P-graph Approach to Optimal Allocation of Electricity to Economic Sectors in Crisis Conditions


 Energy Procedia   61  ( 2014 )  675 – 678 

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1876-6102 © 2014 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license 
(http://creativecommons.org/licenses/by-nc-nd/3.0/).
Peer-review under responsibility of the Organizing Committee of ICAE2014
doi: 10.1016/j.egypro.2014.11.940 

The 6th International Conference on Applied Energy – ICAE2014 

P-Graph Approach to Optimal Allocation of Electricity to 
Economic Sectors in Crisis Conditions 

K. B. Avisoa*, C. Cayamandaa, F. D. Solisb, M. A. B. Promentillaa , K. D. S. Yub, 
J. R. Santosc and R. R. Tana 

a Chemical Engineering Department, De La Salle University, 2401 Taft Avenue, Malate, Manila, 1004, Philippines 
b School of Economics, De La Salle University, 2401 Taft Avenue, Malate, Manila, 1004, Philippines 

 c Department of Systems Engineering, The George Washington University 
 

Abstract 

Rational allocation of scarce resources in a crisis is an integral part of risk management. In the case of energy 
systems, for example, the onset of climate change is expected to increase the frequency of extreme weather events 
which will further affect not only the reliability of electricity transmission and fuel resource delivery but also test the 
integrity of energy infrastructure systems. Electricity supply is essential to all economic sectors and the onset of an 
energy crisis resulting from a calamity, an accident, an infrastructure failure or a political dispute will affect the 
productivity of the entire economy. Furthermore, the interdependencies between sectors can cause “ripple effects” to 
occur. Input-output models are an established methodology for quantifying such linkages in an economic system. 
During a power crisis, it is essential to provide a rational basis for allocation of limited energy supply in order to 
minimize its economic ripple effects. The best allocation for damage control can be determined by representing an 
input-output system as a P-graph model. The latter is a graph-theoretic approach originally developed for chemical 
process design applications, and the analogous problem structures allow it to be used for the optimal allocation of 
electricity to various economic sectors in the event of a power crisis. We demonstrate the methodology using a case 
study based on Philippine input-output data. 
 
© 2014 Published by Elsevier Ltd.  
Selection and/or peer-review under responsibility of ICAE 
 
Keywords:Energy crisis; allocation; P-graph; input-output analysis 

1. Introduction 

Input-output (I-O) analysis was originally developed for the analysis of highly interconnected 
economic sectors for purposes of forecasting and policy design [1,2]. Such I-O models represent 
economic systems via a system of linear equations that capture interdependencies. More recently, I-O 

 

* Corresponding author. Tel.: +632-536-0223; fax: +632-536-0223. 
E-mail address: kathleen.aviso@dlsu.edu.ph. 

© 2014 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license 
(http://creativecommons.org/licenses/by-nc-nd/3.0/).
Peer-review under responsibility of the Organizing Committee of ICAE2014

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676   K.B. Aviso et al.  /  Energy Procedia   61  ( 2014 )  675 – 678 

based optimization models have been proposed for crisis management, such as to determine optimal 
allocation of scarce resources following a disaster [3-5]. Analogous approaches have been proposed for 
infrastructure systems [4,6]. In this work, we propose an alternative approach towards solving such 
problems using a graph-theoretic method known as P-graph, which was originally developed for chemical 
process design applications [7]. It has since been used for various network optimization problems such as 
supply chain design; a recent paper reviews the most important developments in the field [8]. A software 
implementation of this methodology is also available [9]. 

In this paper, we present the first attempt to utilize P-graphs for allocation of scarce energy resources 
in an economic system. The rest of the paper is organized as follows. Section 2 gives the formal problem 
statement while Section 3 gives an overview of P-graph methodology used here. Section 4 shows a 
Philippine case study to illustrate the methodology and Section 5 gives conclusions and future works.  

 

2. Problem Statement 

The problem statement may be formally stated as follows: given an economic I-O system comprised of 
n sectors and n commodities, and given a crisis event that creates a sudden shortage of the kth 
commodity, the problem is to determine the optimal allocation of commodity k in the system so as to 
minimize total reduction of gross domestic product (GDP). 

