Operational Research in Engineering Sciences: Theory and Applications 
Vol. 4, Issue 1, 2021, pp. 67-81 
ISSN: 2620-1607 
eISSN: 2620-1747 

 DOI: https://doi.org/10.31181/oresta2040127s 

* Corresponding author. 
nikolasimicva@hotmail.com (N. Simić), miladin@kg.ac.rs (M.Stefanović), 
pgoran@masfak.ni.ac.rs (G.Petrović), aleksandar.stankovic@masfak.ni.ac.rs (A.Stanković) 

USE OF THE RISK ANALYSIS APPROACH IN THE SERBIAN 
ARMY INTEGRATION PROCESS AGAINST COVID-19 

Nikola Simić*1, Miladin Stefanović2, Goran Petrović3, Aleksandar 
Stanković3 

1 The Serbian Army, Logistics training centre, Kruševac, Serbia 
2 Faculty of Engineering, University of Kragujevac, Serbia 

3 Faculty of Mechanical Engineering, University of Niš, Serbia 
 

Received: 29 September 2020 
Accepted: 03 January 2021 
Published: 23 February 2021 

Research paper 

Abstract: Current developments have contributed to organisations paying increasing 
attention to protecting resources, employee safety, and applying quality products and 
services. There is a need for increasing the application of standards that define the way 
of managing quality, safety at work, risk, and many others. One such organisation is 
the Serbian Army, a complex centralised system that requires integrating these 
standards, and often stricter, in all fields of its activities. The current situation in the 
world, and therefore in Serbia, is sufficient motivation for the project provided by this 
paper. This project aims to show the integration of risk management systems and 
occupational safety systems, through the level of protection and exposure of members 
of the army to the virus infection COVID-19 during the implementation of emergency 
tasks, by defining risks and proposing additional measures to reduce the level of risk 
and increase the protection of military personnel. 

Keywords: virus infection, risk, safety management, emergencies, Serbian Army 

1. Introduction 

The development of the most critical events in the 21st century has confirmed 
that the survival of nations and citizens will increasingly depend on the security of 
the essential functions of society. The ability to protect the population, ensure the 
functioning of government and civil society institutions, maintain critical 
infrastructure, and the democratic principles of functioning of state institutions are 
under enormous pressure in the face of crises. As no crisis is an isolated event "per 
se," awareness and readiness to counter non-military threats are focused on 
analysing complex security policy fields based on different management systems, 
which imposes the need for so-called integrated management systems 
(IMS). Because of this complexity, the identification and analysis of threats usually 

mailto:nikolasimicva@hotmail.com
mailto:miladin@kg.ac.rs
mailto:pgoran@masfak.ni.ac.rs
mailto:aleksandar.stankovic@masfak.ni.ac.rs


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involve assessing multiple risks and studying scenarios of a limited number of 
situations identified as potentially risky or catastrophic (Jørgensen et al., 2006). At 
present, risk assessments and crisis management concepts differ significantly in 
many countries and are conducted in the broader context of risk and crisis 
management. The primary and indisputable responsibility for protecting citizens and 
the fundamental values of society lies with the states. By improving awareness and 
understanding of the risks faced by states, decision-makers have a better position to 
agree on preventive measures to be taken and to prepare to avoid the most severe 
consequences of natural and human-made disasters. In the context of the 
responsibility of the state to prevent and resolve the effects of crises, special 
responsibility lies with the army, with an assessment of the comparative advantage 
of the military over other state bodies, but also the functional needs and 
opportunities for an effective response to non-military security threats (Karović et 
al., 2010). One such security threat is certainly the pandemic caused by the COVID-19 
virus infection. It represents a new type of "enemy" that the Serbian Army has not 
yet encountered in its history. Therefore, this research becomes more exciting and 
encourages and motivates further courses of study. The analysis of various scenarios, 
which represent the core of the study, is focused on determining all assumptions, 
possibilities, risks, and prospects for the use of units of the Serbian Army, based on 
risk assessment, on showing the level of exposure to viral infection in military 
missions. As a result of this project, the preparedness, level of exposure, and 
protection of Serbian Army members' are highlighted, and shortcomings are spotted. 
Possible ways are considered for further suppression and security, while this paper 
gives new additional measures of security and safety of members in some future 
similar non-military threats. 

