The pricing of anomalies using factor models: a test in Latin American markets

Carvalho, Gabriel Augusto de; Amaral, Hudson Fernandes; Pinheiro, Juliano Lima; Correia, Laíse Ferraz

doi:10.1590/1808-057x202111640

ABSTRACT

This article aimed to test the five-factor model in Latin American emerging markets. In order to verify which set of factors best fits the data, the three- and four-factor models were also estimated. Asset pricing models have been proposed within the context of developed markets, with few empirical tests of these models performed based on emerging markets’ data. This study is based on the differences between the markets of developed and emerging countries, which affect the models’ predictive power and, thus, the investors’ decision-making process. The study also provides evidence that contributes to a more assertive decision-making by all financial market players. In addition, the study results suggest an opportunity to carry out tests with the inclusion of new factors in the models. The study sample included assets listed on stock exchanges in Brazil, Chile, Colombia, Mexico and Peru between June 1999 and June 2017. The building of the factors was based on the return differential between portfolios formed based on the characteristics of the assets, and the models were estimated using the two-step regression methodology. The results for the first- and second-step regressions indicated that the five-factor model had the best predictive power. However, in the second-step estimation, none of the models was able to fully explain the returns on the portfolios. Our conclusion is that the five-factor model showed the best performance for the sample, although there may be other relevant factors that could be incorporated into it. The main contribution of this article lies in the better knowledge it provides of the relevant factors for the asset pricing in emerging markets.

Keywords:
asset pricing; factor models; pricing factors; emerging markets; Latin America

Resumo

Este artigo objetivou testar o modelo de cinco fatores nos mercados emergentes da América Latina. Para verificar qual composição de fatores melhor se ajusta aos dados, também foram estimados os modelos de três e quatro fatores. Os modelos de precificação de ativos foram propostos no contexto de mercados desenvolvidos, sendo restrito o número de testes empíricos desses modelos a partir de dados de mercados emergentes. Esta pesquisa sustenta-se nas diferenças existentes entre os mercados dos países desenvolvidos e emergentes, que afetam o poder preditivo dos modelos e, assim, o processo de tomada de decisão dos investidores. A pesquisa ainda fornece evidências que contribuem para uma tomada de decisão mais assertiva para os diferentes atores do mercado financeiro. Além disso, é indicada a oportunidade para realizar testes com a inclusão de novos fatores nos modelos. Foi considerada uma amostra de ativos listados nas bolsas de valores do Brasil, Chile, Colômbia, México e Peru entre junho de 1999 e junho de 2017. A construção dos fatores baseou-se no diferencial de retorno entre portfólios formados a partir das características dos ativos, sendo a estimação dos modelos realizada por meio da metodologia de regressão em dois passos. Os resultados das regressões do primeiro e do segundo passo indicaram que o modelo de cinco fatores apresentou o melhor poder preditivo. Porém, na estimação do segundo passo, nenhum dos modelos foi capaz de explicar completamente os retornos dos portfólios. Ou seja, o modelo de cinco fatores foi o que apresentou o melhor ajuste à amostra, embora possa haver fatores relevantes não incorporados em sua especificação. A principal contribuição deste artigo reside no melhor conhecimento sobre os fatores relevantes para a precificação de ativos em mercados emergentes.

Palavras-chave:
precificação de ativos; modelos fatoriais; fatores de precificação; mercados emergentes; América Latina

1. INTRODUCTION

Studies on asset pricing seek to identify the relevant factors to the return generating process, thus achieving a better understanding of investors’ decision-making and, consequently, of the behavior of asset prices. The Capital Asset Pricing Model (CAPM), based on the works of Sharpe (1964Sharpe, W. F. (1964). Capital asset prices: a theory of market equilibrium under conditions of risk. Journal of Finance, 19(3), 425-443.), Lintner (1965Lintner, J. (1965). The valuation of risk assets and the selection of risk investments in stock portfolios and capital budgets. Review of Economics and Statistics, 47(1), 13-37.) and Mossin (1966Mossin, J. (1966). Equilibrium in a capital asset market. Econometrica, 34(4), 768-783.), is a single factor model that describes the asset’s expected return according to its level of systematic risk.

As Fama and French (2004Fama, E., & French, K. (2004). The capital asset pricing model: theory and evidence. Journal of Economic Perspectives, 18(3), 25-46.) point out, the empirical evidences of the CAPM is poor and, therefore, theoretical and empirical factor models have been proprosed. Merton (1973Merton, R. C. (1973). An intertemporal capital asset pricing model. Econometrica, 41(5), 867-887.) proposed the Intertemporal Capital Asset Pricing Model (ICAPM), a model in which the return generating process is explained through several factors. And, working under the main assumption of the absence of market arbitrage opportunities, Ross (1976Ross, S. (1976). The arbitrage theory of capital asset pricing. Journal of Economic Theory, 13(3), 341-360.) developed the Arbitrage Pricing Theory (APT) as an alternative approach to explain the return generating process, which also assumes that several factors can be used to describe assets’ returns. These models were used in several empirical tests of the return generating process to analyze the process of pricing anomalies observed in the markets. Among these models, the three-factor model by Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.), the four-factor model by Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) and the five-factor model by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) stand out.

As pointed out by Cakici, Fabozzi and Tan (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.) and Leite, Klotzle, Pinto and Silva (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.), most of the studies on asset pricing were conducted in developed markets, and despite the increasing importance of emerging countries’ capital markets, there are few models capable of adequately explaining the return generating process in emerging markets. Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) characterize emerging markets by the lower quality of available data, political and institutional instability and greater vulnerability to speculative capital. Harvey (1995Harvey, C. R. (1995). Predictable risk and returns in emerging markets. Review of Financial Studies, 8(3), 773-816.) points out that the exposure of assets traded in emerging markets to the pricing factors commonly used in the literature is low. Such aspects can affect the rationality of the investors’ decision making and also the ability of pricing models to describe assets’ returns in these markets.

Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.), Cakici, Tang and Yan (2016), Zaremba and Czapkiewicz (2017Zaremba, A., & Czapkiewicz, A. (2017). Digesting anomalies in emerging European markets: a comparison of factor pricing models. Emerging Markets Review, 31, 1-15.), Foye (2018Foye, J. (2018). A comprehensive test of the Fama-French five-factor model in emerging markets. Emerging Markets Review, 37, 199-222.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) are examples of studies that, in developing empirical tests of asset pricing models, used samples of assets traded in emerging markets. The results of these studies pointed, in general, to a low predictive power of models for emerging markets, and also found evidence of market segmentation in relation to developed economies.

Latin America is characterized by a variety of emerging markets among the countries that comprise it. Morgan Stanley Capital International (MSCI) included five markets in the region in the composition of its Emerging Markets Index for August 2018, namely: Brazil, Chile, Colombia, Mexico and Peru. According to data from the World Federation of Exchanges (WFE), in August 2018 more than 1000 companies were listed in these five countries’ markets, totaling a market capitalization of more than US$1.7 trillion.

All this shows there is an opportunity to contribute to the literature on the theme of asset pricing in emerging economies. Thus, the main objective of this article was to test the five-factor model of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) in the context of the main Latin American emerging markets. As this model is an evolution of the three-factor model of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.), on which Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) based his four-factor model, these two models were also estimated in our research. That is, we sought to assess the combination of factors that best explains the asset returns in the sample.

