Abstracts

RECURSOS E DESENVOLVIMENTO EMPRESARIAL

Development of an indicator of propensity to energy commercial losses using geospatial statistical techniques and socio-economic data: the case of AES Eletropaulo

Desenvolvimento de indicador de propensão à perda comercial de energia utilizando técnicas de estatística espacial e dados socioeconômicos: o caso da AES Eletropaulo

Eduardo de Rezende Francisco^I; Eduardo Bortotti Fagundes^II; Mateus Canniatti Ponchio^III; Felipe Zambaldi^IV

^IDoutorando em Administração de Empresas pela Escola de Administração de Empresas de São Paulo, Fundação Getulio Vargas (FGV). Especialista de Negócios do Departamento de Gerência de Estratégias de Marketing da Eletropaulo Metropolitana Eletricidade de São Paulo S.A. Rua Tabatinguera, 164, 6º andar, Sé - São Paulo - SP - Brasil - CEP 01020-901 E-mail: eduardo.francisco@aes.com

^IIMBA em Gestão Empresarial pela Escola de Administração de Empresas de São Paulo, Fundação Getulio Vargas (FGV). Analista de Perdas do Departamento de Projeto de Pesquisas da Eletropaulo Metropolitana Eletricidade de São Paulo S.A. Rua 25 de Janeiro, 320, Luz - São Paulo - SP - Brasil - CEP 01103-000 E-mail: eduardo.fagundes@eletropaulo.com.br

^IIIDoutor em Administração pela Escola de Administração de Empresas de São Paulo da Fundação Getulio Vargas (FGV). Professor do Programa de Pós-Graduação Stricto Sensu da Escola Superior de Propaganda e Marketing (ESPM). Rua Dr. Álvaro Alvim, 123, Vila Mariana - São Paulo - SP - Brasil - CEP 04018-010 E-mail: mateus.ponchio@fgv.br

^IVDoutor em Administração pela Escola de Administração de Empresas de São Paulo da Fundação Getulio Vargas (FGV). Professor da Escola de Administração de Empresas de São Paulo da Fundação Getulio Vargas. Rua Tamandaré, 688, Liberdade - São Paulo - SP - Brasil - CEP 01525-000 E-mail: zambaldi@yahoo.com

ABSTRACT

Given the growing importance of integrating marketing and operations indicators to enhance business performance, and the availability of sophisticated geospatial statistical techniques, this paper draws on these concepts to develop an indicator of propensity to energy commercial losses. Loss management is a strategic topic among energy distribution companies, in particular for AES Eletropaulo. In such context, this work's objectives are: (i) to appropriate spatial auto-regressive models and geographically weighted regression (GWR) in measuring the cultural influence of neighborhood in customer behavior in the energy fraud act; (ii) to replace slum coverage areas by a regional social vulnerability index; and (iii) to associate energy loss with customer satisfaction indicators, in a spatial-temporal approach. Spatial regression techniques are revised, followed by a discussion on social vulnerability and customer satisfaction indicators. Operational data obtained from AES Eletropaulo's geographical information systems were combined with secondary data in order to generate predictive regression models, having energy loss as the response variable. Results show that the incorporation of market and social oriented data about customers substantially contribute to explicate energy loss - the coefficient of determination in the regression models rose from 17.76% to 63.29% when the simpler model was compared to the more complex one. Suggestions are made for future work and opportunities for the replication of the methodology in comparable contexts are discussed.

Keywords: Operations indicators; Energy distribution; Loss management; Geographically weighted regression; Social vulnerability.

