Plane Thermoelastic Waves in Infinite Half-Space Caused


Decision Making: Applications in Management and Engineering 
Vol. 1, Number 1, 2018, pp. 51-66 
ISSN: 2560-6018  

DOI: https://doi.org/10.31181/dmame180151b 

* Corresponding author. 
 E-mail addresses: dragan.bojanic@mod.gov.rs (D. Bojanic), marbojanic@gmail.com 
(M. Bojanic), vladimir.ristic@mod.gov.rs (V. Ristic) 

MULTI-CRITERIA DECISION-MAKING IN A DEFENSIVE 
OPERATION OF THE GUIDED ANTI-TANK MISSILE 

BATTERY: AN EXAMPLE OF THE HYBRID MODEL FUZZY 
AHP - MABAC 

Dragan Bojanic1*, Mitar Kovač2, Marina Bojanic3 and Vladimir Ristic4 

1 Strategic Research Institute, University of Defense, Belgrade, Serbia 
2 University of Edukons, Faculty of Project and Innovation Management, Belgrade, 

Serbia 
3 Electrical Engineering School „Nikola Tesla“, Pančevo, Serbia 

4 University of Defense, Military Academy, Belgrade, Serbia 
 
Received: 3 January 2018;  
Accepted: 31 January 2018;  
Published: 15 March 2018. 

 
Original scientific paper 

Abstract: The military decision-making process is a proven analytical 
process for designing operations, troops’ movements, logistics or air defense 
planning. The hybrid FAHP-MABAC model is tested for obtaining/selecting 
the results for an optimal firing position of the guided anti-tank missile 
battery (GAMB).This study provides a multi-criteria decision-making 
(MCDM) model so that the confidence interval of fuzzy numbers describes the 
comparison in pairs whose degree is not determined before the comparison. 
By using mathematical expressions the confidence interval is brought into 
direct connection with the degree of certainty of decision-makers/expert of 
the comparison performed. In the group decision-making, the confidence 
intervals differ depending on the decision-maker/expert’s opinion. Finally the 
sensitivity analysis is used to determine how sensitive a decision model is. The 
suggested model is expected to contribute to the development of the science 
of military-operations as well as to prove itself useful to the actors related to 
defense. 

Key Words: Fuzzy AHP, MABAC, MCDM, Sensitivity Analysis. 

1. Introduction 

MCDM is a systematic way of problem solving for any scientific research area. The 
military decision-making process is a proven analytical process for designing 
operations, troops’ movements, logistics or air defense planning. 

In most cases, the decision-making process in the military organization implies 
not having relevant information, which is characterized by a high degree of 

mailto:dragan.bojanic@mod.gov.rs
mailto:marbojanic@gmail.com
mailto:vladimir.ristic@mod.gov.rs


 Bojanić et al./Decis. Mak. Appl. Manag. Eng. 1 (1) (2018) 51-66 

52 

uncertainty, subjectivity and ambiguity. Generally, in the decision-making process for 
these problems, a large number of key and different criteria are involved. Therefore, 
it is advisable to use tools for their resolution such as MCDM processes that are 
nowadays widely used in the military (Kewley & Embrechts, 2002; De Leeneer & 
Pastijn, 2002; Zanjirani & Asgarib, 2007; Kose et al., 2013; Gyarmati,  2015; Goztepe 
& Kahraman, 2015; Andersson et al., 2015; Boccia et al., 2017), as well as in other 
research disciplines (Sánchez-Lozano et al., 2013). Fuzzy logic proves to be an 
appropriate tool (Sánchez-Lozano et al., 2015) to address the described uncertainties 
and ambiguities. In that way, fuzzy logic enables the exploitation of tolerance that 
exists in imprecision, ambiguity and partial truth of the results obtained through 
given research. 

