A New Hendecagonal Fuzzy Number For Optimization Problems

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ISSN No: 2456 - 6470 | www.ijtsrd.com | Volume - 1 | Issue – 5
International Journal of Trend in Scientific
Research and Development (IJTSRD)
UGC Approved International Open Access Journal
A New Hendecagonal Fuzzy Number for Optimization Problems
M. Revathi
Assistant professor,
Department of Mathematics, Tamilnadu College of
Engineering,Coimbatore,Tamilnadu, India
Dr.M.Valliathal
Assistant professor, Department of Mathematics,
Chikkaiah Naicker College, Erode, Tamilnadu, India
R. Saravanan
Assistant professor,
Department of Mathematics, Tamilnadu College of
Engineering,Coimbatore,Tamilnadu, India
Dr.K.Rathi
Assistant Professor, Department of Mathematics,
Velalar College of Engineering and Technology,
Erode, Tamilnadu
ABSTRACT
A new fuzzy number called Hendecagonal fuzzy
number and its membership function is introduced,
which is used to represent the uncertainty with eleven
points. The fuzzy numbers with ten ordinates exists in
literature. The aim of this paper is to define
Hendecagonal fuzzy number and its arithmetic
operations. Also a direct approach is proposed to
solve fuzzy assignment problem (FAP) and fuzzy
travelling salesman (FTSP) in which the cost and
distance are represented by Hendecagonal fuzzy
numbers. Numerical example shows the effectiveness
of the proposed method and the Hendecagonal fuzzy
number.
Keywords: Hendecagonal fuzzy number, Alpha cut,
Fuzzy arithmetic, Fuzzy Assignment problem, Fuzzy
transportation problem.
I. INTRODUCTION
A fuzzy number is a quantity whose values are
imprecise, rather than exact as in the case with single-
valued function. The generalization of real number is
the main concept of fuzzy number. In real world
applications all the parameters may not be known
precisely due to uncontrollable factors.
L.A.Zadeh introduced fuzzy set theory in 1965.
Different types of fuzzy sets [17] are defined in order
to clear the vagueness of the existing problems.
D.Dubois and H.Prade has defined fuzzy number as a
fuzzy subset of real line [8]. In literature, many type
of fuzzy numbers like triangular fuzzy number,
trapezoidal fuzzy number, pentagonal fuzzy number,
hexagonal fuzzy number, heptagonal fuzzy number,
octagonal fuzzy number, nanagonal fuzzy number,
decagonal fuzzy number have been introduced with
its membership function. These membership
functions got many applications and many operations
were done using these fuzzy numbers [2], [12] [14],
[15].
In much decision analysis, the uncertainty existing in
input information is usually represented as fuzzy
numbers [1],. S.H.Chen introduced maximization and
minimization of fuzzy set, uncertainty and
information [4]. The arithmetic operations , alpha cut
and ranking function are already introduced for
existing fuzzy numbers by C.B.Chen and
C.M.Klein,T.S.Liou and M.J.Wang [6],[11]. When
the vagueness arises in eleven different points it is
difficult to represent the fuzzy number. In this paper a
new type of fuzzy number named as hendecagonal
fuzzy number is defined with its membership
function. The arithmetic operations, alpha cut and
ranking procedure for hendecagonal fuzzy numbers
are introduced to solve fuzzy assignment problem
(FAP) and fuzzy travelling salesman problem
(FTSP).In literature, many methods were proposed for
fuzzy optimization with uncertain parameters
[3],[5],[10],[13].Here uncertainty in assignment cost

International Journal of Trend in Scientific Research and Development (IJTSRD) ISSN: 2456-6470
and travelling distance are represented by new fuzzy
number named as Hendecagonal fuzzy number, which
are ranked using the ranking function introduced by
R.R.Yager [16],[7]. Numerical examples show the
effectiveness of the proposed method and the new
fuzzy number, It is simple and very easy to
understand and can be applied in many real life
problems.
II. PRELIMINARY
Definition 2.1: The membership grade corresponds to
the degree to which an element is compatible with the
concept represented by fuzzy set.
Definition 2.2: Let X denote a universal set. Then the
characteristic function which assigns certain values or
a membership grade to the elements of this universal
set within a specified range [0,1] is known as
membership function & the set thus defined is called a
fuzzy set.
Definition 2.3: Let X denote a universal set. Then the
membership function A by using a fuzzy set A is
usually denoted as IXA : , where I = [0,1]
Definition 2.4: An  -cut of a fuzzy set A is a crispest