2. Covid-19 review and application of the Serbian Army in non-military 
security threats through swot analysis 

COVID-19 is a disease caused by a coronavirus. Coronaviruses are viruses that 
circulate among animals, but some of them can spread to humans. After they pass 
from animal to human, humans can distribute viruses among themselves. For 
example, the coronavirus of the respiratory syndrome SARS originates from the 
Viverridae, an animal from the order of beasts related to cats. Discovered in China in 
2003, it is genetically closely related to the COVID-19 virus, and the two viruses have 
similar characteristics. In eight months, 33 countries reported more than 8,000 cases 
of SARS. Then one in ten infected people died of SARS. COVID-19 is SARS-CoV-2. It 
was detected in China, the city of Wuhan, Hubei Province, at the end of 2019, the first 
case on November 17, 2019. year (Ma Josephina, 2020), while the first case in the 
territory of Serbia arose on March 6, 2020. year (Government of Serbia, 2020). It is a 
new strain of coronavirus that has not been detected in humans before.   

Although the virus originates from animals, it now spreads from person to person 
(human-to-human transmission). The virus is mainly transmitted by droplets when 
sneezing and coughing. Preliminary research indicates that the average incubation 
period is 5-6 days, with a maximum of up to 14 days (Chu et al., 2020). Although 
people are most contagious when they have symptoms (similar to seasonal flu 
symptoms - fever, sneezing, cough, muscle aches, fatigue). There are indications that 
some people can transmit the virus even though they have no signs or before 



Use of the risk analysis approach n the Serbian army integration process against Covid-19 

 

69 
 

symptoms appear, which is not uncommon with other viral infections. In severe 
cases, severe pneumonia, acute shortness of breath syndrome, sepsis, and septic 
shock occur, which can cause the patient's death. Older people and people with 
chronic diseases (such as high blood pressure, heart disease, diabetes, liver 
disorders, and respiratory diseases) have a higher risk of developing more severe 
forms of this disease. However, the exposure to this infection is not decreased for 
emergency and state services, including members of the Serbian Army.  

The Serbian Army is an organised armed force that defends the country from 
armed threats from outside and performs other missions and tasks, following the 
Constitution, law, and principles of international law that regulate the use of force 
(Law on the Serbian Army, 2019). The President of the Republic or the Minister of 
Defense, upon the authorisation of the President of the Republic, may decide that the 
Serbian Army shall assist the competent state body, i.e., organisation, the body of 
autonomous provinces and local self-government units, at their request, for 
protection of life and safety of people and property, for other reasons determined by 
law (Official Gazette of the Republic of Serbia, 2019). After the war in the 1990s, the 
Serbian Army actively participated in implementing the third mission of the army, 
i.e., assisted civilian authorities in the event of natural disasters, technical-
technological and other accidents. The military usage for civilian purposes could be 
noticed during firefighting actions on several occasions in recent years, then during 
the floods of 2014 and 2019, and during the migrant crisis to help civilian structures 
conduct migrants through the territory Serbia. However, the situation that caused 
the second state of emergency in the country in the 21st century after the prime 
minister's assassination in 2003 showed that the modern army had not encountered 
such a threat so far. The last time army was used in such a case, former JNA, in this 
territory was in 1972, during the smallpox epidemic "Variola Vera," on securing 
temporary hospitals. The necessary measures applied by JNA members were 
protective masks and steeled discipline, and the intensification of hygiene 
(Radovanovic, 2017). The situation with the disease at that time did not seem to 
bring any experience, so the Serbian Army entered the fight against COVID-19 
practically unprepared. Until the declaration of emergency on March 15, 2020, 
activities and tasks in the Serbian Army were going according to plan (Official gazette 
of the Republic of Serbia, 2020).  

Table 1. SWOT analysis 

Strengths – S Weaknesses - W 
The medical and health care system is gradually 

improving - the Military Medical Academy. 

The COVID-19 epidemic has spread to many 

regions in a short period. 

Comprehensive progress of the military health 

system in terms of taking measures. (Blumenthal 

et al., 2020). 