As a practical contribution of our study, we expect our findings to reveal the main relevant factors and allow market investors, company managers and capital markets regulators a more confident decision-making process. The study’s contribution to the specialized literature is mainly focused on providing new evidence on pricing anomalies in emerging markets.

In addition to this introduction, this article has four other sections. The second section presents a general review of the literature on asset pricing theory and some empirical tests developed in emerging markets. The third section describes the methodological procedures used in our study. Our results are presented and analyzed in the fourth section. Finally, the last section provides comments on our objectives and presents our final considerations.

2. THEORETICAL FRAMEWORK

2.1 Capital Asset Pricing

The CAPM of Sharpe (1964Sharpe, W. F. (1964). Capital asset prices: a theory of market equilibrium under conditions of risk. Journal of Finance, 19(3), 425-443.), Lintner (1965Lintner, J. (1965). The valuation of risk assets and the selection of risk investments in stock portfolios and capital budgets. Review of Economics and Statistics, 47(1), 13-37.) and Mossin (1966Mossin, J. (1966). Equilibrium in a capital asset market. Econometrica, 34(4), 768-783.) describe the asset pricing under risk. According to this model, the return on an asset is given by the return on risk-free assets plus a premium for the asset's market risk. To measure market risk, CAPM uses the beta coefficient, which measures the sensitivity of the asset's return to the variance of the market return. This model is therefore characterized by a linear relationship between risk and return, with the presence of a single factor: the beta coefficient.

Ross (1976Ross, S. (1976). The arbitrage theory of capital asset pricing. Journal of Economic Theory, 13(3), 341-360.) proposed the Arbitrage Pricing Theory (APT) as an alternative approach to asset pricing, which allows some CAPM's assumptions to be relaxed. Based on the law of one price, APT assumes the impossibility of obtaining arbitrage profits - differences between prices, which allow profits to be obtained without risk, are immediately eliminated - assumes homogeneous expectations and considers the need for a large number of available assets, which makes the non-systematic risk of a diversified portfolio negligible.

This new approach suggests the existence of other factors capable of explaining the return generating process of assets. That is, APT assumes that returns are described by a multi-factor model. In line with this proposition, Fama and French (1992Fama, E., & French, K. (1992). The cross-section of expected stock returns. Journal of Finance, 47(2), 427-465.) showed that CAPM’s explanatory power increases with the inclusion of other sources of risk in the model and, thus, corroborated the multidimensional nature of systemic risk.

Since then, different anomalies have been tested in the development of multi-factor asset pricing models. Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) proposed a model that incorporates, in addition to market return, factors related to firm size and book-to-market ratio. The model was thus composed of three factors, namely: the premium for the market factor, measured by the excess return on the market portfolio; the small minus big factor (SMB), measured by the difference in return between portfolios composed of smaller and larger market capitalization companies; and the high minus low factor (HML), measured by the return differential between portfolios composed by companies with the highest and the lowest book-to-market ratios.

Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) proposed the addition of the momentum factor as an explanatory variable for asset returns to the three-factor model by Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.), thus developing a four-factor model. To build the winners minus losers (WML) factor, Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) measured by the differential return between portfolios of the winners and losers stocks.

Based on the empirical evidence from studies carried out in the 2000s - such as those by Fama and French (2006Fama, E., & French, K. (2006). Profitability, investment and average returns. Journal of Financial Economics, 82(3), 491-518., 2008Fama, E., & French, K. (2008). Dissecting anomalies. Journal of Finance, 63(4), 1653-1678.), Titman, Wei and Xie (2004Titman, S. K. C., Wei, J., & Xie, F. (2004). Capital investments and stock returns. Journal of Financial and Quantitative Analysis, 39(4), 677-700.) and Novy and Marx (2013Novy-Marx, R. (2013). The other side of value: The gross profitability premium. Journal of Financial Economics, 108(1), 1-28.) - Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) verified that investment and profitability anomalies are left unexplained by the three-factor model. In view of this evidence, Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) proposed the five-factor model, which consisted of the addition of robust minus weak (RMW) - difference in returns between portfolios formed by high and low profitability stocks - and conservative minus aggressive (CMA) - difference between the returns on portfolios composed of low- and high-investment stocks - to the three-factor model.

2.1.1 Assets pricing in emerging markets

Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) and Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56., 2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) developed their models based on empirical tests carried out with North American market data. However, it should be taken into account that the particularities of emerging markets can affect investors' decision-making and, consequently, the predictive power of pricing factors. Thus, an increasing number of studies have been focusing on the development of empirical tests of pricing models based on data from emerging countries.

In a pioneering study, Harvey (1995Harvey, C. R. (1995). Predictable risk and returns in emerging markets. Review of Financial Studies, 8(3), 773-816.) researches asset pricing in a sample composed of 800 stocks from 20 emerging markets. The author tests a global version of the CAPM and his results indicate that the model is not capable of explaining the returns on assets in emerging markets. As a result, it is pointed out that emerging markets are not fully integrated into the world capital markets, and that there are other systematic risk factors that affect asset pricing in those markets.

Similarly, later studies have also compared the performance of models that consider global factors with versions that include factors based on emerging markets data. Authors such as Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.), Hanauer and Linhart (2015Hanauer, M. X., & Linhart, M. (2015). Size, value, and momentum in emerging market stock returns: integrated or segmented pricing? Asia-Pacific Journal of Financial Studies, 44, 175-214.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) used this strategy in their studies and pointed out that, compared with models using global factors, models based on local factors showed a greater predictive power, which is evidence of segmentation of emerging markets from developed markets, as pointed out by Harvey (1995Harvey, C. R. (1995). Predictable risk and returns in emerging markets. Review of Financial Studies, 8(3), 773-816.).

In addition to the segmentation of developed and emerging markets, studies including emerging markets in their samples also look into other aspects. Authors such as Cakici et al. (2016Cakici, N., Tang, Y., & Yan, A. (2016). Do the size, value, and momentum factors drive stock returns in emerging markets? Journal of International Money and Finance, 69, 179-204.), Foye (2018Foye, J. (2018). A comprehensive test of the Fama-French five-factor model in emerging markets. Emerging Markets Review, 37, 199-222.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) observed differing behaviors in average factor returns between: (i) different emerging markets; and (ii) emerging and developed markets. This pattern of differing results across different markets was also observed by the authors in the statistical significance analysis of pricing factors.

The characteristics and patterns observed in assets traded in emerging markets have theoretical and practical implications. As Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) points out, pricing models generally perform poorly in explaining the asset returns in emerging countries compared with results for developed countries. For the investor, these emerging markets’ characteristics may present an opportunity. As pointed out by Harvey (1995Harvey, C. R. (1995). Predictable risk and returns in emerging markets. Review of Financial Studies, 8(3), 773-816.), a global investor, by allocating part of its resources in emerging markets, can benefit from a greater diversification in its portfolio.

Table 1 below presents a summary with some of the main recent studies on asset pricing prepared with emerging markets’ data.

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Table 1
Empirical studies on asset pricing using samples from emerging markets

These studies’ findings provide further evidence of the relevance of the subject of asset pricing in emerging markets. The results of Foye (2018Foye, J. (2018). A comprehensive test of the Fama-French five-factor model in emerging markets. Emerging Markets Review, 37, 199-222.) stand out in suggesting divergences in the models’ predictive power for the different regions studied. Hence the pertinence of carrying out further studies on this theme, while also taking into account these markets’ regional peculiarities.

