*Corresponding Author

P-ISSN: 1412-1212
E-ISSN: 2541-2388

123

The Winners, 22(2), September 2021, 123-136
DOI: 10.21512/tw.v22i2.7056

Risk and Supply Chain Mitigation Analysis Using House 
of Risk Method and Analytical Network Process

Shelvy Kurniawan1*; Denny Marzuky2; Rio Ryanto3; Vanny Agustine4

1,2,3,4 Management Department, BINUS Business School Undergraduate Program, Bina Nusantara University
Jl. Kebon Jeruk Raya No. 27, Kebon Jeruk, Jakarta 11530, Indonesia

1shelvy.kurniawan001@binus.ac.id; 2dennymarzuky1997@gmail.com; 
3rioryanto9@gmail.com; 4vanny.agustine28@gmail.com

Received: 12th February 2021/ Revised: 07th June 2021/ Accepted: 07th June 2021

How to Cite: Kurniawan, S., Marzuky, D., Ryanto, R., & Agustine, V. (2021). Risk and supply chain mitigation analysis 
using house of risk method and analytical network process. The Winners, 22(2), 123-136.

https://doi.org/10.21512/tw.v22i2.7056

Abstract - The research studied PT XYZ, a 
company engaged in the palm oil industry which 
has eleven subsidiaries spread across five provinces 
in Indonesia. The research focused on analyzing 
supply chain risks in PT A, a subsidiary of PT XYZ. 
The objective was to find out and reduce unexpected 
costs that the company may experience caused by the 
risks in supply chain. Furthermore, the aim was to 
determine priority of risk agents and risk mitigation 
actions. The research method was a mixed methods, 
which combined both qualitative and quantitative 
analysis to answer the research questions. Data 
analysis procedure involved Supply Chain Operations 
Reference (SCOR), House of Risk (HOR) 1, and 
Analytic Network Process (ANP). The SCOR method 
was used for mapping supply chain activities, the HOR 
1 was to determine the priority of the risk agent, and 
the ANP was to determine the priority of mitigation 
actions. The results show that there are 36 risk events 
and 35 risk agents. 19 risk agents are categorized as 
priority risks and 11 preventive actions are proposed 
to be implemented by PT XYZ. The research suggests 
that the company implement mitigation actions 
according to priority in accordance with the research 
results.

Keywords: risk analysis, supply chain analysis, 
mitigation analysis, House of Risk (HOR), Analytical 
Network Process (ANP) 

I. INTRODUCTION

Competition in the current era of globalization 
is very high. This can be seen from the number of 
companies that have emerged, developed, grown, and 
competed in their respective fields. Based on data 

from the Central Statistics Agency, the number of 
companies in Indonesia was recorded at 26,7 million in 
2016 (Agustinus, 2017). This figure increased by 3,98 
million when compared to the number of companies 
in 2006. With intense competition, companies must be 
able to maintain busines processes and provide their 
best products or services. Companies strive to manage 
risk, handle unexpected disruptions, and improve 
performance in an uncertain and changing business 
environment (Munir et al., 2020). Furthermore the 
company is facing a higher risk in terms of supply 
disruptions, production, delivery delays, etc. which 
in turn results in lost reputation, lost sales, and bad 
financial performance (Sreedevi & Saranga, 2017). 
An understanding of how to comprehensively mitigate 
and respond to supply chain risk reveals additional 
research challenges in supply chain management 
(Kilubi, 2016). In order to remain competitive in 
supply chain ecosystem, one way is to pay attention 
to supply chain management. The supply chain 
ecosystem is the network environment in which the 
system operate (Macdonald et al., 2018).

Supply chain management includes all 
movement and storage of raw materials, work in 
process inventory, and finished goods from point of 
origin to point of consumption (Mavi et al., 2016). The 
supply chain is to add value to the product by moving 
it from one location to another, or by carrying out a 
process of changing it (Setiadi, Nurmalina, & Suharno, 
2018). Regarding the risks in supply chain, supply 
chain risk management includes a wide variety of 
strategies aimed at identifying, assessing, mitigating, 
and monitoring unforeseen events that may have an 
impact, mostly adversely, on any part of the supply 
chain (Baryannis et al., 2019).

At a strategic level when dealing with Supply 
Chain Management, it can guide the company 



124 The Winners, Vol. 22 No. 2 September 2021, 123-136

in redesigning its corporate culture, processes, 
organizational structure among others and recognizing 
the general impact of supply chain management 
on business performance (Min, Zacharia, & Smith, 
2019). Related to supply chain management, currently 
companies are increasingly responsible for the 
environmental, social and economic outcomes caused 
by their internal operations and by the operations of 
their suppliers (Koberg & Longoni, 2019).

