University of Pennsylvania ScholarlyCommons Wharton Research Scholars Wharton School April 24 Time Dependency in Fama French Portfolios Manoj Susarla University of Pennsylvania Follow this and additional works at: http://repository.upenn.edu/wharton_research_scholars Susarla, Manoj, "Time Dependency in Fama French Portfolios" (24). Wharton Research Scholars. 17. http://repository.upenn.edu/wharton_research_scholars/17 This paper is posted at ScholarlyCommons. http://repository.upenn.edu/wharton_research_scholars/17 For more information, please contact repository@pobox.upenn.edu.
Time Dependency in Fama French Portfolios This journal article is available at ScholarlyCommons: http://repository.upenn.edu/wharton_research_scholars/17
Time Dependency in Fama French Portfolios By Manoj Susarla Advisor J. Michael Steele Wharton Undergraduate Research Scholars WH-299-31 April 24
Time Dependency in Fama French Portfolios Introduction The general relationship between stock returns and the Fama French factors has been examined by many papers in the academic literature. While Fama and French (1992) find that size [market equity] and book-to-market equity combine to capture the cross-sectional variation in average stock returns 1, Lakonishok, Shleifer, and Vishny (1994) fail to find such a relationship between returns and book-to-market equity. More specific study has also been conducted to determine whether stocks exhibit mean reverting tendencies, or a tendency of asset prices to return to a trend path. 2 Fama and French (1992) document evidence of mean reversion in equal-weighted portfolios in the prewar (i.e., pre-1947) period as well as the entire period over which stock data is available (i.e., 1926 present). While the latter point has generated considerable opposing arguments (e.g., Lamoureux and Zhou (1996) and Bidarkota and McCulloch (1996)), the former notion of mean reversion in the prewar period is generally accepted. Furthermore, there seems to be a consensus that there is little evidence for mean reversion in the postwar period (i.e., 1947 present) (sample articles supporting this notion include Kim, Nelson, and Startz (1991), and Bidarkota and McCulloch (1996)). This paper determines the relationship between a more generalized notion of time dependency (i.e., not necessarily mean reverting tendencies) and the Fama French factors by examining the existence of time dependency in portfolios constructed based on the Fama French factors of market equity and the ratio of book-to-market equity. 1 Eugene F. Fama and Kenneth R. French, The Cross-Section of Expected Stock Returns, The Journal of Finance Vol. 47, No. 2. (Jun., 1992): 427. 2 Ronald Balvers, Yangru Wu, and Erik Gilliland. Mean Reversion across National Stock Markets and Parametric Contrarian Investment Strategies, The Journal of Finance Vol. 55, No. 2. (Apr., 2): 745. 1
Specifically, it uses portfolios that were constructed based on the aforementioned Fama French factors and calculates autocorrelations of the returns on these portfolios for lags 1 12 months. The significance of these autocorrelations is then examined by use of confidence intervals constructed by a simulation method. Finally, the simulations are rerun, and the confidence intervals are reconstructed, for the pre- and post-war periods, in order to determine any difference in the occurrence of significant autocorrelations between pre- and postwar data. The Fama French Portfolios The data set used in this paper is entitled 25 Portfolios Formed on Size and Book-to-Market. The portfolios were created by Fama and French and are accessible on the Internet. 3 The portfolios were created using NYSE, AMEX, and NASDAQ stocks for which monthly return data was available during part or all of the period from July 1926 to December 22. The stocks were partitioned into quintiles by market equity and then into subquintiles by book-to-market equity. The two sets of partitions give 25 portfolios, as illustrated in Figure 1 below. Small and Big refer to the lowest and highest quintile, respectively, of market equity, and Low and High refer to the lowest and highest quintile, respectively, of book-to-market equity; these naming conventions will be employed throughout this paper. 3 Accessible at http://mba.tuck.dartmouth.edu/pages/faculty/ken.french/data_library/tw_5_ports.html. 2
