The Cardinal TOPSIS via Grey Relational Grade
Kunli Wen
1*
and Meili You
2
1
Department of Electrical Engineering Education, Chienkuo Technology University, Changhua, Taiwan
2
Department of General Education, Chienkuo Technology University, Changhua, Taiwan
Keywords: Soft computing, Technique for order preference by similarity to ideal solution, Globalization grey relational
grade, Objective weighting.
Abstract: Quite a lot of soft computing models have over the past few years been developed. They are developed to
meet different purposes and needs. These models, however, may not satisfy the technique for order
preference by similarity to ideal solution (TOPSIS). Aware of this phenomenon, the present study applied
globalization grey relational grade of the grey system to convert subjective weighting in the computing
process of technique for order preference by similarity to ideal solution into objective weighting. Data
analysis demonstrated that applying grey relational grade to cardinal technique for order preference by
similarity to ideal solution was not only rational but also could transfer ordinal answer into cardinal answer.
1 INTRODUCTION
The Technique for Order of Preference by Similarity
to Ideal Solution (TOPSIS), originally developed by
Hwang and Yoon in 1981, is a multi-criteria
decision analysis method. The fundamental
assumption of TOPSIS is that the criteria are either
monotonically increasing or decreasing. It is based
on the concept that the positive ideal solution is
composed of the best score in all criteria, given, for
instance, benefit as the maximal value and cost as
the minimum value. In contrast, the negative ideal
solution is composed of the worst score in all
criteria, given, for instance, benefit as the minimum
value and cost as the maximum value (Wen and
You, 2018). According to TOPSIS, a set of
alternatives is measured in terms of the Euclidean
norm to compare their closeness to the positive ideal
solution. TOPSIS is based on the concept that the
chosen alternative should have the shortest
geometric distance from the positive ideal solution
and the longest geometric distance from the negative
ideal solution. Such a method, according to Pi, can
prevent an alternative from being both the shortest
distance to the positive ideal solution and the
negative ideal solution on the one hand, and being
both the longest distance from the positive ideal
solution and the negative ideal solution on the other
hand (Pi, 2005).
A close observation of TOPSIS reveals that one
step of the TOPSIS utilizes subjective weighting for
analysis. Different weighting inevitably generates
different result. There has been research which
either focused on soft computing and environment
area such as grey entropy-TOPSIS method (Liu et
al., 2014), combined TOPSIS with grey relation to
decide the weighting of TOPSIS in contractor
selection (Zavadskas et al., 2010), compared fuzzy
AHP and fuzzy TOPSIS for road pavement
maintenance prioritization (Ouma et al., 2015), used
the AHP and TOPSIS approaches under fuzzy
environment (Shahab, 2016) or applied fuzzy
TOPSIS-TODIM hybrid method for green supplier
selection (Khamseh and Mahmoodi, 2014). (Qian et
al., 2009) was the only one study applying the grey
relation grade method to TOPSIS. The present study,
which was based on the research method mentioned
above, used cardinal grey relational grade to convert
subjective weighting into objective weighting (Wen,
2013). Section Two of this study discussed the
mathematical model related to the Technique for the
Order Preference by Similarity to Ideal Solution.
The third section investigated and ranked four kinds
of drinking water in Changhua County as to their
quality by using this soft computing method. The
last part of this paper provided research findings and
proposed suggestions for forthcoming research.
Wen, K. and You, M.
The Cardinal TOPSIS via Grey Relational Grade.
DOI: 10.5220/0008189002930296
In The Second International Conference on Materials Chemistry and Environmental Protection (MEEP 2018), pages 293-296
ISBN: 978-989-758-360-5
Copyright
c
2019 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
293
2 MATHEMATICS MODEL
The analysis procedure of TOPSIS and grey
relational grade is described step by step (Wen,
2016).
2.1 TOPSIS
1. Input the project data
mnmmm
n
n
n
xxxx
xxxx
xxxx
xxxx
D
321
3333231
2232221
1131211
(1)
2. Normalize the data in equation (1)
m
i
ij
ij
ij
x
x
r
1
2
(2)
then show normalization matrix in equation (3)
mnmmm
n
n
n
rrrr
rrrr
rrrr
rrrr
R
321
3333231
2232221
1131211
(3)
3. Decide the weighting of
],,,,[
321 ni
4. Calculate the weighting decision matrix
mnmmm
n
n
n
mnnmmm
nn
nn
nn
i
vvvv
vvvv
vvvv
vvvv
rrrr
rrrr
rrrr
rrrr
RV
321
3333231
2232221
1131211
332211
3333322311
2233222211
1133122111
(4)
5. Calculate the positive ideal solution
A
and
ideal negative solution
A
),,,,(}.{max
321
mi
vvvvvA
),,,,(}.{min
321
mi
vvvvvA
(5)
6. Calculate the positive ideal distance
i
S
and
negative ideal distance
i
S
n
j
jiji
vvS
1
2
)(
n
j
jiji
vvS
1
2
)(
(6)
7. Calculate the relative approaching of ideal
distance
j
C
, then, weighting can be found.
