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 CHEMICAL ENGINEERING   TRANSACTIONS
 

VOL. 45, 2015 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Sharifah Rafidah Wan Alwi, Jun Yow Yong, Xia Liu  

Copyright © 2015, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-36-5; ISSN 2283-9216 DOI: 10.3303/CET1545055 

 

Please cite this article as: Ubando A.T., Felix C.B., Promentilla M.A.B., Culaba A.B., 2015, Strategic site selection of 

microalgae industry in the philippines using analytic hierarchy process, Chemical Engineering Transactions, 45, 325-330  

DOI:10.3303/CET1545055 

325 

Strategic site selection of microalgae industry in the 

Philippines using analytic hierarchy process 

Aristotle T. Ubando*
,a

, Charles B. Felix
a
, Michael Angelo B. Promentilla

b
,  

Alvin B. Culaba
a
 

a
Mechanical Engineering Department, De La Salle University, 2401 Taft Avenue, Manila, Philippines 

b
Chemical Engineering Department, De La Salle University, 2401 Taft Avenue, Manila, Philippines 

 aristotle.ubando@dlsu.edu.ph 

Microalgae are microorganisms which converts sunlight and carbon dioxide to useful biomass. It consists 

of high-valued contents such as protein, carbohydrates, lipids and pigments which can yield various 

industrial products: nutraceuticals, animal feeds, and biofuels. Since the Philippines was found to have an 

abundance of microalgae species due to its tropical climate and archipelagic nature, a strategic multi-

criteria site selection decision structure must first be established for potential deployment of cultivation and 

processing locations involving multiple industries. Analytic hierarchy process (AHP) was utilized to develop 

the strategic decision structure of the study. A survey from a panel of stakeholders was conducted to 

identify the prioritization between criteria via pairwise comparison method. The results revealed the 

preferred regions of the Philippines suitable for an anticipatory microalgal industry. The developed decision 

structure aims to aid policy makers and stakeholders for the deployment of the emerging industry. Future 

work involves the consideration of uncertainty of judgment from the panel of stakeholders. 

1. Introduction 

Unprecedented rise in the cost of conventional fuels as well as the ongoing concern for global warming 

and climate change have provided the impetus in the quest for sustainable and renewable source of 

energy, for which microalgae have become a mainstream. Several distinguishing characteristics of 

microalgae feedstock include concordance with food security, wastewater treatment potential, carbon 

dioxide sequestration, round-the-clock production and less nutrient input (Brennan and Owende, 2010). 

However, they have yet to reach commercialization stage due to relatively lower energy ratios caused by 

extensive energy input (Lam and Lee, 2012). 

While these are true, harnessing microalgae biomass also presents another opportunity for cogeneration 

of value-added products aside from biofuels. Various compounds present in microalgae such as proteins, 

carbohydrates, lipids and other chemical compounds can be utilized in many aspects such as for power 

generation, health, animal feed and nutraceuticals (Becker, 2008). Sustainable production from microalgae 

biomass can therefore be achieved if co-generation of its high value-products is permitted. Kirrolia et al 

(2013) argued that in order for microalgae biofuel production to become sustainable, co-production of 

other products should be established.  

Several sustainability studies are also being done which consider cogeneration of microalgae products. A 

microalgal multi-functional bioenergy system, aimed at optimising the whole microalgal products supply 

chain while maximising economic potential and minimising environmental impact, was established by 

Ubando (2014). Garcia Prieto et al (2014) formulated an optimisation model of a microalgae biorefinery 

producing both biodiesel and PHB biopolymer. Meanwhile, analysis of the composition of microalgae 

biomass products was examined by Pinzón Frias et al (2014) and ranked these obtainable products based 

on a certain techno-economic criteria. 

The Philippines, having a tropical climate and an archipelagic nature, was found to boast a great 

abundance of numerous microalgae species. As the global demand for microalgal products is sure to 

elevate the economic status of the country, it is likely that a potential microalgae industry would be 



 

 

326 

 
established in the near future. While this is true, there is still a gap in the strategic planning of the 

deployment of this emerging industry. This includes the systematic selection of the best cultivation and 

processing sites as source of useful microalgal biomass. 

A multi-criteria decision-making (MCDM) methodology was employed to facilitate this type of analysis. The 

analytic hierarchy process (AHP) is a very promising MCDM procedure, developed by Saaty in the 1970s 

(Saaty, 1980). It is widely-renowned for its application to energy-related decision analysis and it is highly 

suitable for this study as it combines both qualitative and quantitative information (Pohekar and 

Ramachandran, 2004). Given a set of multiple criteria which are to be considered simultaneously, the AHP 

identifies the best alternative while giving a ranking of all the possible choices or alternatives (Saaty, 

1980). More promising features in using the AHP as a decision-making tool are its ability to handle 

inconsistencies with regards to making subjective judgments as well as its ease of use (Harker, 1987).  