RESUMO

Dada a crescente importância da integração de indicadores de marketing e operações para melhorar o desempenho empresarial e a disponibilidade de sofisticadas técnicas de estatística espacial, este trabalho desenvolve um indicador de propensão a perdas comerciais de energia. Gestão de perdas é um tema estratégico para as empresas de distribuição de energia, em particular para a AES Eletropaulo. Nesse contexto, os objetivos deste trabalho são: (i) apropriar modelos espaciais autorregressivos e a geographically weighted regression (GWR - regressão ponderada geograficamente) para medir a influência cultural da vizinhança no comportamento do cliente no ato da fraude de energia; (ii) substituir as áreas de cobertura de favela por um índice regional de vulnerabilidade social; e (iii) associar a perda de energia com indicadores de satisfação de clientes, em uma abordagem espaço-temporal. Técnicas de regressão espacial são revisadas, seguidas por uma discussão sobre a vulnerabilidade social e os indicadores de satisfação do cliente. Os dados operacionais obtidos por meio de sistemas de informação geográfica da AES Eletropaulo foram combinados com dados secundários, a fim de gerar modelos preditivos de regressão, com a perda de energia como variável resposta. Os resultados mostram que a incorporação de dados sociais e de mercado sobre os clientes contribuem substancialmente para explicar a perda de energia - o coeficiente de determinação dos modelos de regressão aumentou de 17,76% para 63,29%, quando comparados o modelo mais simples e o mais complexo. São apresentadas sugestões para trabalhos futuros e discutidas oportunidades para a replicação da metodologia em contextos comparáveis.

Palavras-chave: Indicadores de operações; Distribuição de energia; Gestão de perdas; Geographically weighted regression; Vulnerabilidade social.

1 INTRODUCTION

Every year, AES Eletropaulo, one of the most important Brazilian electricity distribution companies, fails to bill 2,388 GWh derived from non-technical losses, an amount of energy that is greater than the residential consumption of a city with a population of over 2.3 million people. According to the Brazilian Governmental Energy Agency (Agência Nacional de Energia Elétrica - Aneel), the annual commercial energy loss in the Brazilian energy distribution sector was about R$ 5 billion in 2007, approximately 13.6% of all energy produced in Brazil during that period (ANEEL, 2009).

Due to its relevance, loss management is a strategic topic among energy distribution companies. Losses can be originated by frauds, measurement anomalies, failures in internal billing processes, irregular connections, or cut-off clients directly connected to the grid. Loss management requires a joint effort for its control and for the definition of strategies that are effective to mitigate their impact on the financial results of the company.

Sophisticated statistical methods have been proposed in the operations management field of study as an alternative to traditional ones. In another context, for instance, Brito, Pignanelli and Csillag (2008) showed the benefits of multilevel modeling when compared to traditional statistical methods to investigate the relationship between quality management and financial performance. In this paper, spatial modeling and geostatistical analysis are seen as key elements in planning the development, management and operation of energy losses prevention. The effectiveness, economy and reliability depend on the correct choice of dimensions (categories of variables) used in its manipulation.

Previous studies (FRANCISCO, 2006; FRANCISCO; FAGUNDES, 2006a, 2006b; FRANCISCO et al., 2007a, 2007b) state that the consumption of electric energy is a very good proxy of household income in certain conditions; such results benefited from geospatial statistical techniques. In this paper, similar techniques will be explored to measure energy losses, understood as the difference between bought (income) and sold (outcome - sum of consumption) energy. This information exists for each Transforming Distribution Station (ETD) and its coverage area.

It is expected that the use of sophisticated techniques to support tactical and operational management will contribute for a better financial return through actions oriented towards loss reduction. Geographical analysis tools bring about this contribution, throughout diverse information levels of manipulation. The geostatistical techniques contribute with evaluation and quantification of geographical influence of this phenomenon.

This paper is organized as follows: in the next section, the objectives are presented, followed by a brief presentation of the main concepts dealt with; the methodology is then described. Subsequently, the results are depicted and, in the last section, concluding remarks are offered.

2 OBJECTIVES

In 2006, AES Eletropaulo created the CLPI - Commercial Losses Potential Indicator (FRANCISCO; FAGUNDES, 2006a, 2006b; FRANCISCO et al., 2007a), which integrates information of energy loss rate, average of residential electricity consumption, rate of cut-off customers and areas occupied by slums. This index has been used to refine inspection action priority, and serves as a source for demographic and behavioral clusters (decision tree analyses) for commercial losses, strategic support for metering maintenance and replacement process.