Rumours of wider disinformation 

Rapid and efficient cooperation of joint 

prevention and control of the military and 

civilian structures. (Blumenthal et al., 2020). 

Serbia's population density is 98.1 in / km2 

 Lack of aid and labour supplies (Ebrahim, 2020) 

 
Lack of equipment and accommodation  

(Rimmer, 2020) 

 The public is upset and lacks awareness. 



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Namely, for such a case of non-military security threat, there is no plan in the 
army. All forces are focused on helping civilian structures in extinguishing fires, 
assistance during floods, and select units of atomic-biological-chemical defence that 
are engaged in case of CBRN accident. In a way, the unpreparedness for "fighting" 
against COVID-19 is understandable. Hence the solution to why lessons and 
experiences were not learned from the epidemic of the 1970s. 

Concerning the previous, SWOT analysis presents the situations, which refers to 
the assessment of various strengths (S), weaknesses (W), opportunities (O), threats 
(T), and other factors that affect a particular topic. It comprehensively, 
systematically, and accurately describes the scenario in which the issue is situated. 
This helps to formulate appropriate strategies, plans, and countermeasures, based on 
the results of the assessment (Jasiulewicz-Kaczmarek, 2016). This method can be 
used to identify favourable and unfavourable factors and conditions, target current 
problems, identify challenges and threats, and formulate strategic decision-making 
plans. This SWOT analysis (Table 1) of COVID-19 is based on the experience of the 
reaction to the SARS epidemic from 2003, and the data as a basis are taken from the 
annual health statistics - China for 2019 and adjusted for R. of Serbia (China Health 
Statistics Yearbook, 2019). 

Based on the presented SWOT analysis, it can be concluded that the defence 
forces are extraordinary mild and that the weaknesses are too many. It can also be 
added that the Serbian Army is spread over the entire territory. Due to the 
realisation of tasks, there is a need to connect personnel on specific charges, which 
was the case during the formation of a temporary hospital in the military institution 
"Morovic." The lack of protective equipment can be singled out as a fundamental 
problem because with the existing resources, members are not adequately protected 
under regulations (eg. Surgical masks in pharmacies do not have a long-lasting effect; 
according to some estimates, only 2-3 hours (Chu et al., 2020). Also, the chances that 
may only arise after a pandemic are reflected inexperience, not allowing the same 
omissions as during the epidemic of the 70s. As for threats, the most dangerous is 
related to the army members who are in an unenviable position, given their constant 
engagements and returns to their families after them. There is an increased risk of 
exposure to loved ones, regardless of government measures and curfews.  

Based on the analysis, the fight against this type of "enemy" is shown in the 
following text. So far, the Serbian Army's application in the implementation of the 
third mission has shown that members of the army have not encountered this type of 
"enemy." Role insecurity is one of the daily tasks of members of the army. During the 

Opportunities – O Threats - T 
New research COVID-19 

(Salvatore et al., 2020) 

Impact on the daily life, work, and psychology of 

employees 

(Barnes & Sax, 2020) 

Further improvement and inspection of the health 

system in the army (Blumenthal et al., 2020) 

Impact on the national economy 

(Salvatore et al., 2020) 

Opportunities for education for infectious 

diseases and gaining new experiences in 

combat (Blumenthal et al., 2020) 

 

Possible virus carriers to their families 

 



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security, standardised equipment is used following standardisation documents that 
are even stricter than management systems' standards. The standardisation 
documents are the standards of defence of the Republic of Serbia (SORS), product 
quality regulations (PKP), and technical regulations in the field of protection (TPO) 
(Official military gazette, 2018).  

The defence standard is a document that refers to specific items for the needs of 
defence and contains technical specifications and criteria that ensure that the 
material, products, processes, and services correspond to the purpose. The product 
quality regulation is a document that contains data important for quality in research, 
development, and production. At the same time, the TPO is a document related to 
facilities, devices, and plants for other processes, products, and services in the field of 
defence (Official military gazette, 2018). The Standards of Defense of the Republic of 
Serbia (SORS), formerly the Standards of National Defense (SNO), are applied to 
every means, weapon, equipment in use, like the ones in the following figures.  