In the supply chain, there are various risks that 
may occur. Based on Australian New Zealand Standard 
in (Anggrahini, Karningsih, & Sulistiyono, 2015) risk 
is an unexpected effect of a certain goal. Risk itself 
is often defined as a function of the probability and 
consequences of an uncertain outcome (Boonyanusith 
& Jittamai, 2019). Many companies increase their 
exposure to risk by having partners in business critical 
position in their supply chain (Finch, 2004). According 
to Elvandra, Maarif, & Sukardi (2018) supply chain 
risk is all risks from the flow of information, materials, 
and products or disruption caused by the complexity 
of the company's relationship with external parties. 
Supply chain risk management is done through 
coordination or collaboration among supply chain 
partners to ensure profitability and continuity (Tang, 
2006), while attempts to assess risk accurately across 
organizational boundaries are hindered by the absence 
of a consistent set of risk metrics (Shi, 2004).

PT XYZ is a company engaged in the palm 
oil industry and has eleven subsidiaries spread 
across five provinces in Indonesia, namely North 
Kalimantan, West Kalimantan, East Kalimantan, 
Central Kalimantan, and South Sumatra. PT XYZ 
was found in 2016. For approximately 3 years since 
its establishment, it is known that PT XYZ has never 
evaluated its supply chain process. In carrying out its 
supply chain activities, this company often experiences 
problems from the procurement, production, to 

delivery processes. In the research, supply chain 
analysis was focused on PT A, a subsidiary of PT XYZ 
which is located in the province of Central Kalimantan 
as presented in Table 1.

A supplier is a company or individual capable 
of providing resources, either in the form of goods 
or services needed by other companies (Viarani & 
Zadry, 2015). Currently, PT A has local and foreign 
suppliers. Suppliers who work with the company 
are suppliers for raw materials or materials used 
in plantation and factory operations. PT A is also 
working with local palm oil companies to supply 
fresh fruit bunches (FFB) to increase crude palm oil 
(CPO) and palm kernel (PK) production to match the 
supply demands of other companies. This business 
model can also be called B2B (Business to Business), 
a term used for commercial transactions between 
business people. Delivery is the process of distributing 
finished goods and services to meet consumer needs. 
This process includes order management, warehouse 
management such as product packaging according 
to company procedures, transportation management 
such as making deliveries with the right and on time 
transportation to meet planned needs (Putradi, 2017). 
For CPO produced by PT A, the company uses a 
third party service as a barge provider to load and 
deliver CPO to consumers in Batam, Riau Islands. 
Meanwhile, for PK produced by PT A, the company 
uses its own truck units to be sent to consumers in the 
South Kalimantan area.

For now, PT A has collaborated with several 
suppliers, including fertilizer suppliers, chemical 
suppliers (pest exterminators), and FFB suppliers. The 
problem that often occurs related to supplier operations 
to PT A is the problem of late delivery of the ordered 
materials as presented in Table 2.

Table 3 shows that the data on fruit production 
and outside fruit acceptance (suppliers) in 2017 and 

Table 1 Comparison of PT XYZ Group Subsidiary Data

PT XYZ Group
PT Estate Mill Afdeling Area (Ha) Number of Employees

PT A 4 2 28 17.469 3.397
PT B 4 2 22 12.166 2.848
PT C 2 0 8 7.640 972
PT D 2 1 11 5.999 881
PT E 1 1 8 5.929 844
PT F 1 1 8 5.925 803
PT G 1 0 9 4.713 619
PT H 1 1 6 4.217 573
PT I 2 1 6 4.009 489
PT J 1 0 6 3.648 422
PT K 1 1 5 3.559 407

Sumber : PT XYZ (2019)



125Risk and Supply Chain Mitigation.... (Shelvy Kurniawan, et al.)

2018 did not reach the capacity set by the company. In 
2017, the achievement of fruit capacity was 84,69%, 
which then decreased to 83,31% in 2018.

The fruit achievements described have an 
impact on PT A's annual CPO and Kernel production. 
In Table 4, it can be seen that the achievement of CPO 
oil production in 2017 was only 80,66% and Kernel 
80,53%. In 2018, the achievement of CPO production 
decreased to 78,60% and Kernel dropped to 78,29%. 
Apart from being caused by the large number of 
fruit being processed, the achievement of this oil 
production is also caused by several factors such as 
the level of fruit maturity, machine breakdowns, and 
human negligence in the process. These achievements 
have indirectly impacted the process of sending CPO 
to consumers in Batam, Riau Islands and Kernel areas 
to consumers in the South Kalimantan area. As seen 
in Table 5, for CPO shipments, there are 2 delays 
out of a total of 7 shipments in 2017 and 2 times a 
delay out of a total of 8 shipments in 2018. For Kernel 
shipments, there are 4 times the delay out of a total of 
35 shipments in 2017 and 6 times delays out of a total 
of 36 shipments in 2018. One of the reasons for this 
delay is the lack of CPO and Kernel produced by PT 
A in a certain period, so they have to wait a few days 
later to reach the quantity ordered by consumers. Other 
factors that can impact delivery delays include engine 
breakdowns at factories, vehicle unit breakdowns, 

negligence in the oil processing process, and weather 
for distribution.

The delay in delivery is one of the factors 
causing product damage that is sent to consumers 
of each product. Table 6 provides data on damaged 
products sent by PT A in the period January 2017 to 
December 2018. In accordance with company policy, 
products that have been damaged will not be taken 
back by the company, and payment regulations are 
only made for products that are in good condition.