Figure 1: The Fama French Portfolios Market Equity (ME) Small 4% 6% 8% Big Book-to-Market Equity (BE/ME) Low 4% 6% 8% High Fama and French explain the exact assumptions under which the portfolios are created in their article Multifactor Explanations of Asset Pricing Anomalies (1996). The relevant information is provided below. At the end of June of each year t,nyse, AMEX, and Nasdaq stocks are allocated to two groups (small or big, S or B) based on whether their June market equity (ME, stock price times shares outstanding) is below or above the median ME for NYSE stocks. NYSE, AMEX, and Nasdaq stocks are allocated in an independent sort to three book-to-market equity (BE/ME) groups (low, medium, or high; L, M, or H) based on the breakpoints for the bottom 3 percent, middle 4 percent, and top 3 percent of the values of BE/ME for NYSE stocks. Six size- BE/ME portfolios (S/L, S/M, S/H, B/L, B/M, B/H) are defined as the intersections of the two ME and the three BE/ME groups. Value-weight monthly returns on the portfolios are calculated from July to the following June.The 25 size-be/me portfolios are formed like the six size-be/me portfolios, except that quintile breakpoints for ME and BE/ME for NYSE stocks are used to allocate NYSE, AMEX, and Nasdaq stocks to the portfolios. BE is the COMPUSTAT book value of stockholders equity, plus balance sheet deferred taxes and investment tax credit (if available), minus the book value of preferred stock. Depending on availability, we use redemption, liquidation, or par value (in that order) to estimate the book value of preferred stock. The BE/ME ratio used to form portfolios in June of year t is then book common equity for the fiscal year ending in calendar year t 1, divided by market equity at the end of December of t 1. We do not use negative BE firms, which are rare prior to 198, when calculating the breakpoints for BE/ME or when forming the size-be/me 3
portfolios. Also, only firms with ordinary common equity (as classified by CRSP) are included in the tests. This means that ADR s, REIT s, and units of beneficial interest are excluded. 4 While Fama and French describe their methods only for returns on the portfolios during the 366-month period from July 1963 December 1993, it is assumed that they used similar methods in creating the portfolios for the entire 912-month period from July 1926 December 22. It should also be noted that Fama and French create both equaland value-weighted portfolios; this paper uses value-weighted portfolios. Lastly, it should be noted that the composition of stocks in an individual portfolio, as well as the number of stocks used in an individual portfolio, can change from year to year. s for Fama French Portfolios For each of the 25 portfolios, autocorrelations were calculated for lags 1, 2,, 12 months. The autocorrelations for each portfolio are presented graphically in Appendix 1. An initial overview of the data reveals a few general patterns. All 25 portfolios have both positive and negative autocorrelations, depending on the lag. Also, each lag 1 12 has positive and negative autocorrelations, depending on the portfolio. Lastly, the magnitude of the autocorrelations varies significantly, both within each portfolio and across all the portfolios for a given lag. Whether any of the autocorrelations in a given portfolio is significant was determined by the confidence interval method, based on a simulation described below. 4 Eugene F. Fama and Kenneth R. French, Multifactor Explanations of Asset Pricing Anomalies, The Journal of Finance Vol. 51, No. 1. (Mar., 1996): 58. 4