This case study will present three cases in the suppression of COVID-19, as 
follows: 

- Provision of civilian hospitals, health centres, gerontology centres, and other 
public facilities of importance. During security, members were exposed to 
contact with staff employed in health facilities, controlled the entry and exit 
of patients, and performed their identification, as well as the passing of 
motor vehicles. 

- Establishment of temporary "COVID" hospitals in sports halls and the 
military institution "Morovic." The engagement of members in the formation 
of temporary hospitals was realised in all significant hotspots. They showed 
the most significant efforts during the construction of the hospital at the Fair 
in Belgrade. With a minimum of equipment (surgical mask and gloves), the 
assessment was that the members were protected during this task's 
realisation. 

 

Figure 1. A member of the army during the construction of the COVID hospital 

- Specialised units of the army realised disinfection of public areas and 
buildings. The members of the CBRN units had the best protection, but also 
the most challenging task, because by the nature of their work, they were 



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most exposed to chemical substances, and they were equipped with overalls, 
unique protective masks, and gloves at all times. 

 

Figure 2. A member of the CBRN service on the task of disinfection 

3. The methodological framework of the research 

Research has the character of a theoretical-empirical procedure, where the design 
and implementation combine theoretical methods of scientific research and 
empirical methods.  

Based on data from foreign and domestic literature, the descriptive method was 
used to present the viral pandemic situation as comprehensively as possible, both in 
the world and in the Republic of Serbia. When comparing the cases in which the 
army was engaged, a comparative analysis was used. The inductive-deductive 
method was used to draw lessons from foreign countries' experiences, primarily 
China and Russia. When generalising certain phenomena related to COVID-19 and 
the Serbian Army's use, the analytical-synthetic method was applied.  

The scientific significance of this project work lies in the new theoretical approach 
in defining the army's role in combating similar non-military security threats and 
assisting decision-makers with the advantages of this research; those are new 
adequate measures in case of possible recurrence. 

4. Case study 

So far, the Serbian Army's application has shown that members of the army have 
not encountered this type of "enemy." This case study will compare the levels of risk 
of exposure of members of the Serbian Army to COVID 19 infection in three cases, by 
multicriteria decision using the TOPSIS method, where issues are defined as options 
(A) and risks (K), after which alternatives will be ranked. Appropriate conclusions 
will be drawn for better protection of employees during the performance of duties in 
these cases: 



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Case 1: Securing civilian hospitals, health centres, gerontology centres, and other 
critical public facilities. During security, members were exposed to contact with staff 
employed in health facilities, controlled the entry and exit of patients, and performed 
their identification, as well as the passing of motor vehicles.  

Case 2: Establishment of temporary "COVID" hospitals in sports halls and the 
military institution "Morović." The engagement of members in the formation of 
temporary hospitals was realised in all significant hotspots. They showed the most 
significant efforts during the construction of the hospital at the Fair in Belgrade. With 
a minimum of equipment (surgical mask and gloves), the assessment was that the 
members were protected during this task's realisation.  

Case 3: Disinfection of public areas and buildings carried out by specialised 
military units. The members of the CBRN units had the best protection, but also the 
most challenging task, because by the nature of their work, they were most exposed 
to chemical substances, and they were equipped with overalls, unique protective 
masks, and gloves at all times. 

After defining the cases and gathering information on the dangers posed by a 
viral infection, a risk assessment follows. One of the simplest methods used is to 
determine the level of risk. Three levels of severity of consequences and three levels 
of Probability of occurrence are defined, and then the level of risk is specified based 
on these data (Table 2). 