Companies need to realize the importance of 
building a good supply chain network to prevent risks 
that can reduce company revenues. Therefore, steps 
that can be taken by PT A is to evaluate supply chain 
performance from the starting point of planning to 
consumers and assess whether the performance of the 
supply chain currently implemented is effective and 
efficient so that the company's competitiveness can be 
improved.

Anggrahini et al. (2015) examine problems in the 
supply chain of frozen shrimp products. The research 
uses the Supply Chain Operations Reference (SCOR) 
and House of Risk (HOR) methods. The results shows 
there are 41 risk events and 52 risk agents, 11 of which 
are categorized as priority risks and 12 mitigation 
actions are proposed to be implemented. Ratnasari, 
Hisjam, and Sutopo (2018) examine problems in the 
supply chain of printing companies. This study uses 

Table 2 Data on PT A Material Receipts for the Period Jan 2017 - Dec 2018

Type of Goods Total Receipts Number of Late Receipts Percentage of Late Receipts
Fertilizer 91 22 24,18%
Chemical 15 4 26,67%
Outer FFB 243 31 12,76%

Source: PT XYZ (2019)

Table 3 Data of Production and Receipt of PT A Fruit for 2017 - 2018

2017 2018
Actual (Ton) Target (Ton) Target Achievement Actual (Ton) Target (Ton) Target Achievement

Core Fruit 136.688,14 164.273 83,21% 145.936 179.188 81,44%
Outer Fruit 40.798,19 45.291 90,08% 45.332,23 50.388 89,97%
Total 177.486 209.564 84,69% 191.268 229.576 83,31%

Source: PT XYZ (2019)

Table 4 PT A's CPO and Kernel Production 2017 - 2018

CPO Production at PT A (Ton) Kernel Production at PT A (Ton)
Actual (Ton) Target (Ton) Target Achievement Actual (Ton) Target (Ton) Target Achievement

2017 39.721,44 49.247,54 80,66% 5.360,09 6.655,74 80,53%
2018 42.404,17 53.950,36 78,60% 6.139,71 7.842,00 78,29%

Source: PT XYZ (2019)



126 The Winners, Vol. 22 No. 2 September 2021, 123-136

the SCOR and HOR methods. The results contains 
24 risk events and 20 risk agents, two of which are 
categorized as priority risks and 9 mitigation actions 
are proposed to be implemented. The HOR model is 
based on the proactive assumption that supply chain 
risk management should try to focus on preventive 
measures, namely reducing the possibility of risk 
agents and models capable of determining which risk 
agents have the greatest potential to cause risk events 
(Hartono, Christiani, & Lasiman, 2018). Furthermore, 
according to Chotimah, Purwanggono, and Susanty 
(2017), the SCOR Model includes an assessment 
of delivery and demand fulfillment performance, 
inventory and asset management, production 
flexibility, warranties, process costs, and other factors 
that affect the overall performance assessment of a 
supply chain. According to APICS, the framework  
of SCOR model is divided into Plan, Source, Make, 
Deliver, Return, and Enable (Ben-Daya, Hassini, & 
Bahroun, 2017).

Ramadhani and Baihaqi (2018) analyze the 
correlation relationship by combining two methods, 
namely the Analytic Network Process (ANP) and 
House of Risk (HOR) methods. The end result of 
the two methods finds that there are 30 causes or 
sources of risk and 13 critical risks that have 28 risk 
management strategies with 15 priority strategies 
that can be implemented by the company. Ratnasari 
et al. (2018) map risks in printing companies and 
formulate risk mitigation alternatives to reduce risk. 
HOR method is chosen to select a series of proactive 
actions that are considered cost-effective in managing 
supply chain risk in newspaper companies. Laksmita 
and Widodo (2018) use House of Risk method to 
mitigate risks and successfully identify four priority 
risks, namely A8 (car problems), A4 (human error), 
A3 (error deposits through banks and underpayments), 
and A6 (past accidents cross) that must be reduced.

The initial stage carried out is mapping 
supply chain activities. The mapping of supply chain 
activities at PT A is obtained by conducting interviews 
with related parties in the company. The interview is 
held directly to the Operations and Budgeting Senior 
Manager of PT XYZ who is an expert in the field 
of operations at PT XYZ. Questionnaires are filled 
out by respondents at PT A who have the biggest 
role or responsibility related to the operations of 
PT A company, namely the General Manager of the 
Central Kalimantan Region. Next, PT A's supply chain 
activities are mapped in the SCOR model. SCOR is 
an approach method for measuring the performance of 
a supply chain developed by the SCC (Supply Chain 
Council), which was formed in 1996 (Putradi, 2017). 
SCOR method is used since this method can classify 
supply chain activities into five processes, namely Plan 
(planning process), Source (procurement process), 
Make (production process), Deliver (delivery process), 
and Return (return process) so that activity mapping 
can be made more structured. The SCOR model is 
very effective as a frame of reference for identifying 
supply chain performance metrics in five important 
activities in supply chain management (Kusmantini, 
Guritno, & Rustamaji, 2015).