Construction of Confidence Intervals via Simulation For each of the 25 portfolios, the significance of each of the 12 autocorrelations for the portfolio was tested based on the confidence interval method similar to one used by Dean Fikar, and investment advisor, on his Internet web site, which has short essays on a variety of topics in portfolio management and market theory. 5 To construct these confidence intervals, the monthly returns for each portfolio r 1, r 2,, r 918 were permuted, using a random number generator, to yield a new series r σ(1), r σ(2),, r σ(918). The autocorrelations for lags 1 12 were then calculated for the new series. This method of permutation and autocorrelation calculation was repeated 249 more times for each portfolio. Thus, for each portfolio, the simulation yielded 25 autocorrelations for each lag 1 12. The autocorrelations for each lag i were then put into ascending order; that is, for a given lag, the simulated autocorrelations ρ i,1, ρ i,2,, ρ i,25 were put into ascending order, ρ i,(1), ρ i,(2),, ρ i,(25) such that ρ i,(1) < ρ i,(2) < < ρ i,(25). Then, in order to construct 95% confidence intervals, 2.5% of the autocorrelations were trimmed from the top and the bottom of the ordered distribution of autocorrelations, and the lowest and highest remaining autocorrelations were used as the lower and upper bounds, respectively, of the confidence interval. These confidence intervals could also have been constructed using the traditional mathematical formula for t-confidence interval. In general, these traditional t-confidence intervals are much smaller (i.e., have a much smaller range) than the confidence intervals generated by the simulation method. However, unlike this method, the construction of confidence intervals by the method described above is not only more intuitive but also 5 Accessible at http://nofeeboards.com/raddr/mean%2reversion.htm. 5
makes no assumptions about the normality of the distribution of the simulated autocorrelations. The assumption of normality is an important one for the simulated autocorrelations, and many of the simulated autocorrelations for the 25 portfolios do not significantly fit a normal distribution. For example, Figure 2 shows the distribution of simulated lag 1 autocorrelations for the portfolio corresponding to stocks in the smallest quintile of both market equity and book-to-market equity. As indicated by the results of the output of the Shapiro-Wilks test for normality, one cannot assume that these autocorrelations are drawn from a normal distribution. Figure 2: (Small, Low) Lag 1 s.1.8.6.4.2 -.2 -.4 -.6 -.8 Fitted Normal Parameter Estimates Type Parameter Estimate Lower 95% Upper 95% Location Mu.7963 -.3111.4731 Dispersion Sigma.313638.28834.343834 Goodness-of-Fit Test Shapiro-Wilk W Test W Prob<W.974157.391 6
For each lag i in a given portfolio, it was then determined whether the lag i autocorrelation of the returns when in their historical order fell within the confidence interval constructed using the simulated autocorrelations. If the autocorrelation of the returns when in their historical order did not fall within the confidence interval, it was considered to be significant. For example, the lag 1 autocorrelation for the portfolio corresponding to stocks in the largest quintile of both market equity and book-to-market equity was calculated to be.636. Based on the simulated autocorrelations for this lag on this portfolio, the 95% confidence interval was determined to be [-.673,.626]. Since.636 falls outside this confidence interval, it was considered to be a significant (lag 1) autocorrelation. Similarly, Figure 3 shows the autocorrelations and confidence intervals for all 12 lags for this same portfolio. Significant autocorrelations in the above table are bolded. Thus, for this portfolio, the lag 1, 3, and 9 autocorrelations were determined to be significant. Figure 3: s and Confidence Intervals for (Big, High) Portfolio Lag Confidence Interval Lower Bound Upper Bound 1.636 -.673.626 2 -.193 -.57.634 3 -.126 -.67.747 4 -.458 -.735.695 5.498 -.628.647 6 -.551 -.59.564 7.53 -.65.65 8 -.172 -.558.666 9.911 -.611.681 1.3 -.69.697 11 -.92 -.624.69 12 -.363 -.733.645 7