Table 2. Defining risk levels 

                    Consequences 
Probability 

         Slightly      
Dangerous 

Dangerous   Extremely 
Dangerous 

Probable event  
 MEDIUM RISK HIGH RISK VERY 

HIGH RISK 

Rare event      LOW RISK 
MEDIUM           

RISK 
HIGH RISK 

Sporadic event 
VERY 

LOW RISK 
  LOW RISK 

MEDIUM  
RISK 

Based on the presented method of risk assessment and perception of the 
situation in the field, the risk assessment of the study case takes the Probability of 
events: Probable event, and based on the table, we see the consequences of events 
through a medium, high, and very high risk. A rare event is not taken as a reference, 
and also, the situation is not harmless, so a sporadic occurrence and a shallow risk 
are excluded (Čerepnalkovska, 2016). Based on the above, the risks and levels of risk 
are defined, which are shown in Table 3: 

 
 
 
 
 



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74 
 

Table 3. Defining risks and levels - weighting coefficients 

Risk 
MEDIUM 

RISK 
HIGH RISK 

VERY 

HIGH 

RISK 

Risk 1 
Level of protection of 

members of the Armed Forces  

1 3 5 

Risk 2 Possibility of infection 

Risk 3 

Possibility of possible 

transmission to other members 

of the Armed Forces 

Risk 4 
Possibility of possible 

transmission to their families 

Risk 5 Presence of chemicals 

Risk 6 
Possibility of unwanted 

contact and conflict 

 
Explanation of the level of risk (weighting coefficients) of the First Case:  
- The protection of members of the Armed Forces was assessed as "very high 

risk" because members use only surgical masks N95 or AM-1002 and surgical 
gloves. 

- The possibility of infection was assessed as "high risk" because members are 
exposed to potential patients at the entrance to public buildings, keeping a 
distance of 2 meters but with a personal identification check that requires a 
reduction in the prescribed space.  

- The possibility of possible transmission was assessed as "very high risk" 
because members come to work after completing the task and then go to their 
homes. There is a possibility that they are potentially infected.  

- Persons on this task are not exposed to excessive effects of disinfectant 
chemicals.  

- The possibility of unwanted contact and conflict was assessed as "high risk" 
because there are situations in which potentially infected people refused to 
cooperate and were brought to the brink of physical confrontation.  

Explanation of the level of risk (weighting coefficients) of the Second Case:  

- The level of protection of members of the Armed Forces was assessed as "very 
high risk" because members use only a surgical mask, improvised mask, and 
surgical gloves or work gloves (Figure 1).  

- The possibility of infection was assessed as "high risk" because the members 
are at a distance of fewer than 2 meters and a large concentration of people in 
one place.  

- A possible transfer was assessed as "high risk" because members remain in 
contact after the task, during the rest and preparation for the next job but do 
not come into contact with their families.  

- Persons on this task are exposed to a specific effect of chemicals during the 
disinfection of established hospitals, and this risk is assessed as "high risk." 

- The possibility of unwanted contact and conflict was assessed as "medium 
risk" because there are no other persons than members of the Armed Forces 
to implement this task.  



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Explanation of the level of risk (weighting coefficients) of the Third Case:  

- The level of protection of CBRN members was assessed as "medium risk" 
because they use special protective equipment for particular purposes (Figure 
2).  

- The possibility of infection is assessed as "high risk" because members do not 
come into direct contact with the infected or potentially infected. 

- A possible transfer was assessed as "high risk" because they are in constant 
contact with each other and go to their families after work.  

- People on this task are most exposed to chemicals during disinfection because 
in addition to the use of chemicals, it is necessary to do the same, and this risk 
is assessed as "very high risk."  

- The possibility of unwanted contact and conflict was assessed as "medium 
risk" because there are no persons other than CBRN members to implement 
this task. 

4.1. Technique for order preference by similarity to an ideal solution 

The Technique for the Order Preference by Similarity to Ideal Solution (TOPSIS) 
was introduced by Hwang and Yoon (1981). The standard TOPSIS method is based 
on the concept that the best alternative should have the shortest Euclidian distance 
from the ideal solution, and at the same time, the farthest from the anti-ideal 
solution. TOPSIS method can be implemented using the following steps: 

Step 1: Method starts with determination of a Decision matrix X = (xij)m x n, in 
which element xij indicates the performance of alternative Ai when it is evaluated in 
terms of decision criterion Cj, (for i = 1, 2, 3,..., m and j = 1, 2, 3,..., n): 

    C  C 
 2 

 C 
n 

   
          1          

 X = xij = 
A   x  x  ... x     
      1 

 
 11   12   1n 

 ; 
 

A x 
  

x 
 

... x 
   

   

 21 
 

22 2n  
  

        2          

              