Anti-tank is defined as a combat against enemy’s tanks and other armored 
equipment and vehicles. Its associated tasks include the closing of endangered 
directions, flanks, and junctions (Gordic et al., 2013). Anti-tank is a part of the 
combined combat arms directed against the tanks grouped for an attack or already 
directly attacking, as well as the armored equipment detached to their battle 
formation. For a successful combat, the organization of a solid anti-armor system is 
required, which includes anti-tank units as the basic element. The aim of anti-tank 
operations in a defensive operation is to prevent accidental penetration of the 
enemy's armored forces into our elements of combat disposition (Slavkovic et al., 
2013; Jotić & Slavković,2016). 

The new operational environment imposes the need to upgrade the defense 
science in the field of the preparation and conduct of combat operations (Knežević & 
Slavković, 2012). In the Serbian Army many decisions are made in the processes of 
planning, organization and preparation for the execution of missions and tasks. The 
useful tools which support the decision-making process are the methods of multi 
criteria decision-making. 

The fundamental issue of multi-criteria group decision-making is finding 
procedures for choosing decisions that correspond to the desired solution, with the 
option of selecting and allocating the most acceptable alternative. The complexity of 
group decision-making is reflected in the fact that there are a number of criteria and 
alternatives with different levels of significance for the decision-makers/experts 
involved in decision-making. 

This paper presents a hybrid model, using the fuzzificated Saaty’s scale and the 
MABAC method (Multi-Attributive Border Approximation Area Comparison) 
(Božanić et al., 2015; Božanić et al., 2016a; Božanić et al., 2016b; Pamučar et al., 
2016b). The paper is focused on the demonstration of a new way of fuzzification of 
the Saaty’s scale used for comparison in pairs while varying a confidence interval 
depending on the comparison. The scale is used for obtaining criteria weight 
coefficients, while the MABAC method is used for the final ranking. This model is 
illustrated by an example of decision-making during the selection of firing position 
(POP) of the GAMB in the Army's defensive operation. The example presents only 
one segment from a series of decisions that decision-makers face in the preparation 
and execution of (military) operations. The sensitivity analysis is used to determine 
how sensitive a decision model is. 

2. Description of the methods used in the hybrid AHP-MABAC model 

The described MCDM model is based on the knowledge of several decision- 
making methods (areas), fuzzy logic, the AHP method (Saaty's scale) and the MABAC 

https://www.sciencedirect.com/science/article/pii/S0377221701003721#!
https://www.sciencedirect.com/science/article/pii/S0377221705008775#!
http://www.emeraldinsight.com/author/Kose%2C+Erkan
https://www.researchgate.net/profile/Kerim_Goztepe
https://www.researchgate.net/profile/Cengiz_Kahraman


Multi-criteria decision-making in A defensive operation of the Guided anti-tank... 

53 

 

method. Fuzzy logic successfully covers vagueness and uncertainty that are often 
present in decision-supporting models. The Saaty's scale, which is an indispensable 
part of the AHP method, shows good results in defining the criteria weight 
coefficients, and it is increasingly applied with other methods (Knežević et al., 2015; 
Zhu et al., 1999). The MABAC method provides stable (consistent) solutions and it 
represents a reliable tool for rational decision-making (Pamučar & Ćirović, 2015). 

3. Fuzzy logic and fuzzy sets 

In fuzzy logic, an element’s belonging to the specific set is not precisely defined - 
the element can be more or less part of the set; therefore, it is closer to human 
perception than conventional logic (Pamučar et al., 2016b). Fuzzy logic allows 
quantification of seemingly imprecise information, which is a very common situation 
when describing social phenomena. Fuzzy logic uses the experience of human expert 
in the form of linguistic if-then rules, while approximate reasoning mechanism uses 
managing action for the individual case. In this paper, approximate reasoning 
algorithm is used to display the influence of the entry criteria on decision preference 
in choosing the most appropriate firing GAMB position. 