The confidence intervals can also be represented graphically, as in Figure 4. The significant autocorrelations are noted with a red-colored point. Figure 4: Graph of s and Confidence Intervals for (Big, High) Portfolio.1.5. -.5 -.1 -.15 2 4 6 8 1 12 Preliminary Observations about Simulation Results The graphs for all 25 Fama French portfolios are presented in Appendix 2. Figure 5 summarizes the significant autocorrelations. The blue highlighted boxes indicate a significant positive autocorrelation, and the yellow highlighted boxes indicate a significant negative autocorrelation. The number(s) in each box indicate the lag(s) at which significant autocorrelation occur. 8
Figure 5: Significant s for Entire Period (1926 22) Market Equity (ME) Small 4% 6% 8% Big Book-to-Market Equity (BE/ME) Low 4% 8 6% 8% 8 1, 9 9 High 1,7 3, 6 12 9,12 1, 9 3 Positive Negative Three major observations seem to emerge from Figure 5. First, significant autocorrelations occur for portfolios in the 6 1% quintiles of market equity. Secondly, significant autocorrelations occur for portfolios in the 6 1% quintiles of book-to-market equity as well. Lastly, the most common lag for a significant autocorrelation is 9 months. Most of the significant lag 9 autocorrelations are negative, but for the (Big, High) portfolio, it is positive. Interpretation of Results At first, one may tend to conclude that, given the multiple occurrences of a significant lag 9 autocorrelation, there is a credible relationship between returns during month t and month t + 9. Intuitively, however, it seems unlikely that such a relationship between returns in the current month and returns 9 months prior would credibly exist, and that simulation methods, similar to ones used in this paper, could consistently replicate such a conclusion. Furthermore, given that for each portfolio 12 autocorrelations were 9
calculated, one would expect, at a 95% significance level, that 1 2 12 =.6 autocorrelations would be significant simply due to chance. In light of this expectation, it is difficult to dismiss chance as a reason for the significant lag 9 autocorrelations. One must also question the extent to which the significant autocorrelations (lag 9 or otherwise) are due to returns in the prewar period, particularly around the Great Depression. To determine the extent stock return data during the time of the Depression has an impact on the existence of significant autocorrelations, the simulation described above was rerun on the 25 portfolios, once using only prewar returns (i.e., 1926 1946) and postwar returns (i.e., 1947 22). Appendices 3a and 3b show the autocorrelations of lags 1 12 months for each of the portfolios and the associated 95% confidence interval constructed using the simulated autocorrelations. Correlations that are significant (i.e., correlations that fall outside the simulation-constructed confidence interval) are bolded. The significant autocorrelations are summarized in Figures 5a and 5b below. 1