The next stage is the data processing stage 
which includes risk analysis. In data processing, there 
are several methods such as Failure Mode and Effect 
Analysis (FMEA) and HOR. FMEA is a structured 
procedure to identify and prevent as many failure 
modes as possible. From the mapping of supply chain 
activities using the SCOR method, brainstorming is 
carried out to find out various forms of risk events that 
occur. FMEA has widely used techniques to identify and 
eliminate potential failures to improve system security 
and reliability (Ghadge et al., 2017). After that, the 
risk assessment is calculated through the calculation 
of the Risk Priority Number (RPN) obtained from 

Table 5 CPO and Kernel Delivery Data for the 2017 - 2018 Period

CPO Kernel
Delivery 

Frequency
Late Delivery 

Frequency
Percentage of 

Late Shipments
Delivery 

Frequency
Late Delivery 

Frequency
Percentage of 

Late Shipments
2017 7 2 28,57% 35 4 11,43%
2018 8 2 25,00% 36 6 16,67%

Source: PT XYZ (2019)

Table 6 Data on Products Received by Consumers in 2017 - 2018

Tahun

CPO Kernel
Quantity 
Delivered 

(Ton)

Quantity 
Rejected 

(Ton)

Quantity 
Accepted 

(%)

Quantity 
Delivered 

(Ton)

Quantity 
Rejected 

(Ton)

Quantity 
Accepted 

(%)
2017 38.300 2.849 92,56% 5.292 244 95,39%
2018 43.700 4.107 90,60% 6.070 371 93,89%

Source: PT XYZ (2019)



127Risk and Supply Chain Mitigation.... (Shelvy Kurniawan, et al.)

multiplying three factors, namely the level of damage 
produced (Severity), the probability of risk occurrence 
(Occurrence), and the level of possibility of detection 
(Detection) for each risk event and prioritizing risky 
events that require further treatment (Hapsari, 2018). 
Meanwhile, the HOR method according to Pujawan 
and Geraldin in Putri (2017) is a modification of the 
House of Quality (HOQ) and Failure Mode and Effects 
Analysis (FMEA) methods to compile a framework 
for managing supply chain risk.

In HOR method, a risk agent that has a high 
Aggregate Risk Potential (ARP) is selected, which 
means that the risk agent has a high probability of events 
and causes many risk events with severe impacts. Then, 
mitigation actions are prepared for selected risk agents 
based on the ratio of total effectiveness for the level of 
difficulty and mitigation actions that can reduce many 
risk agents with high ARP values (Cahyani, Pribadi, 
& Baihaqi, 2016). Brainstorming with the company 
is carried out to examine risky events that occur. In 
contrast to the FMEA method, the HOR 1 method 
calculates ARP which is obtained from three factors, 
namely the level of risk source probability, the impact 
of damage to risk events, and the level of relationship 
between risk events and risk sources. One risk agent 
can induce multiple risk events, and vice versa, thus 
the HOR 1 method is chosen since it is considered 
more effective than the FMEA method by considering 
the level of the relationship between risk events and 
risk agents.

After the risk analysis stage, the next stage is 
the risk management stage by looking for mitigation 
action priorities. In this stage, there are several methods 
such as HOR 2, Analytical Hierarchy Process (AHP), 
and Analytical Network Process (ANP). The HOR 2 
method is used for taking effective action to reduce the 
probability of a risk agent (Putri, 2017). In the HOR 
2 method, the calculation of the ratio of effectiveness 
to level of difficulty is based on three factors, namely 
the level of effectiveness of mitigation actions, the 
level of difficulty to be implemented, and the level 
of relationship between risk agents and mitigation 
actions using AHP. Thomas L. Saaty engineered a 
major breakthrough in the 1970s by formulating the 
AHP (Baffoe, 2019; Chan, Sun, & Chung, 2019). It is a 
method for making a sequence of alternative decisions 
and selecting the best alternative. The AHP method 
solves complex problem structures by dividing the 
parts into a hierarchy. Processing is carried out with 
a pairwise comparison matrix (Sasongko, Astuti, 
& Maharani, 2017). Another method that can be 
implemented at this stage is ANP method, which is the 
development of AHP for dependence feedback cases 
and generalizes to the supermatrix approach. It also 
allows interaction and feedback within clusters (inner 
dependence) and between clusters (outer dependence) 
for decision making (Adams & Saaty, 2016). ANP 
is a generalization of the AHP, by considering the 
dependence between elements of the hierarchy. Many 
decision problems cannot be structured hierarchically 
since they involve the interaction and dependence of 

higher level elements in the hierarchy at lower level 
elements (Kusnadi, Surarso, & Syafei, 2016). Similar 
with AHP method, the ANP method also performs 
processing with a pairwise comparison matrix between 
criteria and alternatives. The ANP method is able to 
improve AHP's weaknesses in the form of the ability to 
accommodate linkages between criteria or alternatives 
(Pungkasanti & Handayani, 2017). The ANP method 
is also superior when compared to the HOR 2 method 
since the ANP method can adjust the number of 
assessment criteria for alternatives according to the 
research needs. Thus, the ANP method is chosen for 
the research as it provides a clearer and more detailed 
description of the implementation compared to the 
HOR 2 and AHP methods.