The first step in designing fuzzy sets is to define the degree of the membership of 
an element x (xX) in the set A. This is described with membership function A (x), 
which in the classic theory has a value of 0 (does not belong) or 1 (belongs), while in 
a fuzzy set the membership function can have any value between 0 and 1. So, it can 
be said that the closer А (x) is to 1, the greater belonging of  x to A is, and vice versa. 
A fuzzy set A is defined as a set of ordered pairs 

     A AA x, x x X, 0 x 1      (1) 

where: 

 X  is a universal set or a set of considerations based on which fuzzy set A is 
defined; 

 A (x) function of element x belonging to set A. 
In this paper, triangular fuzzy numbers will be used. They will be presented in the 

form T = (t1, t2, t3), where Fig. 1: 

 t2 is where the membership function of a fuzzy number has a value of 1; 

 t1 is the left distribution of the confidence interval of fuzzy number T, and, 

 t3 is the right distribution of the confidence interval of fuzzy number T. 

t1 t2 t3

1

 T x


  2
1,  

T x
x t  

 
1

1 2

2 1

,  
T x

x t
t x t

t t



  

  
3

2 3

3 2

,  
T x

t x
t x t

t t



  



  1
0,  

T x
x t  

  3
0,  

T x
x t  



0
αT1

αT2

 



 Bojanić et al./Decis. Mak. Appl. Manag. Eng. 1 (1) (2018) 51-66 

54 

Figure 1. Triangular fuzzy number T (Pamučar et al., 2016a) 

The membership function of fuzzy number T is defined in the following way: 

 

1

1

1 2

2 1

2T

3

2 3

3 2

3

        0,     x t

x t
, t x t

t t

x         1,     x t

t x
, t x t

t t

0,     x t







  
 


 
 
  






 (2) 

For its final purpose, fuzzy number T= (t1, t2, t3) is converted into a real number.  

4. Fuzzification of the Saaty’s scale 

One of the key phases in the application of this method is the development of the 
comparison matrix by pairs, corresponding to every level of the hierarchy. A 
pairwise comparison is performed according to the data collected by measuring 
them on the basis of beliefs, estimates or experiences of those who carry out the 
assessment (Čupić & Suknović 2010). The shown fuzzification of the Saaty’s scale is 
presented in (Božanić et al., 2015; Božanić et al., 2016a; Božanić et al., 2016b; 
Pamučar et al., 2016b; Božanić, 2017). 

The definition of this new fuzzificated Saaty’s scale (Table 1) starts from the 
assumption that the decision-makers and analysts have a different degree of 
certainty ji, concerning the accuracy of comparisons in pairs (Božanić et al., 2016a; 
Pamučar et al., 2016b). This degree of certainty differs from one comparative pair to 
another. The value of the degree of certainty belongs to interval ji0,1. In the cases 
when ji=0, it is considered that the decision-maker/analyst has no data about this 
relationship; hence it should not be used in the decision-making process because it 
points to absolute ignorance of the decision-making subject. The value of the degree 
of certainty where ji=1 describes the absolute certainty of the decision-
makers/analysts in the given comparison. The lower the certainty in the performed 
comparison is, the lower the element ji. 

Table 1. Fuzzified Saaty's scale for comparison in pairs (Božanić, 2017). 

Definition 
Standard 

value 
Fuzzy number 

Inverse values of the 
fuzzy number 

Same importance 1 (1, 1, 1) (1, 1, 1) 

Low dominance 3   ji ji3 , 3, 2 3 
 

  ji ji1 2 3,1/ 3,1 3   

High dominance 5   ji ji5 , 5, 2 5 
 

  ji ji1 2 5,1/ 5,1 5   

Very high dominance 7   ji ji7 , 7, 2 7 
 

 ji ji1 (2 )7 ,1 / 7,1 7   

Absolute dominance 9   ji ji9 , 9, 2 9 
 

 ji ji1 (2 )9 ,1 / 9,1 9   



Multi-criteria decision-making in A defensive operation of the Guided anti-tank... 