Figure 5a: Significant s for Prewar Period (1926 1946) Market Equity (ME) Small 4% 6% 8% Big Book-to-Market Equity (BE/ME) Low 4% 6% 8% High 2 5 1 5 8 12 1 12 1 1 2, 3, 4, 6, 7 2 7 1 Positive Negative Figure 5b: Significant s for Postwar Period (1947 22) Market Equity (ME) Small 4% 6% 8% Big Book-to-Market Equity (BE/ME) Low 4% 6% 8% High 11 1 12 1 5 2 4 1 1 4 8 3 6, 9 6 2 4 Positive Negative The pattern of significant autocorrelations is considerably different for the prewar period versus the postwar period, and both patterns also differ considerably from the pattern of significant autocorrelations for the 25 portfolios using the returns over the entire 1926 22 period (as shown in Figure 5). More specifically, there does not seem to be a discernable relationship between either market equity or book-to-market equity 11
and the existence of significant autocorrelations. Furthermore, in neither pattern does any given lag appear more than three times (both lag 2 in the prewar pattern and lag 8 in the postwar pattern appear three times). Perhaps most noticeable is the relatively low frequency of a significant lag 9 autocorrelation. The lag 9 autocorrelation is never significant for the prewar data, and for the postwar data, it only occurs once, in the (Big, Low) portfolio. Not only did this portfolio have a significant lag 9 autocorrelation when data over the entire period were used, but the lag 9 autocorrelation in the postwar data is positive, whereas most of the significant lag 9 autocorrelations for the portfolios that data over the entire period are negative. Thus, one may doubt whether the consistent significance of the lag 9 autocorrelation persists today or is a phenomenon of the return data during the time of the Depression. While this is doubt is one expressed by many in the past (e.g., Kim, Nelson, and Startz (1991), Daniel (1994), and Bidarkota and McCulloch (1996)), it may be possible that longer lags must be analyzed in order to find a persistently significant autocorrelation; Carmel and Young (1997), for example, found a significantly negative autocorrelation to occur at lag 12 months (though, admittedly, their findings pertained to broader based U.S. stock indices and not portfolios created using the Fama French factors). Conclusion While the results of the simulation suggest that a significant lag 9 autocorrelation may exist for portfolios whose stocks fall into certain quintiles or market equity and book-to-market equity, with the lag 9 correlation to be more likely significant for 12
portfolios in the larger quintiles of both market equity and book-to-market equity, one must be careful to accept such a conclusion. On statistical grounds, one would expect.6 significant autocorrelations for each portfolio so one cannot dismiss chance as a reason for the significant lag 9 autocorrelations. Furthermore, it seems counterintuitive that returns in the current month have a concrete relationship with returns 9 months prior; intuition suggests that autocorrelations at lags 1 and 2 are more likely to be significant. The pattern of significant autocorrelations for the postwar period (as shown in Figure 5b) supports this intuition (though, again, one must not dismiss chance as a reason for their occurrence, particularly when the lag 1 or 2 autocorrelation is the only significant autocorrelation for a given portfolio). One question that would be interesting to explore in future research is why there are no significant autocorrelations for small-cap stocks (i.e., stocks having low market equity), as illustrated in Figure 5. In addressing this question, one could investigate the amount of turnover in the small-cap portfolios (i.e., whether the number of securities changes considerably from year to year. Also interesting would be to repeat the analysis conducted in this paper using Fama and French s equal-weighed portfolios. While Fama and French (1988) and Jegadeesh (1991) do not find significant autocorrelations for value-weighted portfolios, this paper, as well as one by Daniel and Torous (1995), do find significant autocorrelations over various lags in value-weighed portfolios. It would be interesting to see whether the impact of market equity and book-to-market equity are influenced by the choice of value- versus equal-weighted portfolios that are created based on the quintiles of the Fama French factors. 13
