ISSN: 2407-814X (p); 2527-9238 (e) 

AGRARIS: Journal of Agribusiness 
and Rural Development Research 

Vol. 7 No. 2 July – December 2021, 
Pages: 241-255 

Article history: 
Submitted : November 2nd, 2020 
Revised : November 3rd, 2021 
   September 21st, 2021 
Accepted : November 8th, 2021 

Agustina Shinta Hartati Wahyuningtyas, Novi Haryati*, Destyana 
Ellingga Pratiwi, and Luisa Maliny Situmeang 
Department of Agricultural Socio-Economics, Faculty of Agriculture, 
Universitas Brawijaya, Jl. Veteran Kota Malang 65145, Indonesia  

 

*) Correspondence email: noviharyati@ub.ac.id  
  

Risk Mitigation Strategies in Semi-Organic Rice Supply Chains: 
Lesson Learned from the Involved Actors  

DOI: https://doi.org/10.18196/agraris.v7i2.10126  

ABSTRACT 

Rice is the main consumption food for Indonesians. The demand for food 
increased from 114.6 kg per capita in 2016 to 124.89 kg in 2017. However, rice 
farmers and supply chain actors in rice agribusiness have experienced high 
challenges, such as production, transportation, price, product quality, and the 
environment. This research aimed to understand actors involved in the supply 
chain, their perception of occurring risks, and evaluation and risk mitigation in 
the supply chain. This was a quantitative descriptive study done purposively in 
Watugede Village, Singosari Sub-District, Malang Regency. Non-probability 
sampling was taken to gather primary data. The respondent of this research was 
16 involved actors, from on-farm actors to consumers. The data were analyzed 
using the Fuzzy analytical hierarchy process (FAHP) to provide descriptive risk 
mitigation strategies. The results show that six involved actors are suppliers, 
farmers, grinders, traders, and buyers. Each actor faces different risks, and thus, 
the recommended mitigation strategies are adjusted to their risks. Sharing 
information, optimizing the level of supply availability, measuring supply chain 
performance, and building more coordination with the government are the best 
strategies to mitigate risks. 

Keywords: Mitigation, rice, risk, supply chains 

INTRODUCTION 

Gross domestic product (GDP) from the agricultural sector in Indonesia increased to 
73.3% in the first quarter of 2019 from IDR 46,173.20 billion in the fourth quarter of 2018; 
the increase reaches an average of IDR 68,735.56 billion from 2010 to 2019 (Food and 
Agriculture Organization [FAO], 2021). Therefore, certain agricultural products with high self-
sufficiency received special attention in the blueprint of the ASEAN Economic Community 
(AEC). In particular, this condition applies to rice which by far is one of the four strategic 
commodities. Typical risks occur in every supply chain management, including interruptions 
and delays caused by suppliers, such as supply capacity (Bollapragada et al., 2004; Cachon & 
Lariviere, 1999; Ellram, 1990; Feng, 2010; Kahraman et al., 2003; Wu et al., 2008), product design 
changes (Novak & Eppinger, 2001) and delivery delays (Feng, 2010). 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&
mailto:noviharyati@ub.ac.id
https://doi.org/10.18196/agraris.v7i2.10126
https://www.investopedia.com/terms/g/gdp.asp


 

ISSN: 2407-814X (p); 2527-9238 (e) 

242 AGRARIS: Journal of Agribusiness and Rural Development Research 
Meanwhile, other risks are due to exchange rates, inventory, and out of stock 

(Halldórsson et al., 2009), logistics, and transportation risks (Santis et al., 2017). The demand 
risks include demand volatility and forecasting inaccuracies, information distortion, and stock 

accumulation due to bullwhip effects (Kahraman et al., 2003).  
Other researchers divide the risks into environmental, social, and financial risks. 

Environmental risk is a consequence of natural ecosystems, corporate reputation, financial 
compliance, and legal compliance (Cachon & Lariviere, 1999). Meanwhile, social risk refers 
to sending responsibility to employees, consumers, business partners, the government, and 
society. Other examples of social risks include business scandals that employ underage 
workers, unethical treatment of animals, illegal environmental practices, pricing, allegations 

of bribery, fraud, and patent infringement (Hammoudi et al., 2009). The financial dimension 
separates financial risks performed by financial environment, corporate, and individual 
behavior and strives for continuous economic growth (Blome & Schoenherr, 2011). 

Sustainability is generally related to risks encountered by industries, such as greenhouse 
gas emissions, natural disasters, accidents, energy consumption, waste, and environmental 
damage during shipping and transportation. The sustainability risks include resistance to 
boycotting a company's products, litigation against companies to cover financial losses caused 
by environmental accidents, non-compliance with regulations, or unethical behavior, risks of 
social justice from unfair workers and work practices, and increasing commodity and energy 
prices as fuel shortages (Spekman & Davis, 2004).  

