

Aw ¼ kmaxw; w ¼ðw1; w2; . . . ; wnÞ
T ð1Þ

where A is a n dimensional comparison matrix, kmax is the largest
eigenvalue of A and w is the eigenvector corresponding to kmax.

In AHP, a consistency index (C.I.) is defined to measure the
inconsistency within the pairwise comparison matrix A.

C:I: ¼
kmax � n

n � 1
ð2Þ

Accordingly, the consistency ratio C.R. is used to measure the degree
of C.I. by the following equation:

C:R: ¼
C:I:
R:I:

ð3Þ

where R.I. is the random consistency index, its value is related to the
dimension of the matrix, listed in Table 2.

If C.R. < 0.10, the inconsistency degree of the comparison matrix
A is consider acceptable and the eigenvector w is used as the
weighting vector after normalization. Otherwise, the comparison
matrix needs to be adjusted.

3. D-AHP for supplier selection

3.1. D numbers

Information about the real world is affected by many sources of
uncertainty. Many existing theories, such as probability theory,
fuzzy set theory (Zadeh, 1965), Dempster–Shafer evidence theory
(Dempster, 1967; Shafer, 1976), have been developed to model
various types of uncertainty, and provide some desirable proper-
ties. But these theories, however, still contain deficiencies that can-
not be ignored. Take Dempster–Shafer evidence theory as an
example. Due to its inherent advantages in the representation
and handling of uncertain information, the Dempster–Shafer evi-
dence theory is being studied for use in many fields, such as
decision analysis, pattern recognition, risk assessment, supplier
selection and others (Dempster, 1967; Deng, Shi, Zhu, & Liu,
2004; Deng, Su, Wang, & Li, 2010; Deng, Chan, Wu, & Wang,
2011; Deng, Sadiq, Jiang, & Tesfamariam, 2011; Deng, Jiang, &
Sadiq, 2011; Deng, Liu, Hu, & Deng, 2013; Kang, Deng, Sadiq, &
Mahadevan, 2012; Liu, Chan, Li, Zhang, & Deng, 2012; Sadiq, Klein-
er, & Rajani, 2006; Sadiq, Najjaran, & Kleiner, 2006; Sadiq, Kleiner,
& Rajani, 2007; Shafer, 1976; Zhang, Deng, Wei, & Deng, 2012; Wei,
Deng, Zhang, Deng, & Mahadevan, 2013). In the mathematical
framework of Dempster–Shafer theory, the basic probability
assignment (BPA) defined on the frame of discernment is used to
express the uncertainty in judgement. A problem domain indicated
by a finite non-empty set X of mutually exclusive and exhaustive
hypotheses is called a frame of discernment. Let 2X denote the
power set of X, a BPA is a mapping m:2X ? [0, 1], satisfying

mð;Þ¼ 0 and
X
A22X

mðAÞ¼ 1 ð4Þ

Table 1
Numerical rating in the AHP method.

Scale Meaning

1 Equal importance
3 Moderate importance
5 Strong importance
7 Demonstrated importance
9 Extreme importance
2, 4, 6, 8 Intermediate values

Table 2
Random consistency index R.I.

n 1 2 3 4 5 6 7 8 9 10

R.I. 0 0 0.52 0.89 1.12 1.26 1.36 1.41 1.46 1.49

X. Deng et al. / Expert Systems with Applications 41 (2014) 156–167 157



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