3. METHODS

3.1 Population and Sample

This study population consisted of all the stocks listed on the stock exchanges of Latin American emerging markets between June 1, 1999 and June 30, 2017. The countries included in the sample were selected based on the MSCI Emerging Markets Latin America Index for August 2018, which included the markets of Brazil, Chile, Colombia, Mexico and Peru.

In the sampling process, we initially excluded stocks of financial firms. As pointed out by Fama and French (1992Fama, E., & French, K. (1992). The cross-section of expected stock returns. Journal of Finance, 47(2), 427-465.), the high leverage of these firms does not mean the same for firms in other sectors. Then, given the data limitation for many stocks that remained in the sample, only companies for which the information described below were available in the database were considered in each year studied:

a) Positive equity and market value as of December 31 of the previous year, with a tolerance of minus 30 days for the second variable;
b) Total assets as of December 31 of the two years preceding the portfolio formation;
c) Operating profit as of December 31 of the year before the portfolio formation;
d) Market value as of June 30, with a tolerance of minus 30 days;
e) Stocks that had consecutive monthly trades and at least one trade per month, for the period of 12 months before and after the date of portfolio formation.

Table 2 shows the annual sample composition, segregated by the different markets considered in the study. Note the relevance of the Brazilian market compared with the other markets in the region, which is due to the greater number of assets that meet the study criteria established. At the other extreme is Colombia, the market with the lowest number of assets in the overall sample.

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Table 2
Sample composition

After selecting the markets to be studied and, based on them, the final study sample, the data necessary for developing the estimated models were collected on the Bloomberg financial information platform. As this study included markets in different countries, all monetary values were converted into US dollars to enable comparisons.

3.2 Econometric Models Estimated

The model testing procedure was structured in two steps, according to the methodology of Fama and MacBeth (1973Fama, E., & MacBeth, J. (1973). Risk, return and equilibrium: empirical tests. Journal of Political Economy, 81(3), 607-636.). Table 3 shows the econometric models estimated in the first step (time series regressions), which were estimated to obtain the slope coefficients (β_i, s_i, h_i, w_i, r_i, c_i).

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Table 3
Econometric models used in the first step

These slope coefficients were then used as explanatory variables for the cross-section regression models estimated in the second step, which were used to test the statistical significance of the factors linked to them. Table 4 shows the econometric models estimated in the second step.

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Table 4
Econometric models estimated in the second step

Below we detail the methods used to build the portfolios and calculate their returns (dependent variables of the first- and second-step models); as well as the methods for building the factors used as independent variables in the first-step models. The procedures used in the building of factors, estimation of models and statistical tests were performed using Python and R programming languages.

3.2.1 Independent variables

We adopted a strategy similar to that of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56., 2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) for building the factors and formed the study portfolios based on the sample stocks’ characteristics. This involved initially ranking the stocks from small to big market capitalization - obtained by multiplying the stock price by the number of stocks outstanding - which were then divided into two groups by the median. As a result, a Small (S) and a Big (B) group were created, the former consisting of stocks with market capitalization below the median of the sample's market value and the latter consisting of stocks with market capitalization above that value.

The stocks composing the two groups formed by size were ranked again independently, according to the values for the other study variables, and then divided into groups based on the 30th and 70th percentiles. For the book-to-market ratio - obtained by the ratio between equity and market value - the High (H), Neutral (N) and Low (L) portfolios were formed, which were used to build the HML factor. For the momentum variable (cumulative stock return between months t-12 and t-2), the groups Winner (Win), Neutral (N) and Loser (Los) were formed, which were used to build the WML factor.

Finally, for the factors added by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), the Robust (R), Neutral (N) and Weak (W) groups were formed for profitability (ratio between operating profit and equity), and the Conservative (C), Neutral (N) and Agressive (A) groups were formed for investment (growth of the firm’s total assets between the years t-1 and t), which were used to build the RMW and CMA factors, respectively.

After performing this procedure, six portfolios were obtained for each variable used in the second ranking; and then the monthly returns on each portfolio were calculated. To obtain the portfolio returns, we used the individual monthly log returns on the stocks weighted by the market value of each asset in relation to the portfolio’s total market value. The portfolio formation procedure was performed again every June of the sample period (2000 to 2017) in order to allow new information to be incorporated into the portfolios’ composition.

Table 5 details the procedure used to build the factors. Our methodology followed that of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56., 2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), using the difference between the average returns on different portfolio groups. It is also worth mentioning that, as in Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) and Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.), the SMB factor used in the estimation of the three- and four-factor models was composed only by the SMB_B/M factor.

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Table 5
Building of the factors

In addition to the factors mentioned above, the first-step models also incorporate the market risk premium, obtained by the difference between the monthly return on the market proxy portfolio and the return on the risk-free asset. For the market portfolio, we considered monthly returns, weighted by the monthly market value, on a portfolio composed of all stocks in the sample in each year of the study period. For the risk-free interest rate, the one-month US Treasury bill rate was considered. We opted to use this rate because it was necessary to assume that the risk-free asset had a zero probability of default. In this way, the high sovereign rating of the United States and the fact that US rates are independent of our study sample markets make the one-month Treasury bill rate an adequate proxy to the risk-free interest rate.

3.2.2 Dependent variables

To test the explanatory power of the estimated models, we formed portfolios based on the characteristics of the sample's assets. The strategy adopted in the formation of these portfolios was similar to that of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), with a double ranking of assets and three sets of portfolios formed to estimate the models tested in the study.

In the formation of portfolios, the stocks were initially ordered by size and separated into quintiles. Next, these quintiles were ordered by a second variable, namely: book-to-market, investment and profitability; and then divided again into quintiles.

This process generated 25 portfolios for each of the three variables considered in the second classification. In other words, 75 portfolios were formed. The number of stocks comprising these portfolios ranged from a minimum of 10 to a maximum of 19, with an average of 14.77 stocks. The dependent variables of the first-step models were then represented by the excess return on these portfolios in relation to the risk-free interest rate. To calculate the portfolio returns, we used the log returns of the stocks weighted by their market value in relation to the portfolio’s total market value. For the second-step models, the dependent variable was represented by the average of the excess return on each of these 75 portfolios over the sample period.

3.3 Validation and Robustness Tests of the Models

An important step in studies involving the estimation of econometric models is carrying out diagnostic tests of their underlying assumptions to verify their validity. Thus, in the models estimated in the second step of the Fama and MacBeth (1973Fama, E., & MacBeth, J. (1973). Risk, return and equilibrium: empirical tests. Journal of Political Economy, 81(3), 607-636.) methodology, which we applied in this study, the presence of the following problems were verified: (i) multicollinearity, using the Variance Inflation Factor (VIF) test; (ii) heteroscedasticity, using the Breusch-Pagan test; (iii) autocorrelation, through the Durbin-Watson test.

In addition to the problems assessed by the tests described above, Collot and Hemauer (2020Collot, S., & Hemauer, T. (2020). A literature review of new methods in empirical asset pricing: omitted-variable and errors-in-variable bias. Financial Markets and Portfolio Management.) point out that the use of the coefficients obtained in first-step regressions as explanatory variables in second-step regressions makes the models susceptible to bias due to measurement errors in the first-step regressions. Thus, the second-step regressions were estimated using both the Ordinary Least Squares Method (OLS) and the Generalized Method of Moments (GMM). The Hausman specification test was then used to assess the consistency of the OLS estimator.