A that contains all the elements of the universal set
X that have a membership grade in A greater or equal
to specified value of  Thus
 10,)(,  
xXxA A
Definition 2.5: A fuzzy set A
~
is a convex fuzzy set if
and only if each of its cuts 
A is a convex set.
Definition2.6: A fuzzy set A
~
is a fuzzy number if
(i) For all ]1,0( the cut sets A is a convex set (ii)
A
~ is an upper semi continuous function.
Definition 2.7: A triangular membership function is
specified by three parameters [a,b,c] as follows
 (x:a,b,c)=










otherwise
cxbbcxc
bx
bxaabax
,0
),/()(
,1
),/()(
This function is determined by the choice of the
parameter a, b, c where  1,0ijx
Definition 2.8: A trapezoidal fuzzy number
),,,(
~
dcbaA  is a fuzzy number with membership
function of the form











otherwise
dxccdxd
cxb
bxaabax
dcbax
,0
,)/()(
,1
,)/()(
),,,:(
III. HENDECAGONAL FUZZY NUMBERS
Definition 3.1: The parametric form of Hendecagonal
Fuzzy Number is defined as
 )(),(),(),(),(),(),(),(),(),(
~
2222211111 vTuStRsQrPvTuStRsQrPU  , for
]2.0,0[r ]4.0,2.0[s ]6.0,4.0[t ]8.0,6.0[u and
]1,8.0[v where )()(),(),(),( 11111 vTanduStRsQrP are
bounded left continuous non decreasing functions
over ]1.8.0[]8.0,6.0[],6.0,4.0[],4.0,2.0[],2.0,0[ and ,
)()(),(),(),( 22222 vTanduStRsQrP Are bounded left
continuous non increasing functions over
]1.8.0[]8.0,6.0[],6.0,4.0[],4.0,2.0[],2.0,0[ and .
Definition 3.2: A fuzzy number
),,,,,,,,,,( 1110987654321 aaaaaaaaaaaA  is said to
be a Hendecagonal fuzzy number if its membership
function is given by






























































































































Otherwise
axa
aa
xa
axa
aa
ax
axa
aa
ax
axa
aa
ax
axa
aa
ax
axa
aa
ax
axa
aa
ax
axa
aa
ax
axa
aa
ax
axa
aa
ax
xU
,0
,
5
1
,
5
1
5
2
,
5
1
5
3
,
5
1
5
4
,
5
1
1
,
5
1
5
4
,
5
1
5
3
,
5
1
5
2
,
5
1
5
1
,
5
1
)(
1110
1011
11
109
910
9
98
89
8
87
78
7
76
67
6
65
56
5
54
45
4
43
34
3
32
23
2
21
12
1

Figure 1 shows the graphical representation of
Hendecagonal fuzzy number.

Figure 1: Graphical representation of Hendecagonal fuzzy number
IV. ARITHMETIC OPERATIONS ON
HENDECAGONAL FUZZY NUMBERS
In this section, arithmetic operations between two
Hendecagonal fuzzy numbers, defined on universal
set of real numbers R, are presented.
Let ),,,,,,,,,,( 1110987654321 aaaaaaaaaaaA  and
),,,,,,,,,,( 1110987654321 bbbbbbbbbbbB  be two
hendecagonal fuzzy number then
(i) Addition of two hendecagonal fuzzy numbers
),,,,
,,,,,,(
),,,,,,,,,,(
~~
11111010998877
665544332211
1110987654321
bababababa
babababababa
cccccccccccBA