Economic risks are related to uncertainty in a country’s economic conditions, interest 
rates, business trends like increasing outsourcing or offsourcing and information technology 
used to develop sustainable supply chains (Zhou & Benton, 2007). The impact of these risks 
is the increasing costs, and thus, a strategy for resource allocation and capacity development 
to manage risks is necessary (Tang & Nurmaya Musa, 2011). One technique to manage risk is 
to provide incentives in the supply chain, and thus suppliers can work together following the 
contract and provide reliable guarantees (Matzembacher & Meira, 2019). After analyzing the 
risks of the supply chain, this study was expected to find a strategy to prevent or eliminate 
risks for the rice supply chain. Rice farmers in Watugede Village Singosari have experienced 
high challenges in their supply chains since they produce semi-organic rice with different 
marketing processes. Besides, other challenges are production, transportation, price, product 
quality, and the environment. Therefore, this research was conducted to understand 1) actors 
involved in the supply chain, 2) their perception of occurring risks, and 3) evaluation and risk 
mitigation in the supply chain. This research is expected to provide theoretical contributions 
for the actor mapping and supply chain risk mitigation, as well as practical contributions for 
advice and inputs for supply chain actors. 

RESEARCH METHOD 

This research employed a quantitative descriptive approach Queirós, Faria, & Almeida, 
(2017) because this research involved data in numbers. The data were obtained from 
interviews conducted in each supply chain. The descriptive method was also used to describe 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

243 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 
each actor in a semi-organic rice supply chain. This method identified sources of risks 
perceived by each actor in the semi-organic rice supply chain. Identifying risks perceived by 
each supply chain actor can be seen from the respondents’ answers on the questionnaire using 
the Likert scales. The scales were 1-5 with the following descriptions: 1 = very unimportant, 2 
= not important, 3 = doubtful, 4 = important, and 5 = very important. 

Furthermore, this study employed the judgment sampling technique to answer the 

objective of supply chain risk. This technique considers the determined characteristics of 
target populations and is adapted to the research purposes or problems Queirós, Faria, & 
Almeida, (2017). This research employed the primary data collected with the structured 
questionnaires based on the research purposes. The research site was Watugede village, 
Singosari Sub-district, Malang Regency, Indonesia. The data were analyzed using the fuzzy 
AHP. The research respondents are the actors of each supply chain. They were one supplier, 
three farmers, three loggers, three grinders, three traders, and three consumers. The research 
framework was summarized in Figure 1.   

 

FIGURE 1. THE RESEARCH FRAMEWORK OF SEMI-ORGANIC RICE SUPPLY CHAINS MITIGATION 

Supply 
Risks 

Price Risks 
Production  

Risks 
Quality Risks 

Environment 
Risks 

Transportation 
Risks 

Semi-Organic Rice Supply Chains 

Identification source of risks 

Supplier Farmer Logger Grinder Trader Buyer 

Perception in Every Chain Fuzzy-Analytic Hierarchy Process (F-AHP) 

Evaluation of Risks 
(Determining the Priority Risk) 

Risk Mitigation 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

244 AGRARIS: Journal of Agribusiness and Rural Development Research 
Fuzzy AHP (analytical hierarchy process) is the best method to determine the weight of 

each risk factor (Feng, 2010). Meanwhile, the risk factors were selected using the highest 
weight with expert judgment inputs. In general, this study developed the fuzzy AHP method 
through eight stages.  
1. The first stage was identifying risk problems. The criteria of risk selection were supply, 

transportation, price, quality, and environment. 
2. The second stage was creating a hierarchical structure to represent a complex problem in 

the risk selection. The sub-criteria of risk selection were diversity of supply, uncertain 
supply, damaged infrastructures, uncertain time, transportation, road insecurity, long haul 
distances, inflation, price fluctuations, information distortion, low quality, quality 
variations, government policy, political, social, and cultural conditions, and competitors’ 
products. 

3. The third stage was choosing alternative assessments and criteria. This stage is pivotal to 
determine the priority criteria from every tier of semi-organic rice, including suppliers, 
farmers, loggers, grinders, traders, and buyers. 

4. The fourth stage was fuzzy fiction from the results of assessing and performing 
defuzzification of the fuzzy score. This stage was done by making criteria and alternative 
matrices.  

5. The fifth stage was calculating the eigenvector values and testing their consistency. If the 
values are not consistent, the data collection should be repeated. The eigenvector values in 
questions refer to the maximum obtained eigenvector value.  

6. The sixth stage was calculating ratio consistency and final scores, determining the ranking 

of the final scores (Santis et al., 2017), and testing the hierarchy consistency. If the scores 
do not meet the CR <0.100, the assessment must be repeated. 

7. The seventh stage was evaluating the highest priority of the most important risks in the 
criteria and sub-criteria.  

The last stage was determining the risk mitigation strategies for each actor in the semi-
organic rice supply chain. The mitigation strategies were determined by conducting a 
discussion between the researchers and respondents, actors in the semi-organic rice supply 
chain. 

RESULT AND DISCUSSIONS 

Semi-Organic Rice Supply Chains 

The post-harvest rice supply chain in Singosari District involves several actors. The rice 
supply chain flow consists of the rice supply chain flow, such as supply chains for grain, rice 
bran, and husk. Each supply chain flow had product, financial, and information flows. 
However, this research limited its investigation to the post-harvest supply chains. Actors 
involved in the post-harvest supply chain were farmers, grain traders, mills, rice traders, 
retailers of markets, stalls, and shops, brick entrepreneurs, and breeders. These actors were 
mentioned in Figure 1. 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

245 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 

 
FIGURE 2. THE SEMI-ORGANIC RICE SUPPLY CHAIN 

In the post-harvest, the semi-organic rice experienced changes in values from grain to 
rice readily consumed, and in the flow of post-harvest yield received by the grinders (wet rice). 
Wet rice was the main raw material in the rice milling process to become rice. Wet grains were 
initially dried in the sun to reduce the water content until they are ready for the grinding 
process. Dry milled grain was included in the rice milling system. Farmer groups have provided 
milling facilities for their members, although they are not required to deposit to farmer 
groups. 