The CLPI, however, does not take into account customer satisfaction indicators or social vulnerability data. Customer satisfaction indicators have a fundamental importance for AES Eletropaulo's strategy to achieve the position of best Brazilian energy distribution company. For instance, a set of customer satisfaction indicators computed by Association of Brazilian Power Distribution Companies (Associação Brasileira de Distribuidores de Energia Elétrica - Abradee, 2009) account for one quarter of the global evaluation of Brazilian electric energy distribution companies that are elected to receive a performance award (the Abradee's Prize). Social responsibility governance, on the other hand, gained strategic importance for energy companies in the last three years. The knowledge about the "bottom of pyramid" customers is a subsidy for actions related to income generation, citizenship, illegal connections and efficient use of energy.

It has been suggested that manufacturing and marketing integration and managerial priorities influence positively business performance (PAIVA, 2008). In this context, the objectives of this paper are to improve the CLPI in three perspectives:

3 CONCEPTS REVIEW

In this section, spatial regression techniques are revised, followed by a discussion on social vulnerability and customer satisfaction indicators.

3.1 SPATIAL REGRESSION TECHNIQUES

Nowadays, it is very common to analyze "spatially enabled" data. The motivation has come from several disciplines, including the universe of marketing and social sciences, and the subsequent improvements that spatial statistics allow in the interpretation, measurement of relationships, and prediction. As pointed out by Bradlow et al. (2005), by generalizing the notion of a map to include demographic and psychometric representations, spatial models can capture a variety of effects (spatial lags, spatial autocorrelation, and spatial drift) that affect firm or consumer decision behavior.

In a traditional linear regression, we assume that the relationship modeled holds everywhere in the study area, that is, the regression parameters are considered "whole-map" statistics. In many situations, this is not correct, as mapping residuals may reveal. An alternative to incorporate spatial effects in econometric models, according to Griffith (1987), is to specify an auto-regressive model with the dependent's variable autocorrelation as a statistic parameter; the rational is to include a spatial lag in the regression as an independent variable calculated by means of a matrix containing the distances among the different regions as coefficients of contiguity (ANSELIN, 1988). That option is the basis for what is known as spatial auto regression (SAR) techniques.

Alternatively, and motivated by computational development, geographically weighted regression (GWR), a term introduced by Fotheringham, Brunsdon, and Charlton (2002) to describe a family of regression models in which the coefficients β are allowed to vary spatially, also takes advantage of data from locations near the focal location as they are informative about the relationship between the independent and dependent variables in the focal location. When calculating the estimates for a focal location, GWR gives more weight to data from locations that are closer to it than to those that are distant (MITTAL; KAMAKURA; GOVIND, 2004). What makes GWR different from SAR techniques, however, is the fact that GWR permits parameter estimates to vary locally; regression coefficients are determined by examining the set of points within a well-defined neighborhood of each point, using a weighting scheme (normally, bi-square or Gaussian).

A bandwidth that defines the neighborhood is the key factor; it may be defined manually or alternatively by some form of adaptive method such as the minimization of the Akaike Information Criterion (AIC) (FOTHERINGHAM; BRUNSDON; CHARLTON, 2002; SMITH; GOODCHILD; LONGLEY, 2007).

3.2 SOCIAL VULNERABILITY

In this work social vulnerability is understood as being "the limited capacity of individuals or groups to respond to risks or contingencies and the consequent predisposition to a decrease in well-being" (FILGUEIRA; PERI, 2004, p. 21, translated by the authors). This definition is coherent with others, such as that of Kaztman (1999) and of State Data Analysis System Foundation (Sistema Estadual de Análise de Dados - Seade, 2004).

In a study to characterize the social vulnerability situation in different regions in the State of São Paulo, in addition to the socio-economic variables of income and educational level that are classically used in similar works, Seade (2004) used variables that indicate the family life cycle (such as the presence of small children, adolescents, female family heads or young family heads in households) and housing conditions (households with urban services such as being connected to the water and sewage networks and trash collection). This study (Seade, 2004) gave rise to the Paulista Index of Social Vulnerability - IPVS, presented in the following section.

3.2.1 The Paulista Index of Social Vulnerability - IPVS

The objective of Seade's (2004) study was to allocate social vulnerability marks to each of the sectors in the census that comprise the State of São Paulo.