Analyzing supply chain performance using the 
HOR and ANP methods is needed to be able to provide 
solutions that can improve supply chain performance. 
The objectives of research are: 1) to identify risk 
events that have the potential to disrupt supply chain 
activities, 2) to determine the causes of risk (Risk 
Agent) that most influence the supply chain process 
by calculating the value of ARP, and 3) to determine 
the best strategy of mitigation (preventive action) 
carried out by PT XYZ, especially in the supply chain, 
to minimize risk by using the ANP method.

II. METHODS

The research applies mixed methods which aim 
to answer research questions that cannot be answered 
with qualitative or quantitative methods alone. Mixed 
methods research focuses on collecting, analyzing, and 
combining both quantitative and qualitative data in a 
single study or a series of studies (Sekaran & Bougie, 
2016). This type of research is a descriptive research. 
Descriptive research is research whose aim is to obtain 
data that describes events to make systematic, factual 
descriptions or descriptions of facts and relationships 
between the phenomena being investigated to produce 
recommendations for future needs (Sekaran & Bougie, 
2016).

The research is conducted by means of interviews 
and also distributing questionnaires to sources who best 
understand the company's supply chain. Interviews 
are conducted to determine the supply chain process 
series and also to analyze the risks that may occur in 
the supply chain process using the SCOR method. 
Results of the interviews shows that there are 36 risk 
events and 35 risk agents in the entire supply chain 
process. The questionnaire is distributed to one person 
who is considered to have the most responsibility 
for the operations of PT A. The first questionnaire is 
conducted to see how the severity of risk events and 
risk agent incidence rates and the level of relationship 
between risk events and risk agents. The results of 
the first questionnaire are processed using the HOR 
phase 1 method to find the impact resulting from each 
risk based on the ARP value. After the ARP value is 
obtained, the process continues to rank the risks from 



128 The Winners, Vol. 22 No. 2 September 2021, 123-136

the highest to the lowest ARP and divide these risks 
into 2 categories, which are priority and non-priority. 
Of the 35 risk agents, 19 are categorized as priority 
risk and 16 of them are categorized as non-priority 
risk. Next step is to design or propose mitigation 
actions against the 19 priority risks. Based on the 
results of the discussion, 11 mitigation actions and 3 
assessment criteria are obtained, namely the level of 
difficulty, effectiveness, and cost, which are compiled 
into a second questionnaire. The second questionnaire 
is conducted to see how the proposed criteria and 
alternatives are related. The results of the second 
questionnaire are processed using the ANP method 
and the help of the Super Decision Software v 2.10 
application to see the priority order of the proposed 
mitigation actions.

The research is expected to become a 
consideration or evaluation for the company to 
implement the research results in the form of a priority 
order of the proposed mitigation actions and apply the 
methods in the research in the future.

 

III. RESULTS AND DISCUSSIONS

From the results of interviews and activity 
mapping using the SCOR method, there are 36 risk 
events and 35 risk agents. Risk events are those that 

can disrupt supply chain activities at a company. Risk 
events are obtained from interviews with PT XYZ 
which are then coded using the letter E to facilitate 
further reading. Company risk events can be seen in 
Table 7.

Risk agents are things that can cause a risk event 
to occur so that it can disrupt supply chain activities 
at the company. The risk agent is obtained from the 
results of the interview which are then coded using the 
letter A which aims to facilitate further reading. The 
company's risk agent can be seen in Table 8.

These risks are processed into a questionnaire 
to determine the severity of risk events, risk agent 
incidence rates, and the relationship between risk 
events and risk agents. The results of the questionnaire 
are then processed using the HOR phase 1 method, 
and the risk order is obtained based on the highest to 
lowest ARP value as presented in Table 9.

Table 9 shows the order of risks based on the 
ARP value. These risks are categorized into two 
categories, namely priority and non-priority with the 
application of the Pareto theory. Risk agents that have 
an influence of 80% are categorized as priority risks 
and the result is 19 risks, while the rest are categorized 
as non-priority risks. Of the 19 prioritized risk agents, 
11 mitigation actions are proposed to reduce the level 
of risk events in Table 10.

Table 7 Risk Events at PT XYZ

Activity Sub-Activity Risk Event Code
Plan Demand Forecasting Improper forecasting of the number of requests E1

Material Planning Gap between recorded and available stock E2
Production Planning Sudden change in production plans E3
Shipping Planning Product delivery plan error E4
Adjustment of Human Resources to Supply Chain 
Requirements

Incompatibility of existing resources with supply 
chain needs

E5

Source Supplier Selection Improper supply ability E6
The price offered exceeds the company budget E7

Scheduling Product Delivery from Suppliers Late delivery of products from suppliers E8
Products damaged in transit E9
Sudden need for goods E10

Product Acceptance Uneven maturity of FFB E11
The number of products received did not match 
the agreement

E12

Lack of transport manpower on the day 
concerned

E13

Quality Checks The quality of the product received is not up to 
standard

E14

There is damage to the product packaging E15
Product Storage Product damage while in warehouse E16

Inadequate warehouse capacity E17
Product Payment There is a price change from the agreed price E18

The company's inability to pay for the product E19
Make Production Scheduling Mistakes in making a production plan E20



129Risk and Supply Chain Mitigation.... (Shelvy Kurniawan, et al.)