Evaluating the Highest Risk Priority for Each Supply Chain actors of Semi-Organic Rice  

Risks at the Supplier Level 

The result of weighting risk using the fuzzy AHP shows that the highest risk weighting 
at the supplier level was supply risk. The following high risks were quality risks, environmental 
risks, production risks, price risks, and transportation risks. The rating was considered valid 
because its CR value is 0.01 or <0.1. The risk of weighting results at the supplier level is 
presented in Figures 3 and 4. There were five criteria to examine the risks for actors of semi-
organic rice supply chains. They were the supply, transportation, price, quality, and 
environment. Figure 3 shows that the highest risk priority was the supply risk by 0.301. The 
successive risk priorities were the transportation risk by 0.078, the price risk by 0.280, the 
quality risk by 0.259, and the environmental risk by 0.081. The sub-criterion risks to supply 
risks are presented in Figure 4. The figure signifies that the uncertain supply has the highest 
risk of the supplier’s activities by 0.81, while the score of diversity in supply was 0.19. Supply 
risks faced by the supplier refer to risks in the uncertain supply availability to meet farmers’ 
needs. Goods that are only provided by suppliers were commodities highly needed by farmers. 
Meanwhile, suppliers wait for the total items requested by farmers to cultivate rice. 

    
 

FIGURE 3. THE WEIGHTING STRUCTURE OF RISK PRIORITY CRITERIA AND SUB-
CRITERIA AT THE SUPPLIER LEVEL 

FIGURE 4. THE WEIGHTING STRUCTURE OF 
RISK PRIORITY AT THE SUPPLIER LEVEL 

Therefore, the most troubling conditions for suppliers are when farmers do not need 
supplies or pay attention to the available supplies. However, when farmers need supplies, then 
the suppliers must immediately provide the available supply. If the supply is absent, the 
farmers are angry, sue the suppliers, or protest against them.  

Suppliers Farmers Loggers Grinders Traders Buyers 

Priority risk criteria  

Environment 
by 0.081 

Quality by 
0.259 

Prices by 
0.28 

 

Transportatio
n by 0.078 

 

Supply by 
0.30 

Priority risk criteria  
 

Uncertain 
Supply  
0.81 

Variety of  
Supply 0.19 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

246 AGRARIS: Journal of Agribusiness and Rural Development Research 
Risks at the Farm Level  

The farm level was analyzed to determine the risks faced by farmers in the supply chain 
management to improve the quality of semi-organic rice products. The result of weighting risk 
factors using the fuzzy AHP shows that the highest risk factor at the farm level was the 
environmental risk. Meanwhile, the following factors were quality, price, supply, production, 
and transportation risks. Rating was considered valid because its CR value was 0.04 or <0.1. 
The risk factor of weighing results at the farm level are presented in Figure 5. There were six 
criteria to examine the risks for actors of semi-organic rice supply chains. They were supply, 
transportation, price, quality, environment, and production. 

 

FIGURE 5. PRIORITY RISK CRITERIA AND SUB-CRITERIA AT THE FARMER LEVEL 

Figure 5 demonstrates that the highest risk priority at the farmer level was the 
environmental risk by 0.507. The transportation risk weights -0.03, the supply risk weights 
0.02, the price risk weights 0.28, the quality risk weights 0.22, and the production risk weights 
0.02. Meanwhile, the risk sub-criteria in the environmental risks are presented in Figure 6.  

 

FIGURE 6. RISK PRIORITY AT THE FARMER LEVEL 

Figure 6 denotes that the pests and diseases are at the highest risk for farmer activities 
with a weight of 0.32. Other risks are the natural disaster risk with a weight of 0.10, the 
government policy risk with a weight of 0.12, the climate risk with a weight of 0.24, the risk 
of political, social, and cultural conditions weight 0.05, and the competitor’s product risk 
weights 0.17. The highest risk of pests or diseases to the farmers’ activities refers to the number 
of pests, such as rats, that make farmers experience huge losses. Pests in agriculture are plant-
disturbing organisms that damage the crops physically and physiologically. These pests cause 
crop failure, decrease the amount of crop production, disturb rice growth, decrease the 
economic value of production, and cause losses to farmers. Farmers and the community have 
done various ways to control rats, such as biological, sanitary, mechanical, and chemical 
methods, but they always fail and suffer from crop failure. Besides pests, diseases, such as 
bacterial leaf blight, often attack rice plants. This disease attacks rice leaves and is similar to 
stem borer attacks. Another disease is a leaf spot disease caused by fungus. 