55 

 

Intermediate values 2, 4, 6, 8 
  ji jix , x, 2 x 
 

x 2,  4,  6,  8  

  ji ji1 2 x ,1/ x,1 x 
x = 2, 4, 6, 8 

 
By defining different values of parameter ji, the left and the right distribution of 

fuzzy numbers change from one comparison to another, according to the expression: 

 

 
 

   

1 2 1 2 1 2

1 2 3 2 2 2

3 2 3 2 2 3

t t ,           t t ,      t , t 1 / 9, 9

T t , t , t t t ,                                 t 1 / 9, 9

t 2 t ,    t t ,    t , t 1 / 9, 9





   
 

    
     

 (3) 

the value of t2 represents the value of linguistic expressions from the classic Saaty’s 
scale, which in a fuzzy number has a maximum membership t2 = 1 

Fuzzy number     1 2 3T t , t , t x , x, 2 x    ,  x 1,9 is defined by the 

expressions: 

1

x ,   1 x x
t x

1,       x 1

 




  
  

 
 (4) 

 2t x,   x 1,9    (5) 

   3t 2 x, x 1,9     (6) 

Inverse fuzzy number     1 2 3T t , t , t x , x, 2 x    ,  x 1, 9 is defined as 

follows: 

 
   

 
 3

1 2 x ,   1 2 x 1
1/ t 1 2 x , x 1, 9

1,   1 2 x 1

 




   
   

  

 (7) 

21 / t 1 / x,   1 / x 1, 9    (8) 

 11/ t 1 x , 1/ x 1,9    (9) 

The defined scale is further used in standard steps of the AHP method, which is 
described in a number of papers (Čupić & Suknović2010), (Inđić et al., 2014) and 
others. 

Based on the pre-defined scale, the decision-makers and analysts fill in the new, 
modified matrix: 

1 2 n

1 11 11 12 12 1n 1n

2 21 21 22 22 2n 2n

n n1 n1 n 2 n 2 nn nn

C     C           C

C a ; a ; a ;

A C a ; a ; a ;

C a ; a ; a ;

  

  

  

 
 
 

 




 



 (10) 

As can be seen, the matrix is extended with the degree of certainty in the 
comparison made, whereby ji=ij, where ji0,1. After the calculation is finished, 
the defuzzification can be performed using one of well-known methods. Some of the 
well-known expressions for defuzzification (Seiford, 1996) are the following ones: 



 Bojanić et al./Decis. Mak. Appl. Manag. Eng. 1 (1) (2018) 51-66 

56 

    13 1 2 1 1defazzy S= t t t t 3 t


       (11) 

  13 2 1defazzy S= t t 1 t 2 


      (12) 

Where  represents the degree of optimism.  
The defined scale is also suitable for group decision-making, which is nowadays 

becoming more and more popular. Involving experts greatly improves the quality of 
decisions made because knowledge and experience are collected and consolidated 
into a single unit. 

5. MABAC method 

The MABAC method was developed by Pamučar and Ćirović (Pamučar & Ćirović, 
2015). The basic setting of the MABAC method is reflected in the definition of the 
distance of the criterion function of each of the observed alternatives from the 
approximate border area. The text that follows shows the procedure of 
implementation of the MABAC method in six steps, its mathematical formulation 
being: 

Step 1. Creation of initial decision matrix (X). In the first step, the evaluation of m 
alternatives by n criteria is carried out. The alternatives are presented with vectors 
Ai = (xi1,xi2, ……xin), where xij.is the value of alternative i according to criteria j (i = 1,2,..., 
m; j = 1,2,..., n). 

1 2 n

1 11 12 1n

2 11 22 2n

m 1m 2m mn

C C ... C

A x x ... x

A x x x
X

... ... ... ... ...

A x x ... x

 
 
 
 
 
 

 (13) 

where m indicates the number of alternatives, and n indicates the total number of 
criteria. 

Step 2. Normalization of initial matrix (X) elements. 

1 2 n

1 11 12 1n

2 11 22 2n

m 1m 2m mn

C C ... C

A t t ... t

A t t t
N

... ... ... ... ...

A t t ... t

 
 
 
 
 
 

 (14) 

The elements of normalized matrix (N) are obtained using the following 
expressions: 

a) For the "benefit" type criteria 

ij i

ij

i i

x x
t

x x



 





 (15) 

 b) For the "cost" type criteria 



Multi-criteria decision-making in A defensive operation of the Guided anti-tank... 