njni
SS
S
C
ii
i
j
,,3,2,1,,,3,2,1 ,
(7)
2.2 Objective Weighting Analysis
Step 3 of TOPSIS is observed to be subjectively
postulated. As for the existent data, a mathematical
method can be used to convert subjective weighting
into objective weighting. The present paper, which
applied grey relational grade to TOPSIS, could yield
objective result. The basic concept of grey relational
grade is shown below. Five kinds of globalization
grey relational grade have been developed in the
past few years(Wen, 2016). This study referred to
the mathematical method proposed by Liu.
)(
2
1
)]([1
1
1
2
nk
ik
n
k
ij
ij
(8)
where:
Ijnkmi
,,,3,2,1 ,,,3,2,1
i.
i
x
: Reference sequence,
j
x
: Inspected sequences
ii.
||)()(|| kxkx
jiij
According to Saaty, the eigenvector method can
be used to rank the sequence, and then choose an
optimal one.
1. Base on the original sequences
))(,,)3(,)2(,)1((
.............................................
))(,,)3(,)2(,)1((
))(,,)3(,)2(,)1((
))(,,)3(,)2(,)1((
33333
22222
11111
kxxxxx
kxxxxx
kxxxxx
kxxxxx
mmmmm
(9)
2. Constructing the relative weighting matrix
mm
R
][
, by using the cardinal globalization grey
relational grade method to find the grey relational
grade, which is called grey relational matrix.
mmmm
m
m
mm
R
21
11
22221
11211
(10)
3. Find the eigenvalue for the relative weighting
matrix
mm
R
][
:
RAR
4. Use eigenvector method to find the weighting
for each target
RPP
1
},{
,.....3,21 n
diag
5. The maximum
corresponding eigenvector is
the weighting for the sequence.
MEEP 2018 - The Second International Conference on Materials Chemistry and Environmental Protection
294
3 REAL EXAMPLE
Four kinds of running water, including tap water,
Funyuan spring water, Puli spring water and
Hungmaojing water, served as the objects for
investigation. The original data was based on the test
conducted by the Environmental Protection Bureau
of Changhua County, and was modified for scaling.
The analysis steps are shown below.
1. Table 1 shows the measurement results.
2. Table 2 shows the normalization of four kinds
of drinking water by using equation (2).
3. Table 3, which is based on the data in Table 2,
demonstrates the weighting of four kinds of water by
using the grey relational grade.
4. Table 4, which is based on the data in Table 3,
shows the normalization matrix of four kinds of
water by using equation (4).
5. Table 5 depicts the calculation of the positive
ideal solution and ideal negative solution by using
equation (6).
6. Table 6 demonstrates the calculation of the
relative approaching of ideal distance of four kinds
of water by using equation (7).
Table 1: The modified data of four kinds of drinking water.
Item/source
A
B
C
D
1. Turbidity(10 times)
7.0
17.0
3.0
1.0
2. pH
8.0
7.5
6.8
6.7
3.Chlorine (100mg/10l)
54.0
12.0
6.0
61.0
4. Sulfates (100mg/10l)
8.5
2.1
2.0
18.2
5. Free chlorine
1.0
23.0
0.5
7.0
6. Total hardness (100mg/10l)
24.2
10.4
6.8
33.4
7. Iron content (times 10)
4.0
2.0
1.0
14.0
8. Total number of viable cells (1,000mg/100l)
13
74.8
6.24
7.3
Table 2: The normalization results.
Item/source
A
B
C
D
1. Turbidity(10 times)
0.0018
0.0025
0.0165
0.0002
2. pH
0.0021
0.0011
0.0374
0.0012
3.Chlorine (100mg/10l)
0.0139
0.0018
0.0330
0.0111
4. Sulfates (100mg/10l)
0.0022
0.0003
0.0110
0.0033
5. Free chlorine
0.0003
0.0034
0.0028
0.0013
6. Total hardness (100mg/10l)
0.0062
0.0015
0.0374
0.0061
7. Iron content (times 10)
0.0010
0.0003
0.0055
0.0025
8. Total number of viable cells (1,000mg/100l)
0.0034
0.0111
0.0343
0.0013
Table 3: The weighting from Liu’s grey relational grade.