Priority risk criteria  

Environment by 
0.57 

Quality by 
022 

Price by 
0.2 

Transportation by 
-0.03 

 

Supply by 
0.02 

Production by 
0.02 

Priority risk sub-criteria  

Socio, economic, 
and political risks 

by 0.05 

Pest by 
0.32 

Climate by 

0.24 

Government policy 
by 0.12 

Natural 
disaster by 0.10 

Others by 

0.17 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

247 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 
Risks at the Logger Level 

The analysis level was conducted to determine the risks compulsorily faced in the supply 
chain management to improve the quality of semi-organic rice products. The result of 
weighting risk factors using fuzzy AHP shows that the highest risk factor to the logger level was 
the environmental risk. The successive high factors were price, quality, supply, and 
transportation risks. The rating was considered valid because its CR value was 0.03 or <0.1. 
The weighting results of the risk factor at the log level are presented in Figure 7. This study 
employed five criteria to examine the risks to actors of semi-organic rice supply chains. They 
were supply, transportation, price, quality, and environment. The following structures are 
weighting priority risk criteria and risk sub-criteria at the logger level.  

 
FIGURE 7. THE PRIORITY WEIGHTING STRUCTURE OF RISK CRITERIA AT THE LOGGING LEVEL 

 
FIGURE 8. PRIORITY WEIGHTING STRUCTURE OF ENVIRONMENTAL RISK SUB-CRITERIA AT THE LOGGING LEVEL 

Figure 7 shows that the highest risk priority at the logging level was the environmental risk 
by 0.37. The supply risk weights are 0.04, the transportation weights 0.04, the price risk weights 
0.24, the quality risk weights 0.23, and the environmental risk weights 0.37. Figure 8 shows that 
the risk of competing products was the highest risk to logging activities with a weighting of 0.34. 
Other risks were the natural disaster risk with a weight of 0.14, the government policy risk with a 
weight of 0.25, the climate risk with a weight of 0.12, the risk of social, political, and cultural 
conditions with a weight of 0.05, and pest or disease risk with a weight of 0.17. The competitors’ 
product risk in question refers to competition among loggers when cutting grains from farmers. 
In addition, when harvesting in other cities, many products from those cities were brought to 
Watugede Village. Consequently, the product prices from this village fall and loggers suffer from 
losses. In addition, the government policies also cause the risk because of insufficient relation to 
the rice entry distribution in Watugede Village. 

Risks at the Grinder Level 

Risk identification at the grinder level using the fuzzy AHP obtained the highest priority 
risk faced by grinders in the semi-organic rice supply chain was the price risk. The next high-

Priority risk sub-criteria  

Socio, economic, 
and political by 

0.05 

Pest by 
0.11 

Climate by 
0.12 

Government policy by 
0.25 

Natural disaster 
by 0.14 

Others by 
0.34 

Priority risk criteria  

Environment by  
0.37 

Quality by 
0.23 

Price by 

0.24 

Transportation by 

0.04 

Supply by 
0.04 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

248 AGRARIS: Journal of Agribusiness and Rural Development Research 
priority risks were quality, production, supply, transportation, and environmental risks. The risk 
assessment was considered valid because its CR value was 0.06 or <0.1. Figure 9 shows the 
calculation results using Fuzzy. There were six criteria used to examine the risks to actors of semi-
organic rice supply chains. They were the supply, transportation, price, quality, environment, and 
production. The following is the weighting structure of priority risk criteria and risk sub-criteria 
at the grinder level. 

 

FIGURE 9. PRIORITY WEIGHTING STRUCTURE OF RISK CRITERIA AT THE GRINDER LEVEL 

Figure 9 describes that the highest risk priority at the grinder level was the price risk by 
0.30. The supply risk weights were 0.19; the transportation risk had a weight of 0.06, the 
quality risk weights 0.21, the environmental risk weights 0.05, and the production risk weights 
0.37. The risk sub-criteria on environmental risks are presented in Figure 10. The figure 
presents that the price fluctuation was the highest risk to grinder activities with a weight of 
0.62. Another risk is inflation with a weight of 0.23. The risk of information distortion weights 
0.15. Price fluctuations occur in two situations. When production is abundant, prices will 
greatly decrease. Conversely, when production is small, prices will rise. In addition, price 
fluctuations occur because the quality of rice was not good due to the damage when drying 
the grain, and there are a lot of rice stocks or broken rice due to uncertain weather conditions. 
The poor grain quality makes the grinder recognize that they should reduce the rice price for 
the retailers and consumers. In addition, the desire of retail traders and consumers to low 
prices causes grinders to suffer from loss. If direct sales are made to consumers, the grinder 
will receive a higher price because the direct sales can be directly adjusted to market prices. 
However, if a sale was made to a trader, the received price will be lower because the price was 
adjusted to the price at the grinder level. 

Risks at the Trader Level 

The risk identification at the trader level using the fuzzy AHP obtained risk priorities 
faced by traders in the semi-organic rice supply chain. The price and quality risks were the 
highest priorities. The next priorities were environmental risk, supply risk, and risk 
transportation. The assessments will produce priority weights investigating the value of each 
risk. The rating was considered valid because its CR value was 0.04 or <0.1. Five criteria were 
employed to examine the risks to actors of semi-organic rice supply chains. They were supply, 
transportation, price, quality, and environment. The following structures are the weighting of 
priority risk criteria and risk sub-criteria at the retail trader level. 