57 

 

ij i

ij

i i

x x
t

x x



 





 (16) 

where xij, xi+and  xi− are the components of initial decision matrix (X), where xi+ 

and xi− are defined as: 
xi+= max (x1, x2,..., xm) and represents the maximum value of the observed criteria 

by alternatives, 
xi+= min(x1, x2,..., xm) and represents the minimum value of the observed criteria 

by alternatives. 
Step 3. Calculation of weighted matrix elements (V). The elements of weighted 

matrix (V) are calculated on the basis of expression (17): 

ij i ij i
v w t w   (17) 

where tij are the elements of normalized matrix (N), and w represents the weight 
coefficient of criteria. By applying expression (17), we get weighted matrix V that 
otherwise can be written as: 

11 12 1n 1 11 1 2 12 2 n 1n n

21 22 2n 1 21 1 2 22 2 n 2n n

m1 m 2 mn 1 m1 1 2 m 2 2 n mn n

v v ... v w t w w t w ... w t w

v v ... v w t w w t w ... w t w
V

... ... ... ... ... ... ... ...

v v ... v w t w w t w ... w t w

     
   

  
    
   
   

     

 (18) 

where n is the total number of criteria, and m is the total number of alternatives. 
Step 4. Determination of approximate border area (G) matrix. The border 

approximate area (BAA) for each criterion is determined by expression (19) 

1/ m
m

i ij

j 1

g v


 
  
 
  (19) 

where vij are weighted matrix elements (V) and m represents the total number of 
alternatives. 

After determining value gi according to the criteria, we form the matrix of 
approximate border areas G (20) size nx1 (n is the total number of criteria by which 
the election of the offered alternatives is made). 

 
1 2 n

1 2 n

C C ... C

G g g ... g  (20) 

Step 5. Calculation of the matrix elements distance from border approximate area 
(Q) 

11 12 1n

21 22 2n

m1 m 2 mn

q q ... q

q q q
Q

... ... ... ...

q q ... q

 
 
 
 
 
 

 (21) 

The distance of the alternatives from border approximate area (qij) is defined as 
the difference between weighted matrix elements (V) and the values of border 
approximate areas (G). 



 Bojanić et al./Decis. Mak. Appl. Manag. Eng. 1 (1) (2018) 51-66 

58 

Q V G   (22) 

which otherwise can be written as: 

11 1 12 2 1n n

21 1 22 2 2n n

m1 1 m 2 2 mn n

v g v g ... v g

v g v g ... v g
Q

... ... ... ...

v g v g ... v g

   
 

  
 
 
 

   

 (23) 

where gi represents the border approximate area for criterion Ci, vij. is weighted 
matrix elements (V), n represents the number of criteria, and m represents the 
number of alternatives. 

Alternative Ai may belong to border approximate area (G), upper approximate 
area (G+) or lower approximate area (G¯), respectively Ai⋲{G¯˅G+V G¯}. Upper 
approximate area (G+) is an area in which the ideal alternative is found (A+), while 
lower approximate area (G¯) is an area in which the anti-ideal alternative (A¯) is 
found (Fig. 2). 

G


G


A


A


1
A 3

A

4
A

2
A

5
A

6
A

7
A

G

Upper approximation area

Lower approksimation area

Bordere approksimation area

0

0.2

0.4

0.6

0.8

1.0

0.2

0.4

0.6

0.8

1.0

C
ri

te
ri

o
n

 F
u

n
c
ti

o
n

s

 

Figure 2. Presentation of upper (G+), lower (G¯) and border (G ) 

approximation areas (Pamučar, Ćirović, 2015)  

Belonging of alternative Ai to approximate area (G ,G+ or G¯) is determined on the 
basis of expression (24) 

ij

i ij

ij

G  if  q 0

A G  if  q 0

G  if  q 0





 


 




 (24) 

In order for alternative At to be chosen as the best from the set, it is necessary 
that, according to as many criteria as possible, it belongs to upper approximate area 
(G+).  