References Balvers, Ronald, Yangru Wu, and Erik Gilliland, 2, Mean Reversion across National Stock Markets and Parametric Contrarian Investment Strategies, Journal of Finance 55, 745 772. Bidarkota, Prasad and J. Huston McCulloch, 1996, Real Stock Returns: Non-normality, Seasonality, and Volatility Persistence, But No Predictability, Working paper, Ohio State University. Carmel, Jonathan Paul and Martin R. Young, 1997, Long Horizon Mean Reversion in the Stock Market: The Postwar Years, working paper, University of Michigan Business School. Daniel, Kent and Walter Torous, 1995, Common Stock Returns and the Business Cycle, Working paper, Northwestern University. Fama, Eugene, and Kenneth French, 1988, Permanent and Temporary Components of Stock Prices, Journal of Political Economy 96, 246 273. Fama, Eugene, and Kenneth French, 1992, The Cross-Section of Expected Stock Returns, Journal of Finance 47, 427 465. Fama, Eugene, and Kenneth French, 1996, Multifactor Explanations of Asset Pricing Anomalies, Journal of Finance 55 84. Jegadeesh, Narasimhan, 1991, Seasonality in Stock Price Mean Reversion: Evidence from the U.S. and the U.K., Journal of Finance 46 1427 1444. Kim, Myung J., Charles R. Nelson, and Richard Startz, 1991, Mean Reversion in Stock Prices? A Reappraisal of the Empirical Evidence, Review of Economic Studies 58, 515 528. Lakonishok, Josef, Andrei Shleifer, and Robert W. Vishny, 1994, The Impact of Institutional Trading on Stock Prices, Journal of Financial Economics 32, 23 33. Lamoureux, Christopher G. and Guofu Zhou 1996, Temporary Components of Stock Returns: What Do the Data Tell Us? Review of Financial Studies 9, 133 159. 14
Appendix 1: s for 25 Fama French Portfolios *Portfolio (i, j) refers to the portfolio of the ith quintile of market equity and the jth quintile of book-to-market equity. s for Portfolio (1, 1) s for Portfolio (1, 2).7.6.5.4.3.2.1 -.1 -.2 -.3 -.4 1 2 3 4 5 6 7 8 9 1 11 12.6.4.2 -.2 -.4 -.6 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (1, 3) s for Portfolio (1, 4).5.4.4.3.3.2.2.1 -.1.1 -.1 -.2 -.2 -.3 -.3 1 2 3 4 5 6 7 8 9 1 11 12 -.4 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (1, 5) s for Portfolio (2, 1).6.4.2 -.2 -.4 -.6 -.8 1 2 3 4 5 6 7 8 9 1 11 12.5.4.3.2.1 -.1 -.2 -.3 -.4 -.5 -.6 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (2, 2) s for Portfolio (2, 3).8.6.6.4.4.2.2 -.2 -.4 -.2 -.4 -.6 -.6 -.8 -.8 1 2 3 4 5 6 7 8 9 1 11 12 -.1 1 2 3 4 5 6 7 8 9 1 11 12 15
Appendix 1 (continued) s for Portfolio (2, 4) s for Portfolio (2, 5).4.3.2.1 -.1 -.2 -.3 -.4 -.5 -.6 -.7 1 2 3 4 5 6 7 8 9 1 11 12.6.4.2 -.2 -.4 -.6 -.8 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (3, 1) s for Portfolio (3, 2).8.4.6.2.4.2 -.2 -.2 -.4 -.6 -.4 -.8 -.6 1 2 3 4 5 6 7 8 9 1 11 12 -.1 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (3, 3) s for Portfolio (3, 4).6.8.4.6.2 -.2 -.4 -.6.4.2 -.2 -.4 -.6 -.8 -.8 -.1 1 2 3 4 5 6 7 8 9 1 11 12 -.1 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (3, 5) s for Portfolio (4, 1).2.6.1.4 -.1 -.2 -.3 -.4 -.5.2 -.2 -.6 -.7 -.4 -.8 1 2 3 4 5 6 7 8 9 1 11 12 -.6 1 2 3 4 5 6 7 8 9 1 11 12 16
Appendix 1 (continued) s for Portfolio (4, 2) s for Portfolio (4, 3).5.6.4.3.2.1 -.1 -.2 -.3 -.4.4.2 -.2 -.4 -.6 -.5 1 2 3 4 5 6 7 8 9 1 11 12 -.8 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (4, 4) s for Portfolio (4, 5).6.1.5.4.3.2.1 -.1 -.2 -.3.8.6.4.2 -.2 -.4 1 2 3 4 5 6 7 8 9 1 11 12 -.4 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (5, 1) s for Portfolio (5, 2).6.4.2 -.2 -.4 -.6 -.8 -.1 -.12 -.14 -.16 1 2 3 4 5 6 7 8 9 1 11 12.8.6.4.2 -.2 -.4 -.6 1 2 3 4 5 6 7 8 9 1 11 12 s for Portfolio (5, 3) s for Portfolio (5, 4).6.6.5.4.4.2.3.2.1 -.2 -.4 -.6 -.1 -.8 -.2 -.1 -.3 1 2 3 4 5 6 7 8 9 1 11 12 -.12 1 2 3 4 5 6 7 8 9 1 11 12 17