After extensive literature review and expert insights, relevant data regarding stakeholder prioritization via 

pairwise comparisons and regional performance indicators were recorded. A sensitivity analysis was also 

done aimed at detailed analysis between the input-output relationship of the developed AHP model. 

2. Methodology 

2.1 AHP structure 
In structuring the significant decision-making methodology, factors which comprise the problem are 

decomposed and structured into a hierarchy. An identified set of criteria was enumerated, with the main 

criteria as natural resources, social acceptability, economic cost and present industries. The four main 

criteria are further expounded by respective sub-criteria. Finally, the set of choices or alternatives includes 

all of the 17 regions in the Philippines. 

Natural resources include those which are necessary for microalgal cultivation. For a phototropic type of 

production, microalgae grow in aqueous media, absorbing carbon dioxide and sunlight or any artificial 

lighting (Brennan and Owende, 2010). Other inorganic nutrients may also be provided as fertilizers to 

accelerate algae production, and these include nitrogen and phosphorus (Brennan and Owende, 2010). 

Land area is also a major requirement for establishing appropriate facilities to serve this purpose and to 

store the generated biomass. For the socio-economic aspect, acceptance of the society for the 

deployment of this industry must be taken into consideration. Job creation is expected and must be highly 

matched by the potential labor force of the regions where they are situated. Poverty index is also affected 

as more jobless people are employed. Meanwhile, the economic or financial performance of this possible 

industry can be best monitored in terms of the costs of the resources required – water, fertilizer and 

electricity, as well as income to labourers. Another consideration for the strategic implementation of a 

multi-functional microalgal industry is its proximity to several present industries which can be served by 

microalgae value-added products. These are, but not limited to, aquaculture, poultry, swine, carabao, cow 

and biofuels. Ubando et al (2015) also proposed a similar hierarchal structure, but only considered biofuels 

industry as the sole beneficiary of the microalgae product. 

The Philippine archipelago, consisting of 7,107 islands, is divided into three groups. Luzon in the northern 

part has the largest land area and is comprised of a total of eight regions, including the National Capital 

Region (NCR). Mindanao, the second largest land area, is situated in the south and is comprised of six 

regions. Lastly, Visayas, which consists of only three regions with many islands, is located at the central 

part. Altogether, the three main island groups comprise the 17 regions in the Philippines.  

The final AHP structure consisting of the goal, main and sub-criteria and the alternatives is depicted in 

Figure 1. 

2.2 Stakeholder prioritization and sensitivity analysis 

A survey was conducted to evaluate stakeholder prioritization between the enumerated criteria via 

pairwise comparison. The stakeholders were selected from various members of national and local 

government agencies, academe and private companies who could be affected by the emergence of a 

possible microalgae industry. The authors adapted a 9-point fundamental scale obtained from Saaty 

(1980), to quantify the judgments. Meanwhile, the pairwise comparison matrix was generated as an n by n 

matrix in which n is the number of main criteria, or the number of sub-criteria relative to each main 

criterion. The entries for the elements in the upper echelon were the priority weights ratio of the two criteria 

evaluated by the stakeholders, or regional data obtained from various references. The entries for the 

remaining cells were the reciprocals of the weight between previously evaluated criteria. The pairwise 

comparison matrix for the main and sub-criteria were checked for consistency, and were normalized using 

the eigenvector method. This theoretical foundation and detailed methodology of the AHP can be found in 

Saaty (1980). For the sensitivity analysis, the main criteria and the present industries sub-criteria were 

tested through intended distribution of priority weights to observe the effects on the regional ranking. For 



 

 

327 

this purpose, a value of 75 % was placed on one criterion and the remainder was divided equally among 

the remaining criteria. The intended prioritisation was done as multiple scenarios to test all the main 

criteria and the present industries sub-criteria. Priority weights in the criteria not being evaluated were held 

constant. A total of 10 scenarios were generated in which 4 scenarios were appropriated to the four main 

criteria and the remaining 6 for present industries sub-criteria. 

Selection of Potential Algal 

Cultivation Sites in the 

Philippines

Natural Resources Social Acceptability Present IndustriesCosts

Carbon Dioxide

Water

Land

Fertilizer

Potential Labor 

Force

Aquaculture

Poultry

Swine

Minimum Wage 

Cost

Cost of Water

Climate Type

Biofuels

Carabao

Power Demand

Poverty Index

Cost of Fertilizer

Cost of Electricity

Cow

Luzon

NCR

CAR

Region 1

Region 2

Region III

Region IV-A

Region IV-B

Region 5

Visayas

Region VI

Region VII

Region VIII

Mindanao

Region IX

Region X

Region XI

Region XII

Region XIII

ARMM

 

Figure 1: Analytic hierarchy process structure in the evaluation of the most suitable microalgal cultivation 

sites in the Philippines 

3. Results and Discussion 

3.1 Survey results 
The priority distribution, in percentages, for the main and sub-criteria is shown in Figure 2. The main 

criteria distribution favoured the natural resources criterion followed by social acceptability. Meanwhile the 

highest obtaining sub-criteria are as follows: water supply for natural resources, potential labour force for 

social acceptability, minimum wage for costs and swine and poultry for present industries. 