Step 6. Ranking alternatives. Calculation of the criteria function values by 
alternatives is obtained as the sum of the distances of the alternatives from border 
approximate areas (qi). Summing the elements of matrix Q by rows gives the final 
values of the criteria function alternatives 



Multi-criteria decision-making in A defensive operation of the Guided anti-tank... 

59 

 

n

i ij

j 1

S q ,  j 1, 2,..., n,  i 1, 2,..., m


    (25) 

where n represents the number of criteria, and m represents the number of 
alternatives. 

6. Selection of the optimal firing position of the Guided anti-tank missile 
battery in a defense operation 

6.1. Identification of the criteria and calculation of the weight coefficients of the 

criteria 

A guided anti-tank missile battery performs its tasks from the firing position 
(POP). It is composed of self-propelled launchers LRSPM83. The (POP) is a part of the 
land in the area of the operation, prepared and occupied or intended to be occupied 
by the artillery units for the execution of firing support (The military lexicon, 1981).  

“In order to ensure the effectiveness of fire control and fire coordination, the 
distance in length is 100–300m between self-propelled launchers, and 300–400m 
between platoons. The dimensions of deployment areas can extend to 1,4-2 km in 
width and 1 km in length for batteries, 1km in width and 500m in length for platoons 
depending on the combat situation, terrain, and the number of assets involved.” (Fig. 
3) (Rule book self-propelled anti-tank battery – platoon, 2016). 

 

 

Figure 3. Battery deployment on POP 

Decision-makers usually have to select an (POP) area relying on the acquired 
theoretical knowledge, experience and assessment in the specific situation. A 
number of criteria that influence the ranking and selection of alternatives indicate a 



 Bojanić et al./Decis. Mak. Appl. Manag. Eng. 1 (1) (2018) 51-66 

60 

possibility of applying multiple criteria methods. Founded on the available literature, 
the ranking criteria that are the basis for selection-making are also defined: 

C1– „distance to the targets area“- the distance at which the guided armor-
piercing missiles will neutralize the enemy armored vehicle in the direction of the 
attack. The range of guided armor-piercing missiles is determined by their maximum 
launching distance and the distance of the fire line – influenced by the terrain in front 
of their firing positions; 

C2– „speed of occupancy POP“ - represents the estimate of time for which 
launching devices from the expected region will make an arrival at POP; 

C3– „maneuver capability “ -the maneuver capability of guided anti-tank missile 
units is determined by their mobility (movements to firing positions, during 
maneuvers to deployment areas), and the time required for occupation and leaving 
of the deployment areas; 

C4 – „fortification conditions“ - terrain features that allow successful fortification 
of artillery to enhance force protection; 

C5 – „quality of access roads“ - road characteristics that appreciate the possibility 
of fast and successful settling and abandonment of POP; 

C6 – „masking conditions “ - terrain features that enable successful masking of 
GAMB and movement of GAMB of parts as well as masking of the effects of the rocket 
launching. 

The values of criteria C1 and C2 are described numerically and the values of  
criteria C3, C4, C5i C6 are described with fuzzy linguistic descriptors, Fig. 4 (very poor - 
VL, poor - L, medium - S, good - D and great - O). 

 

1

0.8

0.6

0.4

0.2

1 32 54
0

VL L S D O

 

Figure 4. Graphic display of fuzzy linguistic descriptors (Božanić et al., 

2016b; Pamučar et al., 2016b; Božanić, 2017) 

The first step in defining the weight coefficients is to define the square 
comparison matrix. Two elements of the hierarchy (models) are compared using the 
Saaty’s classic scale and by defining the degree of certainty of a given claim according 
to expression (10). The degree of inconsistency of the given matrix is 0.0352. 

Table 2. Comparison matrix in pairs 

Crit. C1 C2 C3 C4 C5 C6 

C1 1;1 1.4;0.7 1.2;0.6 4.5;0.9 2.5;0.9 3.1;0.9 
C2 0.7;07 1;1 1.1;0.1 1.3;0.9 1.8;0.6 2.6;0.4 



Multi-criteria decision-making in A defensive operation of the Guided anti-tank... 