Activity Sub-Activity Risk Event Code
Production Process Insufficient amount of raw material E21

The quality of the fruit produced is not up to 
standard

E22

Unfulfilled fruit production targets E23
Damage to factory machines E24
Unfulfilled oil production targets E25

Product Quality Check The quality of the oil does not match the existing 
standards

E26

Product Storage Oil quality deteriorates in storage E27
There is a leak in the oil storage area E28

Deliver Unit Preparation Less / unavailable transportation E29
Product Delivery Late delivery of products E30

Unit accident during delivery E31
Product Acceptance The number of products sent did not match the 

agreement
E32

The quality of the products shipped has 
decreased

E33

Product Payment Late payment from consumers E34
The nominal paid does not match E35

Return Return of Defective Products to Suppliers Late arrival of product replacement from 
suppliers

E36

Source: PT XYZ (2019)

Table 8 Risk Agent in PT XYZ

Risk Agent Code
Forecasting that does not pay attention to external factors A1
Seasonal factor A2
Information and communication errors A3
Error in supplier selection A4
There was damage to the transportation unit / machine A5
Bad weather A6
The transport truck has an accident on the way A7
There is a sudden demand from consumers A8
The occurrence of damage to goods in the warehouse A9
Workers only pursue daily targets regardless of the level of fruit maturity A10
Error in harvesting fruit A11
Lack of attention to essential oil palm care A12
Lack of supervisor's supervision of workers A13
Shipments of unsealed products A14
Worker's negligence when loading goods A15
Lack of coordination A16
Workers do not pay attention to the applicable SOP A17
Worker's inaccuracy in quality checking A18
Error in product packaging process A19
Error in storage of raw materials A20
Warehouse conditions that are not considered A21
The arrival of products from suppliers outside of schedule A22
Price fluctuation A23
Payment policy changes A24

Table 7 Risk Events at PT XYZ (Continued)



130 The Winners, Vol. 22 No. 2 September 2021, 123-136

Risk Agent Code
Lack of monitoring of worker attendance levels A25
Fruit that is damaged by being in the open for a long time A26
Improper and irregular machine maintenance A27
Use of machines that exceed capacity A28
Unattended oil storage area A29
Drivers who do not have a driver's license A30
Rare truck maintenance A31
Truck loads that exceed capacity A32
There is fraud committed by workers A33
There is no driver standby when needed A34
Human error A35

Source: PT XYZ (2019)

Table 9 Order of Risk Based on ARP Value

Risk Agent ARP Rank Percentage Cumulative Category
A3 3.591 1 6,10% 6,10% Priority
A5 3.360 2 5,71% 11,81%
A7 3.186 3 5,41% 17,22%
A35 3.143 4 5,34% 22,56%
A10 2.968 5 5,04% 27,60%
A28 2.872 6 4,88% 32,48%
A17 2.695 7 4,58% 37,06%
A16 2.583 8 4,39% 41,45%
A27 2.513 9 4,27% 45,72%
A13 2.457 10 4,17% 49,89%
A18 2.304 11 3,91% 53,81%
A29 2.100 12 3,57% 57,37%
A6 2.085 13 3,54% 60,92%
A11 2.009 14 3,41% 64,33%
A12 2.009 15 3,41% 67,74%
A31 2.009 16 3,41% 71,16%
A32 2.008 17 3,41% 74,57%
A21 1.482 18 2,52% 77,08%
A20 1.434 19 2,44% 79,52%
A9 1.398 20 2,38% 81,90% Non-Priority
A23 1.206 21 2,05% 83,94%
A34 1.134 22 1,93% 85,87%
A30 1.071 23 1,82% 87,69%
A26 1.050 24 1,78% 89,47%
A25 882 25 1,50% 90,97%
A8 788 26 1,34% 92,31%
A2 770 27 1,31% 93,62%
A33 768 28 1,30% 94,92%
A15 555 29 0,94% 95,87%
A22 540 30 0,92% 96,78%

Table 8 Risk Agent in PT XYZ (Continued)



131Risk and Supply Chain Mitigation.... (Shelvy Kurniawan, et al.)

The 11 mitigation actions proposed are 
processed into a questionnaire to find the priority order 
of mitigation actions based on three criteria, namely 
difficulty level, effectiveness, and cost. Based on the 
network model formed and the results of questionnaire 
filled out by the respondents, three pair comparisons 
are obtained: 1) the pairwise comparison of the criteria 
w.r.t. objective, 2) alternative pairwise comparison 
w.r.t. criteria and 3) pairwise comparison criteria w.r.t. 
alternative.