Starting with the database taken from the Demographic Census (Instituto Brasileiro de Geografia - IBGE, 2000) of people living in the State of São Paulo, they used factor analysis procedures with the aim of exploring the underlying structures in the universe of variables studied. The analyses revealed two factors, called socio-economic and family life cycle (Seade, 2004):

Once the factors had been identified, by means of cluster analysis they tried to identify sectors in the census that had similar profiles in terms of socio-economic conditions and family life cycle (factors 1 and 2). At the end of the analysis they generated a typology with six different groups of sectors that had taken part in the census. This typology is called the Paulista Index of Social Vulnerability - IPVS. ^{Exhibit 1} shows the groups that form the IPVS.

The granular unit of Seade's study was the sector that had taken part in the census. Specifically for the city of São Paulo, the resulting social vulnerability map was as follows.

This result is extremely rich in information, both for public policy purposes as well as for marketing purposes. In this work, information regarding social vulnerability among AES Eletropaulo's customers will be utilized in order to enhance the accuracy of an energy loss estimator.

3.3 ABRADEE'S CUSTOMER SATISFACTION SURVEY

Abradee coordinates the Abradee's Survey of Residential Customer Satisfaction every year since 1999, applied simultaneously for many distribution companies (40 in 2004, 43 in 2005, 48 in 2006, 44 in 2007, 40 in 2008) (Abradee, 2005, 2007, 2008). Its main objective is to evaluate customer satisfaction by measuring service quality perceived attributes. It also allows the ranking of companies per category.

It is a household survey, based on a stratified probabilistic sample (per municipality, district and census sector), which guarantees the representativeness of the distribution companies population. In addition, interviews are made for selected households, with the target person being the head of family (Abradee, 2003).

Forty-three attributes of perceived quality and price are collected, grouped in eight areas (Idars): energy supply; information and communication; energy bill; customer care; image; price; public lighting; and social responsibility. The average of the five first quality areas, weighted by customer declared importance of each area, originates the ISQP (Perceived Quality Satisfaction Indicator), the main index of that survey. In addition, two general satisfaction indexes (IAC and ISG), and some demographic aspects are collected: household income, head of family's age and educational level, monthly billed electricity consumption of the household and some others (Abradee, 2008).

After the survey period, a database with all variables for all respondents is published by Abradee for each distribution company. The most detailed location information of the household collected in the interview is the district where the household is located (addresses, postal codes or census sectors were not supplied) (FRANCISCO; WHIGHAM; MOORE, 2007). It allows the generation of indexes by district and municipality, besides regional indicators commonly published, as illustrated by Figure 2.

The Abradee's survey conducted in the city of São Paulo in 2008 had 1,200 respondents, spread in 75 districts of São Paulo and other 23 municipalities. We considered, in an exploratory way, the following indicators for this study: ISQP, the five ISQP's Idars, IAC, ISG and the particular attribute "satisfaction with concessionary acting on fraud combat".

4 METHODOLOGY

Understanding the spatial distribution of data derived from phenomena occurring over a certain geographical area constitutes a challenge for the clarification of core issues in several areas of public and corporate administration, such as health, urban dynamics, environment, marketing and asset management. Such studies have become increasingly more common, due to the availability of Geographical Information Systems (GIS), and also due to the need for clarification of the spatial distribution of common problems and socio-economical interaction variables that the traditional and classical models usually do not address. Geostatistics is a field of regional science that approaches the theme of dependence and spatial heterogeneity, critical aspects in any study on regional economy. These characteristics can invalidate the use of conventional econometric techniques. Spatial quantitative methods are a special case of overall statistical focus and, therefore, require a set of different methods and techniques than those utilized in conventional statistics. Companies that have geographical information as essential to their business benefit from the application of those techniques.

In this section, we present the SAR and GWR techniques which were applied in the study and their characteristics, comparing them to the use of OLS (ordinary least square) techniques. Then, we demonstrate the process employed to improve an indicator of electricity commercial losses to be explained by means of the applied regressions.

4.1 REGRESSION TECHNIQUES APPLIED IN THIS STUDY

Two geostatistics techniques used were: spatial auto-regression (SAR) and geographically weighted regression (GWR). They are exploratory techniques for spatial data analysis.