61 

 

C3 0.8;0.6 0.9;0.1 1;1 2.0;0.5 2.0;0.7 4.1;0.9 
C4 0.2;0.9 0.8;0.9 0.5;0.5 1;1 2.4;0.5 2.5;0.9 
C5 0.4;0.9 0.5;0.6 0.5;0.7 0.4;0.5 1;1 1.2;0.5 
C6 0.3;0.9 0.4;0.4 0.2;0.9 0.4;0.9 0.8;0.5 1;1 
 
The values of the Table 2 matrix are converted into fuzzy numbers by applying 

the fuzzificated Saaty’s scale (Table 1), so that a new matrix is shown in Table 3. 

Table 3. Comparison matrix in pairs after fuzzification 

 Crit. C1 C2 C3 C4 C5 C6 

C1 1;1;1 1.0;1.4;1.8 1.0;1.3;1.8 4.1;4.5;4.9 2.3;2.5;2.8 2.8;3.1;3.4 

C2 0.6;0.7;1.0 1;1;1 1.0;1.1;2.1 1.2;1.3;1.4 1.1;1.9;2.6 1.0;2.6;4.2 

C3 0.6;0.8;1.0 0.5;0.9;1.0 1;1;1 1.0;2.0;3.0 1.4;2.0;2.6 3.7;4.1;4.5 

C4 0.2;0.2;0.2 0.7;0.8;0.8 0.3;0.5;1.0 1;1;1 1.2;2.4;3.7 2.3;2.5;2.8 

C5 0.4;0.4;0.4 0.4;0.5;0.9 0.4;0.5;0.7 0.3;0.4;0.8 1;1;1 1.0;1.2;1.8 

C6 0.3;0.3;0.4 0.2;0.4;0.9 0.2;0.2;0.3 0.4;0.4;0.4 0.5;0.8;1.0 1;1;1 

 
The weight vector w of every criterion of the Table 3 matrix is the sum of the 

linguistic expressions that describe the criteria in the same row of the Table 3 matrix, 
which is divided by the sum of all linguistic expressions that describe the criteria of 
the Table 3 matrix. After the calculation, the weight vectors of the criteria are 
obtained (Table 4). The label "l" represents the left distribution of the fuzzy number; 
"d" represents the right distribution of the fuzzy number and "s" - a place where the 
level of the membership of the fuzzy number has a value one. 

Table 4. Fuzzy weight vectors of the criteria 

Criteria "l" "s" "d" 
C1 0.203 0.293 0.424 
C2 0.113 0.191 0.339 
C3 0.126 0.217 0.327 
C4 0.085 0.139 0.234 
C5 0.059 0.092 0.159 
C6 0.045 0.068 0.119 

 
Finally, by applying expression (11) the defuzzification of the weight coefficients 

of the evaluation criteria is performed. The final values of the weight coefficients of 
the criteria are given in Table 5. 

Table 5. Final values of the weight coefficients 

Criteria  Weight coefficients (w) 
C1 0.307 
C2 0.214 
C3 0.223 
C4 0.152 
C5 0.103 
C6 0.077 



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62 

6.2. Application of the MABAC method for ranking alternatives 

In order to apply the MABAC method, six alternatives have been selected (from A1 
to A6) (Table 6). The alternatives represent a land area that the artillery means will 
be deployed on. The initial decision matrix is presented in Table 6. Since evaluation 
criteria C3, C4, C5 and C6 have a qualitative character, for the evaluation of alternatives 
by criteria, the fuzzy linguistic descriptors scale is used.  

Table 6. Initial decision matrix 

Alternative 
C1 

(min) 
C2 

(min) 
C3 

 (max) 
C4  

(max) 
C5  

(max) 
C6  

(max) 
A1 1300 6.00 S o d s 
A2 2200 8.00 O vl s o 
A3 1950 11.00 L s l s 
A4 1400 10.00 Vl l s o 
A5 2500 5.00 S vl l s 
A6 1700 9.00 O d d l 

 
Defuzzification is performed by applying expression (12). The next step is the 

normalization of the matrix elements and the final values of the normalized matrix 
are presented in Table 7. 