In Table 11, it can be seen that the most 
influential criterion in determining the best mitigation 
action at PT A is the effectiveness criteria with a 
weight of 0,57690. It is followed by the criteria for 
the level of difficulty in the second priority with a 
weight of 0,34200 and the cost criteria for the last 
priority with a weight of 0,08110. Therefore, it can be 
interpreted that companies prioritize the effectiveness 
of a proposed mitigation action to see how big 
is the impact given if the company implements a 
mitigation action. After effectiveness, the company 
will see the level of difficulty of a mitigation action. 
With the company that has only been established for 
approximately three years, the company will see its 
capacity in implementing mitigation action. The cost 
criterion is the least influential criterion for selecting 
a mitigation action since the criteria for effectiveness 

Risk Agent ARP Rank Percentage Cumulative Category
A14 480 31 0,82% 97,60%
A1 456 32 0,77% 98,37%
A24 432 33 0,73% 99,11%
A19 351 34 0,60% 99,70%
A4 174 35 0,30% 100,00%

Total 58.863

Source: The Researchers (2019)

Table 10 Proposed Mitigation Actions

No. Mitigation Action Code
1 Conduct a briefing in the morning before starting work and an evaluation in the afternoon after work hours PA 1
2 Perform regular periodic checks on the transportation/machine unit PA 2
3 Ensure all unit operators have a SIM according to each unit PA 3
4 Provide incentives to workers who clean warehouse & oil storage areas PA 4
5 Provide counseling regarding company SOPs to all employees including new employees PA 5
6 Provide written sanctions/fines for losses that have been done PA 6
7 Make a place/partition for each material along with a bincard PA 7
8 Create a staff level daily field inspection template for monitoring inspection levels PA 8
9 Create a template for daily activity reports for all employees submitted to their respective superiors PA 9
10 Improve the condition of the main garden road PA 10
11 Expand the current warehouse/build a new warehouse PA 11

Source: The Researchers (2019)

Table 9 Order of Risk Based on ARP Value (Continued)

and the level of difficulty in implementing mitigation 
action are considered more important than the cost of 
implementing it. 

Table 12 shows the weight of each alternative 
against each criterion. For example, PA 10 has the 
highest weight with a value of 0,31023 among 
other alternatives on the cost criteria. Thus it can be 
interpreted that PA 10 requires the greatest cost among 
other alternatives. From the effectiveness criteria, PA 
11 has the highest weight with a value of 0,28625, 
which can be interpreted that PA 11 has the greatest 
effectiveness among other alternatives. From the 
difficulty level criteria, PA 10 has the highest weight 
with a value of 0,31832, which can be interpreted 
that PA 10 has the highest difficulty level to be 
implemented.

Table 13 shows the weight of each criterion 
against each alternative. For example, in PA 1, the 
weight of effectiveness is 0,69231, the weight of 
the difficulty level is 0,23077, the weight of the 
cost is 0,07692. Thus it can be interpreted that the 
effectiveness criterion has the greatest weight because 
implementing PA 1 can reduce the error rate that may 
occur in the supply chain process. It is considered not 
too difficult to implement, and the required costs are 
little or no cost at all.

Table 12 shows the weight of each alternative 



132 The Winners, Vol. 22 No. 2 September 2021, 123-136

against each criterion. For example, PA 10 has the 
highest weight with a value of 0,31023 among 
other alternatives on the cost criteria. Thus it can be 
interpreted that PA 10 requires the greatest cost among 
other alternatives. From the effectiveness criteria, PA 
11 has the highest weight with a value of 0,28625, 
which can be interpreted that PA 11 has the greatest 
effectiveness among other alternatives. From the 
difficulty level criteria, PA 10 has the highest weight 
with a value of 0,31832, which can be interpreted 
that PA 10 has the highest difficulty level to be 
implemented.

Table 13 shows the weight of each criterion 
against each alternative. For example, in PA 1, the 

weight of effectiveness is 0,69231, the weight of 
the difficulty level is 0,23077, the weight of the 
cost is 0,07692. Thus it can be interpreted that the 
effectiveness criterion has the greatest weight because 
implementing PA 1 can reduce the error rate that may 
occur in the supply chain process. It is considered not 
too difficult to implement, and the required costs are 
little or no cost at all.

From the priority criteria to the objectives and 
the comparison between the criteria and alternatives, a 
synthesis stage is carried out to see the priority order 
of mitigation actions that the company should take. 
The synthesis results can be seen in Table 14.

Table 11 Pairwise Comparison of Criteria

Criteria Weight Rank
Effectiveness 0,57690 1
Degree of difficulty 0,34200 2
Cost 0,08110 3

Table 12 Alternative Pairwise Comparison

Criteria Alternative Weight Inconsistency
Cost PA 1 0,01637 0,09787

PA 2 0,13838
PA 3 0,02384
PA 4 0,06747
PA 5 0,02063
PA 6 0,01496
PA 7 0,12632
PA 8 0,02591
PA 9 0,02380
PA 10 0,31023
PA 11 0,23209

Effectiveness PA 1 0,09126 0,09980
PA 2 0,04356
PA 3 0,0570
PA 4 0,02136
PA 5 0,03214
PA 6 0,18722
PA 7 0,02546
PA 8 0,01429
PA 9 0,01945
PA 10 0,22199
PA 11 0,28625

Degree of difficulty PA 1 0,03453 0,08618
PA 2 0,15715
PA 3 0,01273
PA 4 0,02142
PA 5 0,02622



133Risk and Supply Chain Mitigation.... (Shelvy Kurniawan, et al.)