3. P-Graph Methodology 

Another method that can be used besides the Leontief’s I-O model is to apply graph-theoretic 
approach for developing input-output model such as P-graph framework.  Process graph or P-graph 
framework is used to determine the optimal solution of a process network system based on graph theory 
and combinatorial algorithms [7].  P-graph is used in several applications such as optimization of process 
systems, reduction of emissions and wastes, identification of reaction pathways, and sustainable energy 
supply chain [8].   P-graph is the graphical representation of matrix calculations such as mixed-integer 
linear and nonlinear programming (MILP and MINLP) to solve process synthesis problems.  With this 
ability, P-graph can be used to solve I-O models for estimating risk assessment and optimal allocation of 
resources. 

4. Case Study 

This case study is based on the current power crisis in Mindanao, the southernmost major island of the 
Republic of the Philippines. Chronic electricity shortage is experienced in this island during the dry 
season due to over-dependency on hydroelectric power. This situation is expected to be compounded by 
climate change. We consider the case of Region XI, which comprises the most economically vibrant 
region of the island. A low-resolution, 4-sector I-O model of the economy of this region was derived from 
the most recent official national I-O model [10] using established regional disaggregation and sector 
aggregation methods [2], as shown in Table 1 with the total output and final demand rounded off to the 
nearest thousand pesos. 



 K.B. Aviso et al.  /  Energy Procedia   61  ( 2014 )  675 – 678 677

 
Table 1. Technical coefficients, total outputs and final demands for of 4-sector I-O model (Normal State) 

 
 Agriculture Industry Services Electricity 

Generation 
Final Demand 

(‘000 PhP) 
Total Output 
(‘000 PhP) 

Agriculture 0.05 0.06 0.01 0.000 81,646 123,678 
Industry 0.22 0.42 0.19 0.300 117,565 547,260 
Services 0.06 0.10 0.17 0.050 168,693 301,291 
Electricity Generation 0.01 0.02 0.01 0.004 367,904 384,637 

 
The economic flows of the system in its baseline state are shown in Figure 1a. In the event of a 10% 

power shortage with the final demand of all sectors remaining the same, the optimal allocation of 
electricity to minimize GDP loss in the system can be determined via the Accelerated Branch-and-Boud 
Method (ABB) within the P-graph model. This result is shown in Figure 1b, with a corresponding 4.95 % 
reduction in GDP relative to the normal state. Table 2 shows the summary of the experienced reduction in 
final demand and total output resulting from the 10% power shortage relative to the normal state total 
output. It can be seen that the 10% shortage in electricity has resulted in a reduction in total output for all 
other sectors by virtue of their interdependence. The industry sector experiences the second highest loss 
of 4.04% next to the electricity sector while the agriculture sector has the least reduction in total output of 
1.17%. However, even with the shortage in electricity, the final demands of the agriculture, industry and 
services sector were still satisfied while the demand of the electricity sector was reduced by 9.83%.     

 
 

 
 
 
 
 
 
 

 
(a)                                                                   (b) 

Figure 1. Economic flows for (a) normal and (b) crisis state, units in 10,000 pesos 

 

Table 2. Reduction in final demand and total output resulting from the 10% power shortage relative to normal state total output 

 

Economic Sector % Reduction in Final Demand % Reduction in Total Output 

Agriculture 0.00 1.17 

Industry 0.00 4.04 

Services 0.00 1.69 

Electricity 9.83 10.00 

Over-all 2.79 4.95 

 



678   K.B. Aviso et al.  /  Energy Procedia   61  ( 2014 )  675 – 678 

5. Conclusion 

A P-graph based approach for the allocation of scarce energy resources under crisis conditions has 
been presented. The graph-theoretic approach allows for a visual representation of highly interconnected 
input-output systems, and also enables efficient identification of a globally optimal solution. This 
technique is demonstrated with a case study on power shortages in the Southern Philippines. In reality, 
more complex interactions between system components will have to be considered if a higher degree of 
resolution is desired in the results. Furthermore, since the approach identifies the key sectors which must 
be prioritized during a crisis, this approach can be utilized for developing strategies for disaster 
preparedness. Future work will focus on the integration of the P-graph approach within a comprehensive 
decision analysis framework for crisis management. 
 
Acknowledgements 
 
We would like to acknowledge the Commission on Higher Education- Philippine Higher Education 
Research Network (CHED-PHERNet) through its Sustainability Studies Program for financial support. 

References 

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[9] P-graph. www.p-graph.com (accessed Dec. 20, 2013). 

[10] National Statistical Coordination Board. www.nscb.gov.ph/io/default.asp (accessed May 3, 2012). 

Biography  

Krista Danielle S. Yu, PhD is an assistant professor at the School of Economics, De La Salle University 
Manila, Philippines. Her research interests include input-output analysis, computable general equilibrium 
modelling and their applications to disaster risk management.