Table 7. Normalized matrix 

Alternative 
C1 

 (min) 
C2  

(min) 
C3 

(max) 
C4 

(max) 
C5 

(max) 
C6 

(max) 
A1 1.000 0.833 0.500 1.000 1.000 0.375 
A2 0.250 0.500 1.000 0.000 0.500 1.000 
A3 0.458 0.000 0.201 0.500 0.000 0.375 
A4 0.917 0.167 0.000 0.201 0.500 1.000 
A5 0.000 1.000 0.500 0.000 0.000 0.375 
A6 0.667 0.333 1.000 0.799 1.000 0.000 

 
Using the next steps of the MABAC method, the distance values of the alternatives 

from the border approximate area are obtained and their ranking is shown in Table 
8.  

Table 8. Ranking of the alternatives 

Alternative Si Rang 
A1 0.309 1 
A2 0.055 3 
A3 -0.200 6 
A4 0.032 4 
A5 -0.119 5 
A6 0.229 2 

Based on the obtained distances from the ideal alternative, it can be concluded 
that alternative (A1) is the most appropriate alternative while alternative  (A3) is the 
least favorable one.  



Multi-criteria decision-making in A defensive operation of the Guided anti-tank... 

63 

 

7. Sensitivity analysis of the output results 

It is recommended as a means of checking the stability of the results against the 
subjectivity of decision-makers. The sensitivity analysis of the results is carried out 
by changing the initial weight coefficients of the evaluation criteria. Table 9 gives the 
scenarios of change of weight coefficients (seven scenarios), based on which the 
ranking of the already presented alternatives is performed. 

Table 9. Scenarios with different weights of the criteria 

Criteria S1 S2 S3 S4 S5 S6 S7 

C1 0.2 0.6 0.1 0.1 0.1 0.1 0.1 

C2 0.2 0.1 0.6 0.1 0.1 0.1 0.1 

C3 0.2 0.1 0.1 0.6 0.1 0.1 0.1 

C4 0.2 0.1 0.1 0.1 0.6 0.1 0.1 

C5 0.2 0.1 0.1 0.1 0.1 0.6 0.1 
C6 0.2 0.1 0.1 0.1 0.1 0.1 0.6 

 
The ranking of the alternatives after the application of the scenario is given in 

Table 10. By analyzing the obtained results, it can be concluded that there is 
significant stability of the output results in most of the scenarios. This is supported 
by the fact that A1 and A4 are most often ranked as the first or the second, which is 
expected for a stable system. 

Table 10. Ranks of alternatives by applying different situations 

Alternative 
Rank from 

Table 8 
S1 S2 S3 S4 S5 S6 S7 

A1 1 1 1 1 3 1 1 3 
A2 3 3 4 3 2 5 3 1 
A3 6 6 5 6 6 3 6 6 
A4 4 4 2 5 5 4 2 2 
A5 5 5 6 2 4 6 5 5 
A6 2 2 3 4 1 2 4 4 

8. Conclusions 

The application of the (MCDM) model is successfully presented in the paper while 
the sensitivity analysis indicates the potential of the application of the created 
models to support decision-making during the planning process of the Land Forces 
operation. In a similar way, the application would be conducted in group decision-
making. 

A practical example of the fuzzy scale demonstrated a possibility of using the 
hybrid fuzzy AHP-MABAC model, its performance in ranking the offered alternatives. 
The analysis of the output results sensitivity has shown that the hybrid FAHP-
MABAC model provides stable solutions for the problem of choosing an optimal 
firing position of the Guided anti-tank missile battery. The proposed hybrid approach 
can solve not only the problems of location choice, but also many other decision-
making ones. 



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64 

From all of the above mentioned, it can be concluded that the fuzzificated Saaty’s 
scale improves decision-making by taking into account the degree of certainty of 
decision-makers in the shown pairwise comparison.  

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