The SAR technique remount to the 1950s and is traditionally used in spatial statistics (SMITH; GOODCHILD; LONGLEY, 2007). Spatial auto-regressive (SAR) models usually adopt neighborhood matrices (W) with distance weights (and the same dependent term y to estimate y, in an auto-regressive ρWy term), which are internally based on the distance between the points or the centroids of the polygons involved in the predicting model. Equations 1 (multivariate linear regression, or ordinary least square regression) and 2 (SAR) show how the auto-regressive term is incorporated.

where y is the dependent variable; X is the vector of independent variables; β is the vector of coefficients and ε is the estimation error (allegedly normal).

Geographically weighted regression (GWR) was introduced by Fotheringham, Brunsdon and Charlton (2002) to describe a family of regression models in which the coefficients, β, are allowed to vary spatially.

In a traditional linear regression we assume that the relationship we are modeling holds everywhere in the study area - that is, the regression parameters are "whole-map" statistics (it is also valid for SAR). In many situations this is not necessarily the case, as mapping the residuals (the difference between the observed and predicted data) may reveal. Many different solutions have been proposed for dealing with spatial variation in the relationship. GWR provides an easily grasped means of modeling such relationships, with local variations of β coefficients, as shown in Equation 3.

where y, X, β and ε are as in equations (1) and (2), and g indicates that the parameters are to be estimated at a location (point) whose coordinates are given by the vector g (sample point or zone centroid).

The coefficients β(g) are determined by examining the set of points within a well-defined neighborhood of each of the sample points, using a weighting scheme (normally, bi-square or Gaussian). The bandwidth that defines the neighborhood is the key factor; it may be defined manually or alternatively by some form of adaptive method such as the minimization of the Akaike Information Criterion (AIC) (FOTHERINGHAM; BRUNSDON; CHARLTON, 2002; FRANCISCO; WHIGHAM; MOORE, 2007; SMITH; GOODCHILD; LONGLEY, 2007).

Figure 3 shows the differences between the three techniques of regressions applied respectively to the equations (1), (2) and (3).

4.2 IMPROVEMENT OF COMMERCIAL LOSSES POTENTIAL INDICATOR

For each geographical region under study, four basic pieces of information are integrated: (i) percentage of power (or energy) loss (total); (ii) average household income (through the proxy average of residential energy consumption); (iii) IPVS (indicator of social vulnerability); and (iv) percentage of cut-off clients. Figure 4 schematizes the four constructs involved in the creation of this energy loss indicator.

Figure 5 brings a summary of the steps of the creation of this indicator.

The methodology consisted, basically, of the following steps:

4.3 PREDICTIVE MODELS OF ENERGY LOSSES

Figure 6 describes the independent variables (X) used in the explanation of Energy Loss (y) variability. The improvement of the original model, created in 2006 (FRANCISCO; FAGUNDES, 2006b; FRANCISCO; WHIGHAM; MOORE, 2007), is in the substitution of slum coverage areas by IPVS and also in the incorporation of perceived quality indicators (attributes and general indexes) obtained from the ABRADEE's Customer Satisfaction Survey.

The traditional and spatial regression techniques were applied in an exploratory manner for the whole AES Eletropaulo coverage area and for the city of São Paulo, according to availability of information of explanatory variables.

5 RESULTS

The use of ABRADEE's Survey indicators was initiated with the investigation of direct association (simple and spatial) between customer satisfaction and energy loss. In such a context, we decompose (weighted per area) energy losses values for each sampled municipality and district.

Table 1 shows results for diverse tested models. Association is relatively high considering GWR technique, highlighting ISQP and information and communication quality area (Idar).

In a complimentary perspective, in order to promote energy consumption to a social indicator (not only an economic indicator, according to previous studies by FRANCISCO; FAGUNDES, 2006a, 2006b; FRANCISCO; WHIGHAM; MOORE, 2007), we applied regression techniques to analyze IPVS variability from consumption, for all 13,278 census sectors of São Paulo municipality (IBGE, 2004). Results are shown in Figure 7.

Results highlight an expressive and important improvement of explanation power (R²) of IPVS from electric energy consumption. About 60% of the social vulnerability in São Paulo municipality can be explained by electricity habits. Moran's I results (a standard spatial correlation indicator) show a significant auto-correlation between the two constructs that validates the spatial variability model applied and promotes energy consumption as an economic and social indicator.