(ii) Scalar multiplication of hendecagonal fuzzy
numbers






0if),,,,,,,,,,(
0if),,,,,,,,,,(~
1234567891011
1110987654321



aaaaaaaaaaa
aaaaaaaaaaa
A
(iii) Subtraction of two hendecagonal fuzzy
numbers
 
),,,,
,,,,,,(
~~~~
111210394857
66758493102111
bababababa
babababababa
BABA



V. RANKING HENDECAGONAL FUZZY NUMBERS
The ranking method proposed in [4] is used to rank
the hendecagonal fuzzy numbers.
The ranking function RRFr )(: where F(R) is a
set of fuzzy number defined on set of real numbers,
which maps each fuzzy number into the real line,
where the natural order exists, i.e.
)
~
()
~
(
~~
)(
)
~
()
~
(
~~
)(
)
~
()
~
(
~~
)(
BrAriffBAiii
BrAriffBAii
BrAriffBAi



Let ),,,,,,,,,,( 1110987654321 aaaaaaaaaaaA  and
),,,,,,,,,,( 1110987654321 bbbbbbbbbbbB 
be two hendecagonal fuzzy numbers then
11
)
~
( 1110987654321 aaaaaaaaaaa
Ar


and 11
)
~
( 1110987654321 bbbbbbbbbbb
Br


VI. FUZZY ASSIGNMENT PROBLEM AND FUZZY
TRAVELLING SALESMAN PROBLEM
In this section, mathematical formulation of fuzzy
assignment problem is given and a direct approach is
proposed to solve FAP and FTSP. The method is
applicable for all optimization problems.
A. Formulation of Fuzzy Assignment Problem
Let there be m Tasks and m Workers , ijC
~
be the cost
of assigning ith
Worker to the jth
Task and the
uncertainty in cost is here represented as
Hendecagonal fuzzy numbers. Let ijx be the decision
variable define
P1(r)
Q1(s)
R1(t)
S1(u)
T1(v) T2(v)
S2(u)
R2(t)
Q2(s)
P2(r)
0.0
0.2
0.4
0.6
0.8
1.0
1.2
Hendecagonal fuzzy number






otherwise0
jobjthetoassignedispersonitheif1 thth
ijx
Then the fuzzy assignment problem can be
mathematically stated as follows
Minimize  

m
i
m
j
ijij xCZ
1 1
~~
Subject to 

m
j
ij mix
1
...2,1,1 ;


m
i
ij mjx
1
...2,1,1
B. Formulation of Fuzzy Travelling Salesman
Problem
The travelling salesman problem deals with finding
shortest path in a n-city where each city is visited
exactly once. The travelling salesman problem is
similar to assignment problem that excludes sub
paths. Specifically in an n-city situation define




otherwise
icityfromreachedisjcityif
xij
,0
,1
Here ijd
~
is the distance from city i to city j which is
Hendecagonal fuzzy number. Mathematically FTSP
can be stated as
Minimize  

n
i
n
j
ijijij jiallfordxdz
1 1
,
~~~
Subject to 

n
j
ij nix
1
...2,1,1


n
i
ij njx
1
...2,1,1 ,  1,0ijx
VII. NUMERICAL EXAMPLE
In this section numerical examples are given to
illustrate the proposed method and it is shown that the
proposed method offers an effective way for handling
FAP as well as FTSP.
Example 7.1: A manufacturing company
manufactures a certain type of spare parts with three
different machines. The company official has to
execute three jobs with three machines. The
information about the cost of assignment is imprecise
and here Hendecagonal Fuzzy numbers are used to
represent the cost. The fuzzy assignment problem is
given in Table 1.
Solution:
Step 1: Calculate the ranking value of each fuzzy cost
is given in Table 2.
Step 2: Encircle the fuzzy cost with least ranking
value in each row and examine all the encircled fuzzy
costs and identify the encircled fuzzy cost that is
uniquely encircled in both row wise and column wise.
Assign it and delete the corresponding row and
column. The resultant table is given in Table 3.
Step 3:If the cost is not uniquely selected both row
wise and column wise then choose next minimum and
proceed as in step 2.This process is continued until the
fuzzy cost is uniquely selected row and column wise.
Then the optimal assignment is 11 MJ  , 22 MJ  ,
33 MJ  with the optimal assignment cost
(4,8,12,16,21,29,35,39,43,47,54) and its crisp value is
r(C) = 28
Table 1: Fuzzy Assignment Problem with Hendecagonal Fuzzy Cost
Machines
`M1 M2 M3
JOB
J1 (1,3,5,7,9,11,13,15,17,19,21) (2,4,6,8,10,12,14,16,18,20,22) (1,2,3,4,5,6,7,8,9,10,11)
J2 (3,7,11,13,17,21,22,25.29,32,40) (2,4,6,8,9,13,15,16,18,20,21) (2,3,7,8,9,11,13,15,16,21,33)
J3 (1,2,3,4,7,10,13,15,16,17,22) (5,8,10,13,16,21,23,28,31,32) (4,6,7,9,10,11,18,23,24,26,27)