  
A 

 
x 

   
x 

  
... x 

     
  

 m1 
 

m2 mn  
  

       m        

Step 2: Determine the normalized decision matrix which elements are rij: 

      x            
  

rij = 
  ij    

, 
       

      m           
                 
       ij          

       
x 

2          
                 

      i=1            

Step 3: Obtain the weighted normalized decision matrix whose elements are vij by 
multiplying each column j of the normalized matrix by its associated weight wj: 

         vij  = rij   w j ,                                     (3) 

Step 4: Determine the positive ideal and the negative ideal solutions: 

 

                     (4) 

(1) 

(2) 



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76 
 

Where B and C are associated with the maximisation and minimisation criteria 
sets, respectively. 

Step 5: Calculate the separation measures (Euclidean metric) from the positive 
ideal solution and the perfect negative solution. The separation of each alternative 
from the perfect positive solution is given as: 

  

+ 

 

 

+ 

) 

2 

 

   n 

Si = (vij  −V j  

       j=1     

 
The separation of each alternative from the negative ideal solution is given as: 

    

 − 

  

− 

) 

 

2 

. 

   n 

Si= (vij  −V j  

    j=1     

         

Step 6: Calculate the relative closeness of the i-th alternative Ai to the positive ideal 
solution: 

  𝑃𝑖 =
𝑆𝑖

−

𝑆𝑖
+ + 𝑆𝑖

− 

The relative closeness Pi can have values between (0, 1), whereby Pi = 0 
represents a negative ideal solution, while Pi = 1 stands for a perfect positive 
solution. According to Pi values, the alternatives can be ranked. The best option has 
the highest value, Pi, because it is the closest to the positive ideal solution. 

Since the last part of the paper defines alternatives (A) and criteria (K), it is 
necessary to determine the weights of the bars (risk), based on an exchange of 
opinions with occupational safety officers, for the application of the TOPSIS method, 
according to the following: 

- for K1 - 0.4 - is considered the most important because it is the protection of 
human lives;  

- for K2 - 0.2 - presented as an important criterion because it entails other risks 
and possibilities of spreading the infection;    

- for K3  - 0.1 - presented as a medium-important criterion because there is a 
possibility of spreading the disease to military circles;  

- for K4 - 0.15 - presented as an essential criterion because employees, finishing 
their work, can spread the disease to their family members; 

- for K5  - 0.1 - it is considered not very important because only select units of 
the army work with chemicals; 

- for K6 - 0.05 - presented as the least important criterion because the cases are 
individual. 

 
 
 
 

(5) 

(6) 

(7) 



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77 
 

 
Figure 3. Defining risk levels by alternatives 

The first step is the initial table-matrix of initial data with the assignment of 
coefficients, determination of values that are minimised and maximised, and 
assignment of weight values, which is shown in Table 4. 

Table 4. Assignment of values and determination of max and min and weight values 

  Criteria    

K1 K2 K3 K4 K5 K6 
0.4 0.2 0.1 0.15 0.1 0.05 

Alternatives min min min min min min 

A1 5 5 3 1 3 1 

A2 3 5 4 2 3 3 

A3 1 3 5 3 5 5 

 
The values of the criteria are determined, where maximised-rewrite and 

minimised-convert to the max, as shown in Table 5: 

Table 5. Criterion values obtained after minimisation and maximisation 

   Criteria    

                                K1 K2 K3  K4 K5 K6 
0.4 0.2 0.1 0.15 0.1 0.05 

   Alternatives min min min min min min 

A1 0 0 2 4 2 4 
A2 2 0 1 3 2 2 
A3 4 2 0 2 0 0 

 
The next step is to determine the norm and to form a normalised matrix. The 

determination of weighted values follows this, and the obtained data are shown in 
Table 6: 

 



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78 
 

Table 6. Weighted values 

   Criteria     

K1 K2 K3 K4 K5 K6 
0.4 0.2 0.1 0.15 0.1 0.05 

Alternatives min min min min min min 

A1 0 0 0.089 0.111 0.070 0.044 
A2 0.178 0 0.044 0.083 0.070 0.022 
A3 0.357 0.2 0 0.055 0 0 

Best max 0.357 0.2 0.089 0.111 0.070 0.044 
Best min 0 0 0 0.055 0 0 

 
Finally, the distance is calculated according to the shown values, and the 

alternatives are ranked, as shown in Table 7. 