Figure 8 shows 3D maps of spatial distribution of ISQP (satisfaction average, in a 1-10 scale) and IPVS in São Paulo municipality.

In the main result set of analyses, spatial overlay of four constructs (see Figure 6), and Abradee's survey indicators, originates a geographic layer with 41,277 polygons. Table 2 compares results from the original project (FRANCISCO; FAGUNDES, 2006a, 2006b; FRANCISCO; WHIGHAM; MOORE, 2007) with findings of this analysis (considering IPVS and customer satisfaction indexes).

The 2006 model (FRANCISCO; FAGUNDES, 2006a, 2006b) had a 32.1% explanation power (R²) considering SAR technique. Improving it with GWR technique, IPVS and ISQP customer satisfaction indexes, R² increased to about 60%, which increases the importance of this indicator and raises the condition for these analyses to a socio-economical and demographic perspective in fact (FRANCISCO et al., 2007a). The strong association between IPVS and energy consumption and between energy loss and ISQP (Table 1) corroborate this finding.

6 CONCLUDING REMARKS

Developed in 2006 for the whole concession area of AES Eletropaulo, the Commercial Losses Potential Indicator already effectively contributed for definition of strategies in some processes and projects of the company. Such support takes place vis-à-vis at each source of loss detected, such as: combat to frauds only at connected clients and in certain geographical areas, regularization of illegal nuclei, recovery of cut-off clients through commercial strategies, and it may help in the better orientation of future installations of anti-fraud grids and specific equipment, among other strategies.

Since the information utilized is internal and under AES Eletropaulo management, this methodology can be easily implemented and maintained. The innovation is in the integration of technical information, heterogeneous and no-integrated at first, such as total loss per transforming distribution station, and commercial information, such as average billed power consumption and the status (cut-off versus non-cut-off) of each consumer unit. Such integration is enabled by geographic information systems, and the generation of the indicator is made by the determination of geostatistical techniques, still of very limited application, and thus, pioneer in the power distribution industry. Actually, the incorporation of geographic data was proven to improve electricity loss detection, because it allowed for the quantification of contextual local effects, which are relevant to the field of operations management due to the existence of regional interdependence among the studied phenomenon.

Results show this innovation is primordial for establishing better performance in energy loss reduction and for supporting social responsibility and cultural programs. AES Eletropaulo diminished its commercial loss in 0.8 percentage points from 2007 to 2008's first quarters.

Additionally, the inclusion of socio-demographic indicators by means of a vulnerability index in substitution of the rough information about the local presence of slums was revealed to improve the explanation for electricity losses. In fact, the association found between vulnerability, electricity consumption and energy loss suggest that electricity consumption and fraud are not only economic phenomena, but also socially determined. That may reinforce the need for special policies, both from the public and the private sector, to foster customer's welfare and reduction of fraud levels by means of regionally driven initiatives.

Coherently, the inclusion of an attitudinal indicator of satisfaction to explain losses also proved to be significant. In such a context, distributors can be motivated to face satisfaction not only as means to attract and retain customers, but also do reduce loss. Based on the findings of this study, loss can be considered to have social and market dimensions and processes to prevent it incorporate complementary operational and marketing orientations.

In summary, this project aims to establish a geostatistical methodology for the identification of areas with greater potential energy losses (reducing operational costs), and to highlight the statistical relationship between socio-economical variables and energy losses, especially considering poverty indicators. Spatial modeling and geostatistical analysis are key elements for it. The incorporation of customer satisfaction indicators, based on an important survey, raised the condition of analysis to a new level: the one which considers cultural and socio-economic aspects.

As an opportunity, distributors may develop knowhow and data in order to improve their operational tactics for fraud prevention and market penetration, and even offer those skills to other sectors. However, the specificity of data required in this study may imply that this analysis is costly to reproduce. Also, the use of more granular data would result in more precise estimates than the current application with regionally aggregated data. However, with suitable adjustments regarding data availability, there is opportunity to expand this study to costly efficient designs and broader contexts. Hence this work is both novel and new in the energy distribution industry, and should be improved and incorporated in a larger set of optimization processes and in similar service and utility companies.

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