Priority risk criteria  

Environment by 
0.05 

Quality by 
0.21 

Price by 
0.30 

Transportation by 
0.06 

Supply  by 
0.19 

Production by 
0.20 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

249 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 

 
FIGURE 11. PRIORITY WEIGHTING STRUCTURE OF RISK CRITERIA AT THE RETAIL=TRADER LEVEL 

 
FIGURE 12. PRIORITY WEIGHTING STRUCTURE OF PRICE AND QUALITY RISK SUB-CRITERIA AT THE RETAIL TRADER LEVEL 

Figure 11 shows that the highest risk priority at the retail level was the price and quality 
risk by 0.291. The supply risk weights 0.119, the transportation risk weights 0.122, and the 
environmental risk weights 0.177. The risk sub-criteria of the price and quality risk are 
presented in Figure 12. The figure shows that the price fluctuation was the highest price risk 
to trader activities with a weight of 0.68. Other risks were inflation with a weight of 0.19 and 
the information distortion risk with a weight of 0.13. Quality variation also becomes the 
highest quality risk to trader activities with a weight of 0.57. Another risk was the risk of low 
quality with a weight of 0.43. This risk was caused by the low rice price because of low quality, 
such as inadequate rice. Prices sold by retailers range from IDR9,500 to IDR12,000 per kg. In 
addition, the quality of rice was sometimes low and diverse, and thus, consumers refuse or 
become more selective when purchasing rice. Groats in rice is another important factor 

(Beloshapka et al., 2016) that probably makes consumers refuse to buy rice. 

Risks at the Consumer Level 

The risk identification at the consumer level by using the fuzzy AHP revealed that the 
highest priority risk faced by consumers in the semi-organic rice supply chain was the price 
risk. Other encountered risks were the supply and quality risks. The assessments will produce 
priority weights to examine the value of each risk. The rating was considered valid because its 
CR value was 0.04 or <0.1. The following figures summarize the results of calculations using 
fuzzy. Three criteria were employed to explore the risks to actors of semi-organic rice supply 
chains. They were the supply, price, and quality. The following structures are the weighting of 
priority risk criteria and risk sub-criteria at the consumer level. 

Priority risk criteria  

Environment by 
0.177 

Quality by 
0.29 

Price by 
0.29 

Transportation by 
0.06 

Supply by 
0.119 

Priority risk sub-criteria  

Price by 0.291 
 

Price inflation by 
0.19 

Price fluctuation by 
0.68 

Distortion of information 
by 0.13 

Quality by 0.291 

Low quality by 
0.43 

Varies in quality by 
0.37 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

250 AGRARIS: Journal of Agribusiness and Rural Development Research 

   
 

FIGURE 13. PRIORITY WEIGHTING STRUCTURE OF RISK 
CRITERIA AT THE CONSUMER LEVEL 

FIGURE 14. PRIORITY WEIGHTING STRUCTURE OF PRICE RISK SUB-CRITERIA 
AT THE CONSUMER LEVEL 

Figure 13 shows that the highest risk priority at the consumer level was price risk by 
0.48. The supply risk weights 0.46, and the quality risk weights 0.06. The data of risks at the 
consumer level processed by the fuzzy AHP are provided by three respondents. Table 14 shows 
that the highest risk priority experienced by consumers was the price risk by 0.48. Therefore, 
the price risk had the biggest or most important influence among the other five risks to 
consumers of semi-organic rice. Meanwhile, the weight of the supply risk was 0.46, and the 
weight of the quality risk was 0.06. The price risk had several risk sub-criteria, such as inflation, 
price fluctuations, and information distortion. The questionnaire using the fuzzy AHP 
revealed that the highest risk priority of the price fluctuation was at the consumer level. 
Consumers frequently encounter price fluctuations because of the low quality, falling rice 
prices, and rising rice prices due to rising demand (Costantino et al., 2012). 

Risk Mitigation Strategies for Actors of Each Semi-Organic Rice Supply Chains  

This research employed risk mitigation strategies to improve the occurring risks in semi-
organic rice (Talluri, Kull, Yildiz, & Yoon, 2013). The strategies applied for semi-organic rice 
supply chains in Watugede Village are expected to minimize the risk. Mitigation strategies are 
conducted by discussion between researchers and respondents, who are actors (Di Falco & 
Bulte, 2013) in the semi-organic rice supply chains. The risk mitigation of risk priorities 
encountered by actors in each supply chain is explained as follows. 

Risk Mitigation Strategies at the Supplier  Level 

Table 1 describes those suppliers perceive three risks that occur at the supplier level. 
The first was the supply risk, namely the uncertain supply risk. The second was the quality 
risk, namely the low-quality risk. The third was the environmental risk, namely government 
policy risk. The fuzzy AHP analysis discovered that the highest risk priority was the supply risk, 
namely the uncertain supply risk. To deal with the uncertain supply problem, sharing 
information in the supply chain, optimizing the level of supply readiness, and measuring 
supply chain performance are highly needed (Zhou & Benton, 2007).  