Appendix 1 (continued) s for Portfolio (5, 5).15.1.5 -.5 -.1 -.15 1 2 3 4 5 6 7 8 9 1 11 12 18
Appendix 2: s and Confidence Intervals for 25 Fama French Portfolios *Portfolio (i, j) refers to the portfolio of the ith quintile of market equity and the jth quintile of book-to-market equity. s and Confidence Intervals for (1, 1) Portfolio s and Confidence Intervals for (1, 2) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12 s and Confidence Intervals for (1, 3) Portfolio s and Confidence Intervals for (1, 4) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12.1.8.6.4.2 -.2 -.4 -.6 -.8 2 4 6 8 1 12 s and Confidence Intervals for (1, 5) Portfolio s and Confidence Intervals for (2, 1) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12 s and Confidence Intervals for (2, 2) Portfolio s and Confidence Intervals for (2, 3) Portfolio.1.8.6.4.2 -.2 -.4 -.6.1.8.6.4.2 -.2 -.4 -.6 -.8 -.8 2 4 6 8 1 12 -.1 2 4 6 8 1 12 19
Appendix 2 (continued) s and Confidence Intervals for (2, 4) Portfolio s and Confidence Intervals for (2, 5) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12.1.8.6.4.2 -.2 -.4 -.6 -.8 2 4 6 8 1 12 s and Confidence Intervals for (3, 1) Portfolio s and Confidence Intervals for (3, 2) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8 2 4 6 8 1 12.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12 s and Confidence Intervals for (3, 3) Portfolio s and Confidence Intervals for (3, 4) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12 -.1 2 4 6 8 1 12 s and Confidence Intervals for (3, 5) Portfolio s and Confidence Intervals for (4, 1) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12 -.1 2 4 6 8 1 12 2
Appendix 2 (continued) s and Confidence Intervals for (4, 2) Portfolio s and Confidence Intervals for (4, 3) Portfolio.1.8.6.4.2 -.2 -.4 -.6 -.8 2 4 6 8 1 12.1.8.6.4.2 -.2 -.4 -.6 -.8 -.1 2 4 6 8 1 12 s and Confidence Intervals for (4, 4) Portfolio s and Confidence Intervals for (4, 5) Portfolio.1.1.5.5. -.5. -.5 -.1 -.1 -.15 2 4 6 8 1 12 -.15 2 4 6 8 1 12 s and Confidence Intervals for (5, 1) Portfolio s and Confidence Intervals for (5, 2) Portfolio.1.5 -.5 -.1.1.8.6.4.2 -.2 -.4 -.6 -.8 -.15 2 4 6 8 1 12 -.1 2 4 6 8 1 12 s and Confidence Intervals for (5, 3) Portfolio s and Confidence Intervals for (5, 4) Portfolio.1.1.8.6.5.4.2 -.2 -.4 -.6 -.5 -.1 -.8 2 4 6 8 1 12 -.15 2 4 6 8 1 12 21
Appendix 2 (continued) s and Confidence Intervals for (5, 5) Portfolio.1.5 -.5 -.1 -.15 2 4 6 8 1 12 22
Appendix 3a: s and Confidence Intervals for 25 Fama French Portfolios using Prewar Data *ME Market Equity, ME/BE Market-to-Book Equity. The quintile naming scheme is as discussed on Page 2. Significant autocorrelations are bolded. ME BE/ME ME BE/ME ME BE/ME ME BE/ME ME BE/ME Small Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1.828 -.1136.1289 1 -.983 -.1155.1613 1 -.922 -.1244.199 1 -.739 -.1216.1299 1.73 -.1334.1141 2 -.511 -.1187.1336 2.217 -.1148.1151 2 -.115 -.1213.138 2.382 -.123.1425 2 -.162 -.1199.1372 3 -.157 -.127.1217 3.41 -.126.15 3.349 -.1326.1312 3 -.94 -.1157.1232 3 -.16 -.1251.1366 4 -.36 -.1145.1363 4 -.516 -.1221.1393 4.26 -.1244.1392 4.37 -.1179.1262 4 -.42 -.124.132 5 -.78 -.122.1245 5.1496 -.125.1283 5 -.277 -.1318.1449 5 -.512 -.116.146 5.529 -.1165.1568 6 -.24 -.132.1284 6.412 -.182.1255 6.998 -.1228.1256 6.14 -.1246.1268 6 -.53 -.1178.1475 7.633 -.183.1132 7 -.661 -.116.1249 7.213 -.173.1388 7 -.291 -.1169.1237 7 -.39 -.153.1349 8 -.282 -.162.134 8.612 -.1211.1317 8.343 -.1266.1327 8 -.444 -.1333.1177 8.1767 -.12.1618 9 -.16 -.1268.1288 9 -.285 -.195.1565 9 -.735 -.1248.1545 9 -.1 -.1233.1768 9.647 -.1226.1328 1 -.786 -.1262.1224 1.92 -.158.154 1 -.688 -.1145.1347 1 -.1721 -.1429.1395 1 -.497 -.1255.115 11 -.987 -.1266.1388 