Furthermore, we used the Gibbons, Ross and Shanken (1989Gibbons, M., Ross, S., & Shanken, J. (1989). A test of the efficiency of a given portfolio. Econometrica, 57(5), 1121-1152.) (GRS) test to assess the performance of the models estimated in the first step of the Fama and MacBeth (1973Fama, E., & MacBeth, J. (1973). Risk, return and equilibrium: empirical tests. Journal of Political Economy, 81(3), 607-636.) methodology in explaining the returns on each of the 75 portfolios used as the models’ dependent variable. Finally, to verify the robustness of the results, the estimation was performed again by dividing the sample into two equal sub-periods of 108 months, namely: July 2000 to June 2009 and July 2009 to June 2018.

4. ANALYSIS OF RESULTS

4.1 Returns

Initially, we analyze the characteristics of portfolios whose excess returns were used as a dependent variable in the models, or left-hand-side portfolios (LHS). Table 6 shows the average of the characteristics used to form the portfolios, with the average for size shown on the left and, on the right, the average for the second variable considered in the formation of each portfolio group.

In interpreting the values on the left of Table 6, it is interesting to analyze the average sizes in each row, since they express the behavior of the portfolio size in relation to the average of the second variable considered in the ranking. On the right side of Table 6, it is important to observe, in each column, how the average of the second variable considered in the ranking behaved in relation to the size of the portfolio assets. The results presented in both sides of Table 6, when observed together, show the relationship established between the variables used in the ranking.

Table 6 results allow us to infer that there is a positive relationship between size and investment, and also between size and profitability, as the high portfolios for these two variables always presented a larger average size compared with the low portfolios. In the matrices for the average size and for the average profitability - Panel (c) - we find the only case in which a big portfolio has lower average profitability compared with the small portfolio of the same profitability group (big and high portfolio). As for the book-to-market ratio, there was a negative relationship between this index and size, as shown in Panel (a). This fact was already expected, as the market value is used in the denominator for calculating this index.

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Table 6
Average of the characteristics used to form the portfolios (left-hand-side variables)

Next, the average and standard deviation of the excess return on the LHS portfolios are shown in Table 7. Each Panel presents the values for a different portfolio group, which are organized according to the variable used in the second ranking of the portfolio formation process. This analysis is relevant because it aims to identify possible patterns in the excess average return on the portfolios in relation to the variables used in the study.

Panel (a) of Table 7 presents the characteristics for the 25 portfolios formed using size and the book-to-market ratio. In the columns of Table 7, we can observe decreasing average returns as portfolios composed of stocks with higher market value are considered. For all book-to-market groups, the excess average return on big portfolios was lower than the average value for the small portfolio, a pattern similar to this was also observed by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) in developed markets and, in the context of Latin American emerging markets, by Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.). This result shows the presence of a size effect: investors demand a higher return as a premium for the higher risk of investing in stocks of companies with lower market capitalization.

It is also possible to observe the relationship established between return and the book-to-market ratio. As documented by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) and by Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.), we can perceive a trend of growing average returns when comparing the low and high book-to-market ratio portfolios - which suggests the existence of a premium for investors adopting the strategy of investing in high book-to-market stocks (low price in relation to equity). It is also interesting to note that, similar to the results of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), the effect of the book-to-market ratio is larger for the small portfolio group compared with the big portfolio group. For portfolios composed of stocks with lower market capitalization, the excess average return between the low and high portfolios grows from 0.8436% to 2.2637%; while for the portfolios of stocks with higher market capitalization, the growth is from 0.4209% to 0.7213%.

Similarly, when investment is used as the second variable in the formation of portfolios, as shown in Panel (b) of Table 7, we also observe a size effect, with a tendency for the average return to fall as portfolios composed of larger companies are considered. This relationship, however, is strictly decreasing only for investment group 4.

Panel (b) of Table 7 also shows that the average return on the low portfolios was higher than that of the high portfolios for the small, 2 and 3 size groups. This result differs from those of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) - for developed markets - and those of Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) - for Latin American emerging markets - both studies found higher average returns on low investment portfolios for all company size groups. This fact indicates that in the study sample there is no investment effect for the groups of stocks with the higher market capitalization.

For the portfolios formed according to profitability ranking, we can observe again that Panel (c) of Table 7 shows a downward trend in returns as we consider portfolios composed of companies with higher market capitalization.

As documented by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), when we consider the low and high extremes of profitability, the high group has always presented higher returns. It is also interesting to note the lower profitability effect for the big portfolios, with an average of 0.3354% for the low portfolio and 0.5517% for the high portfolio. This differs from the findings by Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) for their Latin American sample. These authors observed higher average returns on low profitability portfolios.

Regarding the standard deviation of the excess return on the LHS portfolios, we observe that, in general, the small portfolios show a higher value for this measure compared with the big portfolios. These statistics corroborate the explanation for the presence of a size effect stating that the stocks of companies with lower market capitalization represent a higher risk for the investor. Also regarding the standard deviation, it is noteworthy that the results indicate that high book-to-market stocks represent a higher risk for the investor, as there is an upward trend in the standard deviation of the excess return on the high portfolios, compared with the low book-to-market portfolios.

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Table 7
Descriptive statistics for the portfolios' monthly excess return

4.2 Factors

After analyzing the characteristics and returns of the models’ LHS portfolios, we assess in this section the right-hand-side factors (RHS) - independent variables of the first-step models.

Panel (a) of Table 8 presents the descriptive statistics for the factors used to estimate the three-factor model of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) and the four-factor model of Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.). The SMB factor showed the highest average return among all factors (0.8783%), contrary to the HML factor, which exhibited the lowest average return (0.4460%). Regarding the statistical significance of the averages, at a level of 5%, only the average for the SMB factor was statistically significant. In terms of the distribution of returns, the skewness and kurtosis statistics indicate that none of the factors follows a normal distribution, which in this study does not represent a problem, given the large sample size used.

Due to the differences in how the factors of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) were built, which resulted in an SMB factor different from that used in the three- and four-factor models, the descriptive statistics of the factors used in the estimation of this model were separately presented in Panel (b) of Table 8.

These statistics showed again that the average return for the SMB factor was the highest among all factors (0.9076%). In contrast, the average CMA return was the lowest (0.1586%). Similar to what Panel (a) of this table shows, only the average for the SMB factor was statistically significant at the level of 5%. Again, skewness and kurtosis indicate that the factors do not have a normal distribution.

On the one hand, the results presented in Table 8 differ from those by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), who generally found lower, statistically significant averages for the factors in their study. Considering the factors built with a strategy similar to ours, the highest average documented by these authors was 0.50% for the market factor.

On the other hand, these statistics are in line with the results of other studies conducted with emerging markets samples, such as in Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.), who also found non-significant average monthly returns for the factors that were higher than those of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.). In the study by Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.), the market factor showed the highest average among all tested factors (1.02%); while in Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) the highest average was observed for the size factor (0.72%).

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Table 8
Descriptive statistics for the factors’ monthly returns

In order to assess whether the RHS factors represent different dimensions of systematic risk, we performed an analysis of the correlations between the factors. Panel (a) of Table 9 shows the correlations estimated for the factors of the Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) and Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) models. Our analysis showed that the HML and Market (R_m-R_f) factors have the strongest and most positive relationship, with a coefficient of 0.4043. In contrast, the WML and HML factors showed the strongest negative association, with a coefficient of -0.3166.