Risk Mitigation Strategies at the Farmer Level 

Table 1 describes those farmers perceive five risks occurring at the farm level. The first 
was the supply risk, consisting of the uncertain supply risk. The second was the price risk, 

Priority risk criteria 

Quality by 0.06 Price by 0.48 Supply by 0.46 

Priority risk sub-criteria  

Information distortion by 0.32 Price fluctuation by 0.35 Inflation by 0.33 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

251 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 
consisting of the inflation and price fluctuation risk. The third was the quality risk, consisting 
of the risk of low quality. The fourth was the environmental risks, consisting of the 
government policy, pest or disease, and competitors’ product risks. The fifth was production 
risk, consisting of the risk of an unachieved production target. The fuzzy AHP analysis revealed 
that the highest risk priority was the environmental risk, consisting of the pest or disease risk. 
This risk is preventable by cleaning land or environmental sanitation, cleaning grass or bushes 
where rats nest, installing nursery curtains when rice is sown, dismantling rat holes, and killing 
the physical states of the rats directly (Di Falco & Bulte, 2013). 

TABLE 1. PERCEPTION AND EVALUATION RESULTS OF THE HIGHEST RISK PRIORITIES FOR ACTORS OF SEMI-ORGANIC RICE SUPPLY CHAINS 

Criteria Sub-criteria Supplier Farmer Logger Grinder Trader Consumer 

Supply Diverse supplies    ✓   

Uncertain supplies ✔ ✓ ✓ ✓ ✓ ✓ 

Transportation Infrastructure damages       
Uncertain transportation time    ✓   

Insecure road       
Long haul distances       

Prices Inflation  ✓ ✓     

Price fluctuations  ✓ ✓ ✔ ✔ ✔ 
Information distortion   ✓ ✓ ✓  

Quality Low quality ✓ ✓ ✓ ✓ ✓ ✓ ✓ 
Quality variation   ✓ ✓ ✔ ✓ 

Environment Natural disasters       
Government policies ✓ ✓ ✓    

Climates  ✓ ✓ ✓   

Political, social, and cultural conditions       
Pests/diseases  ✔   ✓  

Competitive products  ✓ ✔ ✓ ✓  

Production  Production capacities       
Inefficient production processes       
Not achieved targets  ✓     

Use of technology       

Risk Mitigation Strategies at The Logger Level 

Table 1 shows that the loggers perceive four risks occurring at the logger level. The first 
was the supply risk, comprising of the uncertain supply risk. The second was the price risks, 
comprising price fluctuations and information distortion risks. The third was the quality risks, 
comprising low quality and various quality risks. The fourth was the environmental risk, 
comprising government policy, climate, and competitors’ product risks (Zhou & Benton, 
2007). The AHP fuzzy analysis found that the highest risk priority for the environmental risk 
was the risk of competitors’ products. If the harvest in other cities is big, the products freely 
enter the village. This condition makes the price fall, and the logger suffers from losses (Di 
Falco & Bulte, 2013). There are several efforts to minimize the risks:  

 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

252 AGRARIS: Journal of Agribusiness and Rural Development Research 
1. Communicating more with farmers,  
2. paying more attention to rice planting schedules to minimize falling prices and maintain 

the supply availability when there is a big harvest outside Watugede Village,  
3. relating the government policies to several products entering Watugede Village, and 
4. hoarding unhusked rice in advance to keep the stock and increase rice production. 

Risk Mitigation Strategies at the Grinder Level 

Table 1 represents that the grinders perceive five risks occurring at the grinder level. The 
first was the supply risks, such as the diverse supply and uncertain supply risks. The second 
was the transportation risk, such as uncertain transportation time. The third was the price 
risks, such as price volatility and information distortion risks. The fourth was the quality risk, 
such as the low quality and various quality risks. The fifth was the environmental risk, such as 
the climate risk. The sixth was the production risk, such as the competing product risk (Di 
Falco & Bulte, 2013). The AHP fuzzy analysis revealed that the highest risk priority was the 
price risk, consisting of the price fluctuation risk. (Zhou & Benton, 2007) propose several 
efforts to minimize the risks:  
1. More maintaining quality of rice produced,  
2. obtaining raw materials of grain, and 
3. always updating the information of prevailing grain and rice prices in the market. 

Risk Mitigation Strategies at the Trader Level 

Table 1 presents that the retail traders perceive four risks occurring at the retail trader 
level. The first was the supply risk, consisting of the uncertain supply risk. The second was the 
price risks, consisting of the risks of price fluctuations and information distortion. The third 
was the quality risks, consisting of the risk of low quality and the risk of various quality. The 
fourth was the environmental risks, consisting of the pest or disease risk and the competing 
product risk. The AHP fuzzy analysis found that the highest risk priority was the price risk, 
consisting of the price fluctuation risk, and the quality risk, consisting of the risk of various 
quality. An effort to minimize the risks is building cooperation among traders to control rice 
prices in the market (Di Falco & Bulte, 2013). In addition, frequently fluctuating prices 
require intervention from the government to stabilize rice prices (Zhou & Benton, 2007)  

Risk Mitigation Strategies at the Consumers Level 

Table 1 shows that the consumer perceived three risks occurring at the consumer level. 
The first was the supply risk, comprising of uncertain supply risk. The second was the price 
risk, comprising of the price fluctuation risk. The third was the quality risk, comprising low-
quality and various quality risks. The AHP fuzzy analysis discovered that the highest risk 
priority was the price risk, comprising of the price fluctuations. The risk can be minimized by 
maintaining stable prices in all parties or actors of the supply chain from the downstream to 
the upstream (Zhou & Benton, 2007). 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

253 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 
CONCLUSION 

This study concludes several principal findings. This conclusion is related to the 
introduction and aims or hypothesis but does not repeat the discussion. Moreover, the 
conclusion was written briefly, critically, logically, and honestly following the discovered facts. 
Moreover, the discussion was written cautiously if there had been a generalization.  