Table 2: Ranking value of Hendecagonal Fuzzy cost
Machines
M1 M2 M3
JOB
J1
11)~( 11 cr 12)~( 12 cr 6)~( 13 cr
J2
20)~( 21 cr 12)~( 22 cr 13)~( 23 cr
J3
10)~( 31 cr 19)~( 32 cr 15)~( 33 cr
Table 3: Encircled Fuzzy Cost
Machines
M1 M2 M3
JOB
J1 (1,3,5,7,9,11,13,15,17,19,21) (2,4,6,8,10,12,14,16,18,20,22) (1,2,3,4,5,6,7,8,9,10,11)
J2 (3,7,11,13,17,21,22,25.29,32,40) (2,4,6,8,9,13,15,16,18,20,21) (2,3,7,8,9,11,13,15,16,21,33)
J3 (1,2,3,4,7,10,13,15,16,17,22) (5,8,10,13,16,21,23,28,31,32) (4,6,7,9,10,11,18,23,24,26,27)
Example 7.2:Let us consider a fuzzy travelling
salesman problem with three cities C1,C2,C3. The
distance matrix  ijd
~
is given whose elements are
Hendecagonal fuzzy numbers. A salesman must travel
from city to city to maintain his accounts. The
problem is to find the optimal assignment, so that the
assignment minimize the total distance of visiting all
cities and return to starting city. The fuzzy travelling
salesman problem is given in Table 4.
Solution:
Step 1: Calculate the ranking value of each fuzzy
distance is given in Table 5.
Step 2: Encircle the fuzzy distance with least ranking
value in each row and examine all the
encircled fuzzy distance to find the uniquely
encircled fuzzy distance in both row wise and
column wise. Assign it and delete the
corresponding row and column. The resultant
table is given in Table 6.
Step 3:If the distance is not uniquely selected
both row wise and column wise then choose
next minimum and repeat the step 2.This
process is continued until the fuzzy distance is
uniquely selected row and column wise.
Thus the optimal assignment is 21 CC  ,
32 CC  , 13 CC  with the optimal distance
(5,9,16,20,26,33,40,46,50,58,77) and its crisp
value is 55.34)
~
( ijdr

Table 4: Fuzzy Travelling Salesman Problem with Hendecagonal Fuzzy Distance
CITY
`C1 C2 C3
CITY
C1  (2,4,6,8,10,12,14,16,18,20,22) (1,2,3,4,5,6,7,8,9,10,11)
C2 (3,7,11,13,17,21,22,25.29,32,40)  (2,3,7,8,9,11,13,15,16,21,33)
C3 (1,2,3,4,7,10,13,15,16,17,22) (5,8,10,13,16,21,23,28,31,32) 
Table 5: Ranking value of Hendecagonal Fuzzy Distance
CITY
`C1 `C1 `C1
CITY
C1  12)~( 12 cr 6)~( 13 cr
C2 20)~( 21 cr  13)~( 23 cr
C3 10)~( 31 cr 19)~( 32 cr 
Table 3: Encircled Fuzzy Distance
CITY
`C1 `C1 M3
CITY
C1  (2,4,6,8,10,12,14,16,18,20,22) (1,2,3,4,5,6,7,8,9,10,11)
C2 (3,7,11,13,17,21,22,25.29,32,
40)
 (2,3,7,8,9,11,13,15,16,21,33)
C3 (1,2,3,4,7,10,13,15,16,17,22) (5,8,10,13,16,21,23,28,31,32) 
VIII. CONCLUSION AND FUTURE ENHANCEMENT
In this paper, a new fuzzy number is developed for
solving optimization problem with Hendecagonal
fuzzy cost and fuzzy distance. The optimal solution to
FAP and FTSP obtained by the proposed method is
same as that of the optimal solution obtained by the
existing methods. However the proposed method is
simpler, easy to understand and it takes few steps for
obtaining the fuzzy optimal solution. Numerical
example shows that the proposed method offers an
effective tool for handling the fuzzy assignment
problem. In future, the generalization of
Hendecagonal fuzzy number is developed to solve
optimization problems.

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