The correlations between the returns for the factors used to estimate the Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) model are shown in Panel (b) of Table 9. The strongest negative relationship was observed between the HML and RMW factors (-0.2699). It is also interesting to note the correlation of -0.2243 between the RMW and CMA factors.

Overall, these results suggest a low degree of association between the factors of the Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.), Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) and Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) models. In other words, our results suggest that they represent different dimensions of systematic risk. Foye (2018Foye, J. (2018). A comprehensive test of the Fama-French five-factor model in emerging markets. Emerging Markets Review, 37, 199-222.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) are examples of studies that also examined the Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) model in the context of Latin American emerging markets, and they also observed a low degree of association between the factors used in the five-factor model.

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Table 9
Correlation between systematic risk factors

4.3 First-Step Regressions

As pointed out by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), the evaluation of an asset pricing model should focus mainly on its performance in explaining the excess return on the LHS portfolios. To this end, we used in this study the GRS test, which has the null hypothesis that the regression intercepts for a portfolio group are statistically equal to zero. Therefore, the best model evaluated using this test is the one with the highest p-value and the lowest test statistic. In addition to the GRS test, Table 10 presents other statistics for the model intercepts, which allow us to assess the magnitude of the returns left unexplained by the factor models, which are:

(i) A|a_i| - average of the absolute values of the intercepts found for the model in a given LHS portfolio group. For this statistic, lower values indicate a better model performance.
(ii) A|a_i|/A|r_i| - ratio between the absolute average of the intercepts - A|a_i| - and the absolute value of the average deviation of the returns on each portfolio i in relation to the average of the returns on all LHS portfolios formed using the same variables used to build the portfolio i - A|r_i|. It shows the dispersion of the model intercepts in relation to the expected return for a LHS portfolio group, thus measuring how much of the returns on the LHS portfolios are left unexplained by the factor models.

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Table 10
Descriptive statistics for the first-step regressions

The following analysis is mainly aimed at comparing the performance of the models in the different sets of factors tested to assess the impact of the inclusion of new factors on the models’ predictive power. The GRS test statistics, presented in Table 10, show that the model with the highest p-value was composed of five factors for all LHS portfolio groups. This result is in line with those obtained by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), providing evidence for the inclusion of investment and profitability factors in the model.

The worst performance was observed for the models based on book-to-market portfolios - Panel (a). It is interesting to note that the GRS null hypothesis was rejected at the significance level of 5% for all sets of factors of this portfolio group. For the other LHS portfolio groups, the null hypothesis could not be rejected, indicating that the models were able to fully explain the expected returns on the respective portfolios.

The values of the A|a_i| presented in Table 10 favor the five-factor of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) for the book-to-market and profitability portfolios. However, as Panel (b) shows, for investment portfolios, the model that presented the lowest value for A|a_i| (0.2229) was composed of the three-factor Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.).

For the A|a_i|/A|r_i| ratio, lower values mean that the model left a smaller portion of average returns unexplained. The A|a_i|/A|r_i| ratio also favored the five-factor model for the book-to-market and profitability portfolios in the second ranking. For investment portfolios, the model showing the lowest value for this statistic (0.5158) was composed of the three-factor Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.). It is important to note that the A|a_i| and A|a_i|/A|r_i| statistics fulfill different objectives compared with the GRS test: while A|a_i| and A|a_i|/A|r_i| are aimed at analyzing the portion of returns left unexplained by the models, the GRS test verifies whether the set of intercepts for a portfolio group is statistically equal to zero.

The analysis of the average R² statistics in Table 10 shows that the results favors the Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) model for all LHS portfolio groups. The largest gain in explanatory power for this statistic was observed for the investment portfolios in the second ranking, with R² jumping from 0.7265 for the three-factor model to 0.7557 for the five-factor model.

Our results corroborate those of other studies that analyzed returns on stocks of companies listed on stock exchanges in Latin America. Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.) and Foye (2018Foye, J. (2018). A comprehensive test of the Fama-French five-factor model in emerging markets. Emerging Markets Review, 37, 199-222.), for example, do not reject the GRS null hypothesis for the models, with the five-factor model being preferable to the three-factor model for the profitability and investment portfolios formed in the second ranking.

4.3.1 Robustness analysis

To verify the robustness of the first-step regressions’ results, the models were estimated again with the sampling period segmented into two equal periods: (i) July 2000 to June 2009 (Pre-2009); and (ii) July 2009 to June 2018 (Post-2009).

The robustness test results - Table 11 - show that, for all LHS portfolio groups, the models were better adjusted in the second sampling period. The largest gain was observed for investment portfolios in the second ranking highest GRS p-value between the two periods - Panel b). This result could be explained by a greater integration of the studied countries’ markets into the global markets. Transactions in the emerging markets would thus be showing a behavior more similar to that of the markets for which the models were proposed.

Again, the five-factor model showed the best performance both in the GRS test and in the A|α_i| statistic. As Panel (c) of Table 11 shows, the only exception was the profitability portfolios, as the GRS test statistics (p-value = 0.2182) for the post-2009 period suggested that the four-factor model of Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) performed better.

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Table 11
Robustness tests of model performance: estimates for two sub-periods

4.4 Second-Step Regressions

The second-step cross-section regressions were estimated using the average of the excess return for each of the 75 LHS portfolios as a dependent variable over the sample period and the coefficients estimated in the first-step regressions as independent variables.

Before interpreting the results for the models, it is necessary to analyze the validation tests’ results. Table 12 shows the Variance Inflation Factor (VIF) for the explanatory variables used in the models. It is interesting to note that this statistic indicates no multicollinearity for the models, given that, as Wooldridge (2010Wooldridge, J. M. (2010). Introdução à econometria: uma abordagem moderna (4a ed.). São Paulo: Cengage Learning.) points out, it is normally assumed that VIF values higher than 10 indicate multicollinearity.

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Table 12
VIF of the second-step regressions’ explanatory variables

Table 13 shows the results of the Breusch-Pagan, Durbin-Watson and Hausman tests, used to detect heteroscedasticity, autocorrelation and endogeneity problems, respectively. It is noteworthy that the results obtained show no autocorrelation problems in the models, whereas the BP test result attested the presence of heteroscedasticity for the five-factor model, with a p-value of 0.0457. In view of the validation tests’ results, it was necessary to correct standard errors only for the five-factor model; therefore, this model was estimated again, considering the robust standard errors for heteroscedasticity.

Finally, the Hausman test results showed no endogeneity problems for the models. Still regarding the endogeneity problem, as pointed out by Collot and Hemauer (2020Collot, S., & Hemauer, T. (2020). A literature review of new methods in empirical asset pricing: omitted-variable and errors-in-variable bias. Financial Markets and Portfolio Management.), using portfolios to estimate the models is an approach aimed at increasing the accuracy of the coefficients. Therefore, we used OLS to estimate the models.

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Table 13
Validation tests of the second-step regressions

Table 14 shows the results of the cross-section regressions. All factors used in the estimation of the three-factor model showed to be significant - Panel (a). After adding the momentum factor to this model - Panel (b) - its coefficient showed no significance. When the five-factor model was estimated, the coefficient for profitability was significant only at the level of 10%; and the investment coefficient was not significant. Despite the fact that the new factors included in the Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) model showed no significance for the tested models, this was the model with the greatest explanatory power in the second-step regressions, with an adjusted R² of 0.6995.