Actors involved in semi-organic rice supply chains in Watugede Village, Singosari 
District were suppliers, farmers, loggers, grinders, traders, and consumers. The risks at the 
supplier level were supply, quality, and environment risks. Risks at the farm level awere the 
supply, price, quality, environment, and production risks. Risks at the logging level were 
supply, price, quality, and environment risks. Risks at the grinder level were supply, 
transportation, price, quality, environment, and production risks. Risks at trader levels were 
supply, price, quality, and environment risks. Finally, risks at the consumer level were supply, 
price, and quality risks. 

The evaluation of the highest risk priority in supply chain actors employed the fuzzy 
AHP and revealed several points. The risks at the supplier level were the supply risk and the 
supply risk sub-criteria, such as the uncertain supply risk. The risks at the farm level were the 
environmental risk and environmental risk sub-criteria, such as the pest or disease risk. The 
risks at the logistical level were environmental risks and environmental risk sub-criteria, such 
as the risk of competing products. The risks at the grinder level were the price risk and the 
price risk sub-criteria, such as the price fluctuation risk. The risks at the retail level were price 
risk and quality risk. The price risk subcategory constitutes the price fluctuation risk. 
Meanwhile, the quality risk subcategory constitutes the risk of various quality. The risks at the 
consumer level were the price risk and price risk sub-criteria, such as the price fluctuation risk. 

The risks at the supplier level can be prevented by sharing information along the supply 
chains, optimizing the level of supply availability, measuring supply chain performance, and 
building more coordination with government subsidies. The risks at the farm level can be 
prevented by clearing land or environmental sanitation, cleaning grass or bushes where rats 
nest, installing nursery curtains when rice is sown, dismantling rat holes, and killing rats’ 
physical states directly. The risks at falling prices can be minimized by improving government 
policies on products entering Watugede Village and hoarding unhusked rice. Consequently, 
stocks remain. Another effort is increasing rice production. The risks at the grinder level can 
be minimized by maintaining the quality of rice production, obtaining raw materials of grains, 
and always following the information of prevailing grain and rice prices in the market. The 
risks at the retail trader level can be minimized by building cooperation among traders to 
control rice prices in the market. Moreover, frequently fluctuating prices require intervention 
from the government to stabilize rice prices. The risks at the consumer level can be minimized 
by maintaining stable price stability in all parties or actors in the supply chain from the 
downstream to the upstream. 

Acknowledgments: We would like to express our sincere gratitude to the Directorate of 
Research and Community Service, General Directorate for Strengthening Research and 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&


 

ISSN: 2407-814X (p); 2527-9238 (e) 

254 AGRARIS: Journal of Agribusiness and Rural Development Research 
Development of the Ministry of Research, Technology, and Higher Education (RISTEKDIKTI) 
for funding this research through the community service in the community partnership 
program no. 579 in 2019. 

REFERENCE 

Beloshapka, A. N., Buff, P. R., Fahey, G. C., & Swanson, K. S. (2016). Compositional analysis 
of whole grains, processed grains, grain co-products, and other carbohydrate sources 
with applicability to pet animal nutrition. Foods, 5(2), 1–16. 
https://doi.org/10.3390/foods5020023 

 

Blome, C., & Schoenherr, T. (2011). Supply chain risk management in financial crises - A 
multiple case-study approach. International Journal of Production Economics, 134(1), 43–
57. https://doi.org/10.1016/j.ijpe.2011.01.002 

 

Bollapragada, R., Rao, U. S., & Zhang, J. (2004). Managing inventory and supply performance 
in assembly systems with random supply capacity and demand. Management Science, 
50(12), 1729–1743. https://doi.org/10.1287/mnsc.1040.0314 

 

Cachon, G. P., & Lariviere, M. A. (1999). Capacity choice and allocation: strategic behavior 
and supply chain performance. Management Science, 45(8), 1091–1108. 
https://doi.org/10.1287/mnsc.45.8.1091 

 

Costantino, N., Dotoli, M., Falagario, M., Fanti, M. P., & Mangini, A. M. (2012). A model 
for supply management of agile manufacturing supply chains. International Journal of 
Production Economics, 135(1), 451–457. https://doi.org/10.1016/j.ijpe.2011.08.021 

 

Di Falco, S., & Bulte, E. (2013). The Impact of Kinship Networks on the Adoption of Risk-
Mitigating Strategies in Ethiopia. World Development, 43, 100–110. 
https://doi.org/10.1016/j.worlddev.2012.10.011 

 

Ellram, L. M. (1990). The Supplier Selection Decision in Strategic Partnerships. Journal of 
Purchasing and Materials Management, 26(4), 8–14. https://doi.org/10.1111/j.1745-
493x.1990.tb00515.x 

 