3.2 Results of the AHP 

Table 1 presents the complete ranking of all the Philippine regions with their corresponding percentages. 

The overall results reveal that region XII (Soccsksargen) in Mindanao is the most preferred cultivation site 

for microalgae biomass production in the Philippines. This is followed by region IV-A (CALABARZON) in 

Luzon. Of the three regions in Visayas, region VI (Western Visayas) obtained the highest weight. Analysis 

of the data revealed that the top three regions show relatively high values in terms of regional performance 



 

 

328 

 
indicators – water supply for region XII, and carbon dioxide sources shared by both regions III and IV-A. 

These sub-criteria belong to natural resources main criteria which obtained the highest percentage of 

importance at 40 %. Meanwhile, a graphical representation of Table 1 is depicted in Figure 3. The weights 

were classified into five ranges of values which were represented by five different shades in the figure. 

Figure 2: Percentage weight of a) Main Criteria, b) Natural resources, c) social acceptability, d) Cost, and 

e) Present industries 

3.3 Results of the Sensitivity Analysis 
The results of the 10 scenarios generated were summarised in Table 3. It can be observed that all of these 

scenarios generally bring up the top-performing regions in the general AHP ranking even though priority 

weight distribution for some criteria were intentionally changed. This indicates that these top-performing 

regions are adaptable to anticipatory changes especially with regards to the priority weights to be given by 

additional surveys.  



 

 

329 

Table 1:  Ranking of the Philippine regions with the corresponding normalized weight 

Ranking Region   % 

1 XII Mindanao Soccsksargen 11.22 
2 IV-A  Luzon CALABARZON 9.12 
3 III  Luzon Central Luzon 7.78 
4 X Mindanao Northern Mindanao 6.84 
5 NCR Luzon National Capital Region 6.57 
6 VI Visayas Western Visayas 6.17 
7 VII Visayas Central Visayas 6.00 
8 V Luzon Bicol Region 5.94 
9 IX Mindanao Zamboanga Peninsula 5.61 
10 XI Mindanao Davao Region 5.45 
11 I Luzon Ilocos Region 5.24 
12 ARMM Mindanao Autonomous Region of Muslim Mindanao 4.61 
13 IV-B Luzon MIMAROPA 4.51 
14 VIII Visayas Eastern Visayas 4.32 
15 II Luzon Cagayan Valley 4.30 
16 XIII Mindanao Caraga 3.26 
17 CAR Luzon Cordillera Administrative Region 3.08 
                                                               Total  100 

 

Figure 3: Preferred microalgal cultivation and processing sites in the Philippines 

 



 

 

330 

 
Table 2:  Summary of the sensitivity analysis 

Scenario Preference (Given 75% weight) 1
st
 % 2

nd
 % 3

rd
 % 

1 Main Criteria – Natural Resources XII 16.17 IV-A  9.28 III  7.60 
2 Main Criteria – Social Acceptability IV-A  8.92 III  7.98 NCR 7.71 
3 Main Criteria – Cost XII  7.19 IV-A  6.73 III  6.54 
4 Main Criteria – Present Industries IV-A  13.04 III 10.15 VI 9.91 
5 Industry Sub-criteria – Aquaculture XII 10.92 IV-A  8.42 III  7.47 
6 Industry Sub-criteria – Poultry XII 11.18 IV-A  9.24 III  8.57 
7 Industry Sub-criteria – Swine XII  11.48 IV-A  8.90 III  8.21 
8 Industry Sub-criteria – Biofuels XII 10.82 IV-A 10.18 NCR 10.14 
9 Industry Sub-criteria – Carabao XII  11.59 IV-A  8.20 III  7.37 
10 Industry Sub-criteria – Cow XII  11.59 IV-A  8.62 III 7.34 

4. Conclusions 

A multi-criteria decision structure using analytic hierarchy process was developed to evaluate the most 

suitable microalgal cultivation and processing sites in the Philippines. Of the 17 regions, the most preferred 

are regions XII, IV-A and III. The sensitivity analysis performed provided grounds that these regions are 

really promising to serve this purpose very well. However, it is still best to consider the latter two regions 

due to their proximity to the national capital. Future work involves the consideration of participation of more 

stakeholders as well as addressing the uncertainty of judgment from this panel of stakeholders. 

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