Finally, it is interesting to note that the models’ intercepts showed to be highly significant in all cases. This suggests that the factors tested were not sufficient to explain the excess cross-section return for the LHS portfolios. The intercept would thus reflect the variations in the return resulting from relevant factors not included in the model.

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Table 14
Results of the factor models’ cross-section regressions

5. FINAL CONSIDERATIONS

The relevance of this study stems from its examination of the differences between the capital markets of developed countries and emerging countries, which affect the results and the predictive power of asset pricing models - which were mostly proposed for developed markets - and, consequently, the investor’s decision-making process. Thus, this study had as its main objective testing the five-factor model of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) using a sample composed of stocks of companies listed in the stock markets of Brazil, Chile, Colombia, Mexico and Peru. At the same time, in order to allow comparing the results for models with different sets of factors, the models of Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) and Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) were also estimated.

It is interesting to note that the descriptive statistics of the returns for the factors built to estimate the models showed that the averages found were, in general, higher than those found by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.), with only the SMB factor average showing statistical significance. These results corroborate those of other studies on asset pricing in emerging markets, such as those by Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.) and Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.); and they indicate the existence of a greater impact of the variables used to build the factors on the returns on the assets traded in these markets.

Regarding the results of the first-step regressions estimated, the descriptive statistics indicated, in general, that the five-factor model performed better. The p-values of the GRS statistics were always higher for the five-factor model, with the result for the model applied to portfolios formed by size and book-to-market the only case in which the null hypothesis of the test was rejected (0.0447).

To test the robustness of the results, the models were estimated again by segmenting the sampling period into two sub-periods of equal duration. The robustness test results showed that the models performed better in the second half of the sampling period, which could be explained by the greater integration of the markets studied into the global markets. With regard to the different model compositions tested, the results again indicated that the model composed of the five factors of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) performed better for the sample.

Finally, the cross-section regressions, or second step models, were tested to verify whether the coefficients obtained in the first step were able to explain the excess average return on the LHS portfolios. The results favored the Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) model, given its higher adjusted R². However, the estimates of the models studied clearly showed that none of them was able to fully explain the excess return on the LHS portfolios. Our findings, therefore, suggest that the factors tested could not fully describe the cross-section returns for the sample assets. This reinforces the need to carry out further studies with the inclusion of other factors in the models, such as market liquidity and informational risk.

The study results contribute to a better understanding of the relevant factors in emerging markets and their impact on asset pricing; and they help financial market players to improve their decision-making process both in the composition and in the assessment of the performance of their investment portfolios in view of the exposure to different sources of systematic risk. With regard to the asset pricing literature, this article provides important contributions by analyzing a broad sample of stocks traded in different emerging markets in Latin America and by conducting an empirical test of the Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) model based on the Fama and MacBeth methodology (1973Fama, E., & MacBeth, J. (1973). Risk, return and equilibrium: empirical tests. Journal of Political Economy, 81(3), 607-636.).

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*
The authors would like to thank the Centro Federal de Educação Tecnológica de Minas Gerais (CEFET-MG) for the financial support provided to this study.

Publication Dates

Publication in this collection
23 July 2021
Date of issue
Sep-Dec 2021

History

Received
16 June 2020
Reviewed
13 Aug 2020
Accepted
02 Feb 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Ali, F., Khurram, M. U. & Jiang, Y. (2019). The five-factor asset pricing model tests and profitability and investment premiums: evidence from Pakistan. Emerging Markets Finance & Trade, 1-23.

[2] Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.

[3] Cakici, N., Tang, Y., & Yan, A. (2016). Do the size, value, and momentum factors drive stock returns in emerging markets? Journal of International Money and Finance, 69, 179-204.

[4] Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.

[5] Collot, S., & Hemauer, T. (2020). A literature review of new methods in empirical asset pricing: omitted-variable and errors-in-variable bias. Financial Markets and Portfolio Management.

[6] Fama, E., & French, K. (1992). The cross-section of expected stock returns. Journal of Finance, 47(2), 427-465.

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Authors	Sample	Factors included	Main findings
Cakici et al. (2013Cakici, N., Fabozzi, F. J., & Tan, S. (2013). Size, value, and momentum in emerging market stock returns. Emerging Markets Review, 16, 46-65.)	18 emerging markets	Market; size; value; and momentum	Local factors showed a better predictive power compared with American and global factors.
Hanauer and Linhart (2015Hanauer, M. X., & Linhart, M. (2015). Size, value, and momentum in emerging market stock returns: integrated or segmented pricing? Asia-Pacific Journal of Financial Studies, 44, 175-214.)	21 emerging markets	Market; size; value; and momentum	The model with the greater predictive power was based on Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) and used local factors.
Cakici et al. (2016Cakici, N., Tang, Y., & Yan, A. (2016). Do the size, value, and momentum factors drive stock returns in emerging markets? Journal of International Money and Finance, 69, 179-204.)	18 emerging markets	Market; size; value; and momentum	The value and momentum factors fail to explain asset returns.
Xie and Qu (2016Xie, S., & Qu, Q. (2016). The three-factor model and size and value premiums in China’s stock market. Emerging Markets Finance & Trade, 52(5), 1092-1105.)	Shanghai Stock Exchange (SSE)	Market; size; and value	The model of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) performed well, being able to increase the predictive power compared with CAPM.
Siqueira, Amaral and Correia (2017Siqueira, L. S., Amaral, H. F., & Correia, L. F. (2017). O efeito do risco de informação assimétrica sobre o retorno de ações negociadas na BM&FBOVESPA. Revista Contabilidade & Finanças, 28(75), 425-444.)	Brazilian Market (B3)	Market; size; value; momentum; investment; profitability; and volume-synchronized probability of informed trading (VPIN)	The VPIN factor increased the models' explanatory power. The model that performed better was composed of market, size, investment, profitability and VPIN factors.
Zaremba and Czapkiewicz (2017Zaremba, A., & Czapkiewicz, A. (2017). Digesting anomalies in emerging European markets: a comparison of factor pricing models. Emerging Markets Review, 31, 1-15.)	5 Eastern-European emerging markets	Market; size; value; momentum; investment; and profitability	The model of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) best explains the returns of anomaly portfolios.
Foye (2018Foye, J. (2018). A comprehensive test of the Fama-French five-factor model in emerging markets. Emerging Markets Review, 37, 199-222.)	18 emerging markets	Market; size; value; investment; and profitability	The factors used by Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) offered a better description of returns in Eastern Europe and Latin America, whereas for Asia this model failed to increase the explanatory power of the model of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.).
Leite et al. (2018Leite, A. L., Klotzle, M. C., Pinto, A. C. F., & Silva, A. F. (2018). Size, value, profitability, and investment: evidence from emerging markets. Emerging Markets Review, 36, 45-59.)	12 emerging markets	Market; size; value; investment; and profitability	The models of Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.) and Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) performed better, the value factor showed to be redundant in the model of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.).
Ali, Khurram and Jiang (2019Ali, F., Khurram, M. U. & Jiang, Y. (2019). The five-factor asset pricing model tests and profitability and investment premiums: evidence from Pakistan. Emerging Markets Finance & Trade, 1-23.)	Pakistan’s Market	Market; size; value; momentum; investment; and profitability	The model using the factors of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.) showed the greater predictive power. An important point is that the momentum and value factors were redundant.
Ganz, Schlotefeldt and Rodrigues Junior (2020Ganz, A. C. S., Schlotefeldt, J. O., & Rodrigues Junior, M. M. (2020). Modelos de precificação de ativos financeiros e governança corporativa. Revista de Administração Mackenzie, 21(2), 1-27.)	Brazilian Market (B3)	Market; size; value; investment; profitability; and corporate governance	Results showed that the market risk factor was the only significant one, regardless of the combination of factors tested.