Feng, Q. (2010). Integrating dynamic pricing and replenishment decisions under supply 
capacity uncertainty. Management Science, 56(12), 2154–2172. 
https://doi.org/10.1287/mnsc.1100.1238 

 

Food and Agriculture Organization. (2021). Gross domestic product and agriculture value 
added 1970–2019. Global and regional trends. In FAOSTAT analytical briefs. Rome, 
Italy: Food and Agriculture Organization. Retrieved from 
https://www.fao.org/documents/card/en/c/cb4651en/ 

 

Halldórsson, Á., Kotzab, H., & Skjøtt-Larsen, T. (2009). Supply chain management on the 
crossroad to sustainability: a blessing or a curse? Logistics Research, 1, 83–94. 
https://doi.org/10.1007/s12159-009-0012-y 

 

Hammoudi, A., Hoffmann, R., & Surry, Y. (2009). Food safety standards and agri-food supply 
chains: An introductory overview. European Review of Agricultural Economics, 36(4), 469–
478. https://doi.org/10.1093/erae/jbp044 

 
 

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&
https://doi.org/10.3390/foods5020023
https://doi.org/10.1016/j.ijpe.2011.01.002
https://doi.org/10.1287/mnsc.1040.0314
https://doi.org/10.1287/mnsc.45.8.1091
https://doi.org/10.1016/j.ijpe.2011.08.021
https://doi.org/10.1016/j.worlddev.2012.10.011
https://doi.org/10.1111/j.1745-493x.1990.tb00515.x
https://doi.org/10.1111/j.1745-493x.1990.tb00515.x
https://doi.org/10.1287/mnsc.1100.1238
https://doi.org/10.1007/s12159-009-0012-y
https://doi.org/10.1093/erae/jbp044


 

ISSN: 2407-814X (p); 2527-9238 (e) 

255 Risk Mitigation Strategies in Semi-Organic Rice ….. (Wahyuningtyas, Haryati, Pratiwi, and Situmeang) 
Kahraman, C., Cebeci, U., & Ulukan, Z. (2003). Multi‐criteria supplier selection using fuzzy 

AHP. Logistics Information Management, 16(6), 382–394. 
https://doi.org/10.1108/09576050310503367 

 

Matzembacher, D. E., & Meira, F. B. (2019). Sustainability as business strategy in community 
supported agriculture: Social, environmental and economic benefits for producers and 
consumers. British Food Journal, 121(2), 616–632. https://doi.org/10.1108/BFJ-03-
2018-0207 

 

Novak, S., & Eppinger, S. D. (2001). Sourcing by design: Product complexity and the supply 
chain. Management Science, 47(1), 189–204. 
https://doi.org/10.1287/mnsc.47.1.189.10662 

 

Queirós, A., Faria, D., & Almeida, F. (2017). Strengths and Limitations of Qualitative and 
Quantitative Research Methods. European Journal of Education Studies, 3(9), 369–387. 
https://doi.org/10.5281/zenodo.887089  

 

Santis, R. B. de, Golliat, L., & Aguiar, E. P. de. (2017). Multi-criteria supplier selection using 
fuzzy analytic hierarchy process: case study from a Brazilian railway operator. Brazilian 
Journal of Operations & Production Management, 14(3), 428. 
https://doi.org/10.14488/bjopm.2017.v14.n3.a15 

 

Spekman, R. E., & Davis, E. W. (2004). Risky business: Expanding the discussion on risk and 
the extended enterprise. International Journal of Physical Distribution and Logistics 
Management, 34(5), 414–433. https://doi.org/10.1108/09600030410545454 

 

Talluri, S. (Sri), Kull, T. J., Yildiz, H., & Yoon, J. (2013). Assessing the Efficiency of Risk 
Mitigation Strategies in Supply Chains. Journal of Business Logistics, 34(4), 253–269. 

 

Tang, O., & Nurmaya Musa, S. (2011). Identifying risk issues and research advancements in 
supply chain risk management. International Journal of Production Economics, 133(1), 25–
34. https://doi.org/10.1016/j.ijpe.2010.06.013 

 

Wu, W. Y., Chang, M. L., & Chen, C. W. (2008). Promoting innovation through the 
accumulation of intellectual capital, social capital, and entrepreneurial orientation. 
R&D Management, 38(3), 265-277. https://doi.org/10.1111/1467-9914.00120-i1  

 

Zhou, H., & Benton, W. C. (2007). Supply chain practice and information sharing. Journal of 
Operations Management, 25(6), 1348–1365. https://doi.org/10.1016/j.jom.2007.01.009  

http://issn.pdii.lipi.go.id/issn.cgi?daftar&1420518152&1&&
https://doi.org/10.1108/09576050310503367
https://doi.org/10.1108/BFJ-03-2018-0207
https://doi.org/10.1108/BFJ-03-2018-0207
https://doi.org/10.1287/mnsc.47.1.189.10662
https://doi.org/10.5281/zenodo.887089
https://doi.org/10.14488/bjopm.2017.v14.n3.a15
https://doi.org/10.1108/09600030410545454
https://doi.org/10.1016/j.ijpe.2010.06.013
https://doi.org/10.1111/1467-9914.00120-i1
https://doi.org/10.1016/j.jom.2007.01.009