Criteria Alternative Weight Inconsistency
PA 6 0,01544
PA 7 0,13609
PA 8 0,04116
PA 9 0,02204
PA 10 0,31832
PA 11 0,21489

Source: The Researchers (2019)

Tabel 13 Alternative Pairwise Comparison

Alternative Criteria Weight Inconsistency
PA 1 Cost 0,07692 0,00000

Effectiveness 0,69231
Degree of difficulty 0,23077

PA 2 Cost 0,63699 0,03703
Effectiveness 0,25828
Degree of difficulty 0,10473

PA 3 Cost 0,10203 0,02795
Effectiveness 0,72585
Degree of difficulty 0,17212

PA 4 Cost 0,69552 0,07348
Effectiveness 0,22905
Degree of difficulty 0,07543

PA 5 Cost 0,09534 0,01759
Effectiveness 0,65481
Degree of difficulty 0,24986

PA 6 Cost 0,08967 0,01759
Effectiveness 0,70503
Degree of difficulty 0,2053

PA 7 Cost 0,69096 0,05156
Effectiveness 0,21764
Degree of difficulty 0,09140

PA 8 Cost 0,07543 0,07348
Effectiveness 0,69552
Degree of difficulty 0,22905

PA 9 Cost 0,07543 0,07348
Effectiveness 0,69552
Degree of difficulty 0,22905

PA 10 Cost 0,75825 0,03112
Effectiveness 0,15125
Degree of difficulty 0,09051

PA 11 Cost 0,72585 0,02795
Effectiveness 0,17212
Degree of difficulty 0,10203

Source: The Researchers (2019)

Table 12 Alternative Pairwise Comparison (Continued)



134 The Winners, Vol. 22 No. 2 September 2021, 123-136

IV. CONCLUSIONS

The research results show that there are thirty-
six risk events in PT A's supply chain for the period 
January 2017 - December 2018. Three risk events 
include a unit accident during delivery, insufficient 
warehouse capacity, and damage to factory machinery. 
The risk events analyzed in PT A are caused by the 
risk agent or risk cause. 35 risk agents in the supply 
chain of PT A were obtained in the period of January 
2017 - December 2018, 19 of which were categorized 
as priority risks. The three priority risks include 
misinformation and communication, damage to the 
transportation unit/engine, and the truck accident 
on the way. To reduce the occurrence of risk events, 
companies need to reduce the incidence rate of risk 
agents. As many as 11 mitigation actions for the 19 
priority risks are proposed. Three mitigation actions 
include improving the condition of the main garden 
road, expanding the current warehouse/building a new 
warehouse, and conducting routine checks on certain 
periods of the transportation/machinery unit.

By looking at the many risks that could 
potentially arise in the supply chain process of PT A, 
the researchers suggest that the company is able to 
implement mitigation actions according to priority in 
accordance with the research results, for example, by 
improving the condition of the main garden road. By 
implementing these mitigation actions, the company 
incurs significant costs initially, but is expected to 
reduce indirect costs in the long run, such as unit 
repair costs due to accidents that occur continuously. 
For supply chain risk analysis and other fields, it is 
recommended that companies are able to apply: 
1) the SCOR method to help map activities, 2) the 
HOR method to analyze risk since it considers the 
relationship between risk events and risk agents, and 
3) the ANP method to seek mitigation action priorities 
since ANP can accommodate the linkages between 
criteria and alternatives. 

The research has limitations since it investigates 

Tabel 14 Mitigation Action Priority Sequence

Mitigation Action Code Rank
Improve the condition of the main garden road PA 10 1
Expand the current warehouse/build a new warehouse PA 11 2
Perform regular periodic checks on the transportation / machine unit PA 2 3
Make a place/partition for each material along with a bincard PA 7 4
Provide written sanctions/fines for losses that have been done PA 6 5
Provide incentives to workers who clean warehouse & oil storage areas PA 4 6
Conduct a briefing in the morning before starting work and an evaluation in the afternoon after work 
hour

PA 1 7

Ensure that all Unit Operators have a SIM in accordance with each unit PA 3 8
Provide counseling regarding company SOPs to all employees including new employees PA 5 9
Create a staff level daily field inspection template for monitoring inspection levels PA 8 10
Create a template for daily activity reports for all employees submitted to their respective superiors PA 9 11

Source: The Researchers (2019)

only in one palm oil company in Indonesia. Future 
research is suggested to examine several oil palm 
companies to compare the results of their research 
whether it can be generalized. In addition, it is 
suggested that there is future research on other 
industries outside of plantations.

 

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