Model	Equation	Empirical basis
Three-factor	$R_{i} - R_{f} = α_{i} + β_{i} (R_{m} - R_{f}) + s_{i} S M B + h_{i} H M L + ε_{i}$	Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.)
Four-factor	$R_{i} - R_{f} = α_{i} + β_{i} (R_{m} - R_{f}) + s_{i} S M B + h_{i} H M L + w_{i} W M L + ε_{i}$	Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.)
Five-factor	$R_{i} - R_{f} = α_{i} + β_{i} (R_{m} - R_{f}) + s_{i} S M B + h_{i} H M L + r_{i} R M W + c_{i} C M A + ε_{i}$	Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.)

Model	Equation	Empirical basis
Three-factor	$\bar{R} = γ_{0} + γ_{1} β + γ_{2} s + γ_{3} h + ε_{i}$	Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.)
Four-factor	$\bar{R} = γ_{0} + γ_{1} β + γ_{2} s + γ_{3} h + γ_{4} w + ε_{i}$	Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.)
Five-factor	$\bar{R} = γ_{0} + γ_{1} β + γ_{2} s + γ_{3} h + γ_{5} r + γ_{6} c + ε_{i}$	Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.)

Variable	Classification	Factor
Size	Median	SMB_B/M = ${S M B}_{B ∕ M} = (S H + S N + S L) / 3 - (B H + B N + B L) / 3$
		${S M B}_{L u c} = (S R + S N + S W) / 3 - (B R + B N + B W) / 3$
		${S M B}_{I n v} = (S C + S N + S A) / 3 - (B C + B N + B A) 3$
		$S M B = ({S M B}_{B / M} + {S M B}_{L u c} + {S M B}_{I n v}) / 3$
Book-to-market	30th and 70th percentiles	$H M L = (S H + B H) / 2 - (S L + B L) / 2$
Momentum	30th and 70th percentiles	$W M L = ({S W}_{i n} + {B W}_{i n}) / 2 - (S_{L o s} + B_{L o s}) / 2$
Profitability	30th and 70th percentiles	$R M W = (S R + B R) / 2 - (S W + B W) / 2$
Investment	30th and 70th percentiles	$C M A = (S C + B C) / 2 - (S A + B A) / 2$

Panel (a): Portfolios formed by size - book-to-market
	Size					Book-to-market
	Low	2	3	4	High	Low	2	3	4	High
Small	37.16	31.92	35.06	32.36	20.64	0.94	2.24	3.91	6.85	26.14
2	202.19	190.58	195.20	181.38	174.20	0.56	1.08	1.71	2.88	9.48
3	595.75	545.91	552.13	546.51	549.39	0.41	0.83	1.29	2.15	7.15
4	1498.66	1441.27	1412.36	1333.77	1376.17	0.31	0.65	1.03	1.72	5.76
Big	10532.17	8392.76	7629.42	7509.62	7404.11	0.24	0.47	0.73	1.21	3.12
Panel (b): Portfolios formed by size - investment
	Size					Investment
	Low	2	3	4	High	Low	2	3	4	High
Small	31.17	31.70	32.14	28.76	33.24	-0.21	-0.06	0.02	0.12	0.48
2	182.68	182.43	194.30	196.38	188.30	-0.16	-0.02	0.05	0.14	0.49
3	551.20	556.07	550.61	564.68	570.09	-0.12	-0.01	0.07	0.16	0.56
4	1373.81	1418.07	1433.96	1404.19	1437.23	-0.12	0.00	0.08	0.17	0.62
Big	6286.97	8604.36	9039.85	9241.75	8381.72	-0.10	0.01	0.09	0.18	0.55
Panel (c): Portfolios formed by size - profitability
	Size					Profitability
	Low	2	3	4	High	Low	2	3	4	High
Small	27.97	30.23	35.01	34.76	29.30	-0.76	0.01	0.10	0.18	0.96
2	174.62	190.35	192.15	189.65	197.58	-0.13	0.08	0.14	0.22	0.44
3	528.38	571.35	562.52	545.58	584.12	0.00	0.11	0.17	0.25	0.57
4	1391.35	1392.12	1395.13	1435.58	1454.04	0.03	0.13	0.19	0.28	0.68
Big	5560.85	7312.36	7555.83	10434.41	10700.42	0.00	0.14	0.21	0.31	0.61

	Brazil	Chile	Colombia	Mexico	Peru	Total
2000	109	70	8	65	21	273
2001	119	63	8	69	25	284
2002	123	61	9	61	29	283
2003	128	65	9	58	31	291
2004	141	64	9	58	35	307
2005	144	68	7	60	40	319
2006	161	78	6	60	47	352
2007	178	88	6	58	48	378
2008	211	81	5	58	51	406
2009	229	76	7	66	49	427
2010	231	84	7	67	47	436
2011	223	92	8	71	44	438
2012	233	84	9	69	37	432
2013	224	84	12	67	35	422
2014	215	86	19	66	31	417
2015	201	82	17	70	26	396
2016	192	78	20	73	27	390
2017	197	80	21	71	28	397

Panel (a): Portfolios formed by size - book-to-market
	Average					Standard deviation
	Low	2	3	4	High	Low	2	3	4	High
Small	0.8436	1.6775	1.8581	2.0105	2.2637	9.0437	8.3484	9.6646	9.0696	8.4727
2	1.2731	1.2952	1.7941	2.7619	1.8136	8.8339	7.4174	7.8206	8.5000	9.3274
3	0.5159	1.3284	0.9358	1.5069	1.5458	8.1598	7.1883	8.0903	7.8140	8.6186
4	0.9368	0.8417	1.1315	1.0921	1.1476	6.8290	6.6835	6.6623	7.3880	8.3322
Big	0.4209	0.3880	0.4499	0.9325	0.7213	7.1090	6.6723	7.0559	7.9369	9.6569
Panel (b): Portfolios formed by size - investment
	Average					Standard deviation
	Low	2	3	4	High	Low	2	3	4	High
Small	1.6851	1.5126	1.6140	2.1141	1.6395	10.1082	8.7661	9.2969	8.2701	9.1962
2	2.0772	1.7192	2.1014	1.7472	1.1454	9.0066	7.9045	9.0331	7.7572	8.8953
3	1.1125	1.3214	1.4360	1.0629	0.7175	7.4009	7.6881	7.7626	7.8410	9.9135
4	0.8620	1.0621	1.1183	1.0570	1.0488	7.3286	7.1012	6.5647	7.2185	8.2037
Big	0.2964	0.8184	0.4306	0.7031	0.4818	7.5539	7.3562	7.9723	7.8180	8.4644
Panel (c): Portfolios formed by size - profitability
	Average					Standard deviation
	Low	2	3	4	High	Low	2	3	4	High
Small	1.5424	1.9536	1.3257	1.8692	1.9659	10.7182	8.8083	8.3039	7.7938	10.1249
2	1.9084	1.2445	1.4908	1.6217	2.4318	9.7890	7.6491	7.4476	8.0016	8.9191
3	0.7834	1.1481	1.4690	1.1965	1.1571	8.5374	7.7659	7.4743	7.2863	8.8785
4	0.8954	0.7066	0.9109	1.2370	1.3156	7.0042	7.9307	6.4517	6.6165	7.8578
Big	0.3354	0.4861	0.3406	0.9200	0.5517	8.9496	7.0948	7.0585	7.9690	7.4829