Water source
A
B
C
D
Weighting
0.6941
0.1226
0.1705
0.6885
Table 4: The normalization decision matrix after add the weighting.
Item/source
A
B
C
D
1. Turbidity(10 times)
0.0013
0.0003
0.0028
0.0001
2. pH
0.0014
0.0001
0.0064
0.0008
3.Chlorine (100mg/10l)
0.0097
0.0002
0.0056
0.0076
4. Sulfates (100mg/10l)
0.0015
0.0000
0.0019
0.0023
5. Free chlorine
0.0002
0.0004
0.0005
0.0009
6. Total hardness (100mg/10l)
0.0043
0.0002
0.0064
0.0042
7. Iron content (times 10)
0.0007
0.0000
0.0009
0.0017
8. Total number of viable cell (1,000mg/100l)
0.0023
0.0014
0.0059
0.0009
The Cardinal TOPSIS via Grey Relational Grade
295
Table 5: The positive ideal solution and ideal negative solution of four kinds of drinking water.
Water source
A
B
C
D
i
S
0.0214
0.0031
0.0099
0.0164
i
S
0.0108
0.0014
0.0115
0.0090
Table 6: The relative approaching of ideal distance of four kinds of drinking water.
Weighting/water
A
B
C
D
Ideal distance
0.3354
0.3111
0.5374
0.3543
Rank
3
4
1
2
*A: Tap water(Changhua). B: Funyuan spring water. C: Puli spring water. D: Hungmaojing water
4 CONCLUSIONS
The main purpose of the TOPSIS is to obtain the
sorting of all alternatives. Despite the effort of this
research to avoid the difficulty in comparing the
distance between two directions in the weighting
steps, it was subjective to a certain degree. The
research result could therefore be uncertain. One of
the major contributions of this study was using the
grey relational grade to convert subjective weighting
into objective weighting for further cardinal. The
present research, which referred to and analysis four
kinds of running water, effectively verified and
supported this soft computing method; The results
obtained from the cardinal TOPSIS were consistent
with the real situation.
Forthcoming study is suggested to implement
other cardinal weighting methods such as grey
cluster analysis and GM(h,N) to make analysis more
reliable.
ACKNOWLEDGEMENTS
The authors would to thank Taiwan Kansei
information association, for the supporting of the
toolbox to verify the data calculation.
REFERENCES
Khamseh, A. A., Mahmoodi, M., 2014. A new fuzzy
TOPSIS-TODIM hybrid method for green supplier
selection using fuzzy time function, Advances in
Fuzzy Systems, vol. 2014, pp. 177-186.
Liu, W. L., You, M. L., Tsai, Y. L., Wen, K. L, and Wen,
H. C., 2014. The new approach of grey-TOPSIS and
the development of Matlab toolbox. In e-CASE & e-
Tech Conference, pp. 853-866.
Ouma, Y. O., Opudo J., and Nyambenya, S., 2015.
Comparison of fuzzy AHP and fuzzy TOPSIS for road
pavement maintenance prioritization: methodological
exposition and case study, Advances in Civil
Engineering, vol. 2015, pp. 1-17.
Pi, W. I., 2005. Supplier evaluation using AHP and
TOPSIS, Journal of Science and Engineering
Technology, vol. 1 no. 1, pp. 75-83.
Qian, W. U., Dang, Y. G., Xiong, P. P., and Wang, Z. X.,
2009. TOPSIS based on grey correlation method and
its application, Systems Engineering, vol. 27, no. 8,
pp. 124-126.
Shahab, A., 2016. Alunite processing method selection
using the AHP and TOPSIS approaches under fuzzy
environment, International Journal of Mining Science
and Technology, vol. 6, pp. 1017-1023.
Wen, K. L., 2013. Grey system theory, Wunan Publisher,
Taipei, 2nd Edition.
Wen, K. L., 2016. The proof of a new modified grey
relational grade. Grey Systems: Theory and
Application, vol. 6, no. 2, pp. 180-186.
Wen, K. L., You, M. L., 2018. Apply soft computing in
data mining, 2nd Edition, Taiwan Kansei Information
Association, Taiwan.
Zavadskas, E. K., Vilutiene, T., Turskis, Z., and
Tamosaitiene, J., 2010. Contractor selection for
construction works by applying saw-g and TOPSIS
grey techniques, Journal of Business Economics and
Management, vol. 11, no. 1, pp. 34-55.
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