Table 7. The final ranking of alternatives 

  Criteria  
 

 

S+ S- 
The similarity to the 

solution       RANK 

A1 0.1345 A1 0.40987 A1 0.7528 1 

A2 0.2006 A2 0.27436 A2 0.5775 2 

A3 0.4098 A3 0.13454 A3 0.2471 3 

Based on the final rank of alternatives shown in Table 7, it is concluded that 
members of the Serbian army engaged in protecting hospitals and public institutions 
(alternative 1) were most exposed to COVID-19 infection. The risk of their disease is 
the most significant, primarily due to daily exposure to potentially infected persons. 
In contrast, the lowest possibility of infection was present in members of the CBRN 
service (alternative 3) because they possessed the highest protection level. Members 
of the army engaged in the formation of "covid" hospitals were ranked second 
because there was no one in their presence except themselves.  

A graphical representation of the final rank of alternatives is shown in Figure 4. 

 
Figure 4. Graphical representation of the final rank of alternatives by the TOPSIS method 



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5. Conclusion 

This research showed the level of protection and risk of members of the Serbian 
Army. Which were engaged in three cases, with some new security, which motivated 
the authors to examine the level of maximum risk exposure and identifies gaps and 
shortcomings, and proposes additional measures based on the research 
results. Based on the case study and the application of multicriteria decision-making 
using the TOPSIS method, the results showed that military members are most 
exposed to the possibility of contracting COVID-19 virus infection, primarily due to 
low levels of protection and contact with potentially ill persons. CBRN members 
serve, thanks to their protective equipment and almost minimal contact with 
potentially infected people, they are the safest from the effects of a viral 
infection. Members in the second case who were engaged in the formation of "covid" 
hospitals were assessed with a medium level of risk due to their spatial distribution 
in places where no viral agents were present. Based on the research and case study, 
measures can be concluded and proposed to further prevent the spread of infection 
according to the following:  

▪ Provide sufficient quantities of surgical masks to ensure the condition of 
replacement every two hours,  

▪ At the entrance to human accommodation (for pedestrians and vehicles), install 
and maintain disinfection barriers in the complexes (NaClO, Pinosteril 200, 
Chlor, Alcohol 70%),  

▪ Regularly disinfect the premises for housing and dining of people,  
▪ Perform regular personal and collective hygiene and accommodation and eating 

people, i.e., before eating to control the personal hygiene of all persons,  
▪ During the execution of hospital security tasks, avoid close contacts with persons 

who show signs of acute respiratory diseases and strictly adhere to all 
prescribed measures,  

▪ Indirect communication with the civilian population, provide a distance of at 
least 2 meters,  

▪ measure the members' temperature before performing the task, and send it to 
the ambulance if it occurs.  

▪ Use protective equipment (gloves and visor) when making the disinfectant 
mixture,  

▪ After engaging in tasks, disinfect personnel and equipment. 

Experiences that can be gained during this project's development are that the 
approach to the problem must be more serious and meaningful. It is necessary to 
look retroactively and see that preparation didn't exist for this type of "fight" and 
that for some future situations, all the people should be in the machine in a state of 
emergency. 

Acknowledgement 

This research was financially supported by the Ministry of Education, Science and 
Technological Development of Serbia. 



Simić, et al., /Oper. Res. Eng. Sci. Theor. Appl. 4 (1) (2021) 67-81  

 

80 
 

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https://dx.doi.org/10.1016%2FS2352-4642(20)30235-2

	USE OF THE RISK ANALYSIS APPROACH IN THE SERBIAN ARMY INTEGRATION PROCESS AGAINST COVID-19
	Nikola Simić*1, Miladin Stefanović2, Goran Petrović3, Aleksandar Stanković3
	1. Introduction
	2. Covid-19 review and application of the Serbian Army in non-military security threats through swot analysis
	3. The methodological framework of the research
	4. Case study
	4.1. Technique for order preference by similarity to an ideal solution

	References