Panel (a): Descriptive statistics for the three-factor of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) and for the momentum factor of Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.)
	Rm-Rf		SMB	HML	WML
Average	0.7750		0.8783	0.4460	0.5629
Standard deviation	6.9756		2.7187	3.9544	4.8929
Skewness	-0.9295		0.0852	-0.0215	-0.3034
Kurtosis	3.2129		-0.0090	1.1484	1.6118
t-statistics	1.6328		4.7480	1.6577	1.6909
P-value	0.1040		0.0000	0.0988	0.0923
Panel (b): Descriptive statistics for the five-factor of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.)
	Rm-Rf	SMB	HML	CMA	RMW
Average	0.7750	0.9076	0.4460	0.1586	0.2749
Standard deviation	6.9756	2.7721	3.9544	4.1325	3.3548
Skewness	-0.9295	0.1468	-0.0215	0.0445	-0.9242
Kurtosis	3.2129	-0.0359	1.1484	1.3586	3.3941
t-statistics	1.6328	4.8117	1.6577	0.5640	1.2044
P-value	0.1040	0.0000	0.0988	0.5733	0.2297

Panel (a): Correlation between the three-factor of Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.) and the momentum factor of Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.)
	Rm-Rf		SMB	HML	WML
Rm-Rf	1
SMB	-0.1525		1
HML	0.4043		0.0306	1
WML	-0.1411		-0.1187	-0.3166	1
Panel (b): Correlation between the five-factor of Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.)
	Rm-Rf	SMB	HML	RMW	CMA
Rm-Rf	1
SMB	-0.1111	1
HML	0.4043	0.0359	1
RMW	-0.1346	-0.2194	-0.2699	1
CMA	-0.2108	0.0428	0.1773	-0.2243	1

Panel (a): Portfolios formed by size - book-to-market
	GRS	*p-value*	A\|α_i\|	s(α)	A\|α_i\|/A\|r_i\|	R²
Three factors	1.7815	0.0165	0.2731	0.3803	0.5676	0.7657
Four factors	1.6918	0.0265	0.2600	0.3769	0.5402	0.7684
Five factors	1.5884	0.0447	0.2547	0.3574	0.5292	0.7715
Panel (b): Portfolios formed by size - investment
	GRS	*p-value*	A\|α_i\|	s(α)	A\|α_i\|/A\|r_i\|	R²
Three factors	1.1879	0.2548	0.2229	0.2996	0.5180	0.7265
Four factors	1.5134	0.0641	0.2610	0.3565	0.6066	0.7315
Five factors	1.1164	0.3277	0.2496	0.3140	0.5801	0.7574
Panel (c): Portfolios formed by size - profitability
	GRS	*p-value*	A\|α_i\|	s(α)	A\|α_i\|/A\|r_i\|	R²
Three factors	1.4103	0.1029	0.2533	0.3359	0.5911	0.7441
Four factors	1.3569	0.1300	0.2305	0.3288	0.5379	0.7475
Five factors	1.1291	0.3139	0.2085	0.2515	0.4866	0.7600

Panel (a): Portfolios formed by size - book-to-market
	Pre-2009			Post-2009
	GRS	p-value	A\|α_i\|	GRS	p-value	A\|α_i\|
Three factors	1.8508	0.0207	0.4563	1.8030	0.0255	0.25840
Four factors	1.7970	0.0264	0.4422	1.5870	0.0636	0.28518
Five factors	1.7163	0.0375	0.4412	1.5711	0.0683	0.23002
Panel (b): Portfolios formed by size - investment
	Pre-2009			Post -2009
	GRS	p-value	A\|α_i\|	GRS	p-value	A\|α_i\|
Three factors	1.1960	0.2694	0.3737	0.8840	0.6246	0.27889
Four factors	1.1897	0.2754	0.3900	0.8505	0.6674	0.28041
Five factors	1.1400	0.3223	0.3704	0.6742	0.8662	0.25086
Panel (c): Portfolios formed by size - profitability
	Pre-2009			Post -2009
	GRS	p-value	A\|α_i\|	GRS	p-value	A\|α_i\|
Three factors	1.8827	0.0180	0.5128	1.4471	0.1101	0.40548
Four factors	1.8353	0.0224	0.5084	1.2600	0.2182	0.40767
Five factors	1.6781	0.0440	0.4974	1.2960	0.1932	0.32200

Variable	Three factors	Four factors	Five factors
β	1.0235	1.0216	1.0246
s	1.0303	1.0678	1.0452
h	1.0105	1.0055	1.0378
w	-	1.0475	-
r	-	-	1.0544
c	-	-	1.0299

Model	DW	p-value	BP	p-value	Hausman	p-value
Three factors	2.0480	0.5743	5.3742	0.1464	2.4555	0.4834
Four factors	2.0686	0.6200	9.1008	0.0586	2.8188	0.5886
Five factors	2.1301	0.7375	11.3020	0.0457	3.4976	0.6237

Panel (a): Three-factor Fama and French (1993Fama, E., & French, K. (1993). Common risk factors in the returns on stocks and bonds. Journal of Financial Economics, 33(1), 3-56.)
	γ₀	γ₁	γ₂	γ₃			Adjusted R^²
Coef	1.6041	-0.9308	0.9527	0.3226			0.6555
p-val	0.0000	0.0002	0.0000	0.0082			0.6555
Panel (b): Four-factor Carhart (1997Carhart, M. M. (1997). On persistence in mutual fund performance. Journal of Finance, 52(1), 57-81.)
	γ₀	γ₁	γ₂	γ₃	γ₄		Adjusted R^²
Coef	1.5997	-0.9217	0.9784	0.3582	0.2020		0.6606
p-val	0.0000	0.0003	0.0000	0.0037	0.5001		0.6606
Panel (c): Five-factor Fama and French (2015Fama, E., & French, K. (2015). A five-factor asset pricing model. Journal of Financial Economics, 116(1), 1-22.)
	γ₀	γ₁	γ₂	γ₃	γ₅	γ₆	Adjusted R^²
Coef	1.7301	-1.0481	0.9246	0.3988	0.2946	-0.0410	0.6958
p-val	0.0000	0.0002	0.0000	0.0018	0.0774	0.7821	0.6958

Brasil

Brasil

The pricing of anomalies using factor models: a test in Latin American markets* * The authors would like to thank the Centro Federal de Educação Tecnológica de Minas Gerais (CEFET-MG) for the financial support provided to this study.

ABSTRACT

Resumo

1. INTRODUCTION

2. THEORETICAL FRAMEWORK

2.1 Capital Asset Pricing

3. METHODS

3.1 Population and Sample

3.2 Econometric Models Estimated

3.3 Validation and Robustness Tests of the Models

4. ANALYSIS OF RESULTS

4.1 Returns

4.2 Factors

4.3 First-Step Regressions

4.4 Second-Step Regressions

5. FINAL CONSIDERATIONS

REFERENCES

Publication Dates

History

The pricing of anomalies using factor models: a test in Latin American markets^* * The authors would like to thank the Centro Federal de Educação Tecnológica de Minas Gerais (CEFET-MG) for the financial support provided to this study.