11.816 -.1213.1411 11 -.524 -.1292.1154 11.19 -.1262.1177 11 -.8 -.123.1291 12.29 -.1215.1447 12 -.847 -.1126.131 12 -.559 -.1358.1212 12.382 -.1163.115 12.24 -.117.1316 4% Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1.361 -.1228.1327 1.781 -.1157.1285 1 -.663 -.1159.1251 1.61 -.136.1386 1 -.1229 -.153.1384 2 -.1312 -.135.1133 2.121 -.185.1364 2 -.512 -.119.134 2 -.122 -.119.1277 2 -.8 -.1273.134 3.129 -.1244.1294 3.452 -.1176.134 3 -.65 -.1139.136 3.561 -.126.196 3.1 -.138.1237 4 -.15 -.1241.1296 4.35 -.1115.185 4 -.295 -.122.1516 4.211 -.1227.133 4.3 -.1166.1218 5 -.13 -.1266.1168 5 -.447 -.1223.1393 5 -.77 -.176.1234 5 -.164 -.1173.1516 5.386 -.1234.1145 6 -.35 -.1412.1179 6.788 -.153.1399 6 -.661 -.193.127 6 -.474 -.1265.1253 6 -.1211 -.1211.129 7.218 -.1283.1233 7.374 -.1388.1582 7.449 -.1312.1341 7 -.111 -.1388.1384 7.582 -.1135.1199 8.51 -.1321.128 8.748 -.1325.1378 8 -.24 -.188.1387 8 -.118 -.1177.1252 8 -.1127 -.1434.1215 9.346 -.131.1182 9 -.1274 -.1316.1446 9 -.632 -.132.1675 9 -.684 -.127.122 9.965 -.1222.1551 1 -.54 -.1174.1227 1 -.93 -.1267.116 1.726 -.1224.1213 1.852 -.1347.1195 1 -.382 -.124.1287 11 -.832 -.1131.1455 11 -.83 -.1432.1218 11 -.463 -.1239.1529 11.599 -.1361.1158 11 -.578 -.138.1399 12.662 -.1179.1224 12 -.812 -.1282.1159 12.448 -.131.1264 12.298 -.1188.1248 12.1665 -.1348.1221 6% Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1 -.178 -.1349.1234 1 -.329 -.1312.1277 1.759 -.1119.159 1 -.79 -.1154.1177 1 -.175 -.1162.1291 2.269 -.1214.1287 2.224 -.1192.122 2 -.558 -.1222.146 2.36 -.123.11 2 -.681 -.117.175 3 -.974 -.1299.1395 3.369 -.182.1181 3.891 -.1282.1226 3.695 -.1393.1558 3.198 -.1132.1381 4.55 -.173.1133 4 -.54 -.1287.1186 4.277 -.1192.1246 4 -.182 -.147.1319 4.14 -.1178.1397 5 -.863 -.1129.1692 5 -.523 -.166.1215 5 -.61 -.111.128 5.994 -.113.1223 5.164 -.1148.1446 6.951 -.1116.1317 6.19 -.1466.1125 6 -.14 -.115.1525 6 -.174 -.1153.1332 6.178 -.132.167 7 -.847 -.1213.1233 7.79 -.1319.131 7.519 -.1483.135 7 -.293 -.1194.1399 7 -.346 -.1183.165 8.538 -.1255.1251 8.89 -.1268.1293 8 -.238 -.12.1297 8.62 -.1237.126 8 -.118 -.1231.1192 9 -.669 -.1251.1288 9 -.423 -.1381.1288 9 -.437 -.1344.123 9 -.6 -.1257.1129 9.111 -.1227.1554 1.513 -.1365.142 1 -.626 -.115.173 1 -.248 -.14.1522 1.135 -.1422.1157 1 -.1 -.1487.1374 11 -.12 -.1265.1281 11 -.472 -.1299.116 11 -.174 -.1337.1355 11 -.164 -.138.117 11.135 -.129.1341 12 -.768 -.1325.1321 12 -.5 -.112.1444 12 -.313 -.126.1458 12 -.1479 -.1328.1595 12 -.836 -.1245.136 8% Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1.1187 -.1293.1156 1.966 -.123.1266 1 -.45 -.1287.172 1 -.1242 -.1119.1497 1 -.32 -.1285.1337 2 -.952 -.157.1485 2.1344 -.18.1171 2.236 -.1216.1315 2.59 -.1424.1224 2 -.427 -.119.1261 3 -.344 -.1257.15 3.156 -.19.1389 3.518 -.1198.1146 3 -.1122 -.1287.1144 3.848 -.1298.1256 4.427 -.129.1318 4.148 -.11.1153 4 -.328 -.1184.1183 4.748 -.1234.1144 4.413 -.1357.1197 5.17 -.1226.1147 5.162 -.1295.1318 5 -.915 -.123.1237 5 -.11 -.164.1219 5.187 -.121.1229 6 -.791 -.146.1312 6.1156 -.1222.184 6 -.372 -.1366.1256 6.63 -.1392.1349 6.554 -.1187.135 7.236 -.1252.1299 7.1332 -.1233.1192 7 -.37 -.1216.1253 7 -.372 -.129.141 7.268 -.134.1452 8 -.775 -.138.1153 8.899 -.142.1432 8 -.635 -.1237.1214 8.147 -.1166.1366 8.676 -.119.1227 9 -.1256 -.1256.1212 9 -.318 -.1227.1118 9 -.22 -.1399.1341 9.671 -.1235.1161 9.535 -.1423.1433 1 -.1482 -.127.122 1.1272 -.1264.1274 1 -.864 -.1166.1183 1 -.477 -.1242.1237 1 -.687 -.1266.1252 11 -.939 -.1236.1199 11 -.266 -.1292.143 11.456 -.1354.117 11.399 -.1142.1255 11 -.245 -.1264.1313 12.365 -.1646.1259 12.817 -.117.1331 12 -.764 -.124.1291 12 -.388 -.1338.1158 12.583 -.121.1476 Big Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1 -.23 -.116.1223 1.143 -.122.185 1 -.137 -.143.1213 1.471 -.126.132 1 -.22 -.1359.1297 2 -.636 -.133.1268 2 -.179 -.1348.1214 2.167 -.1369.1336 2.26 -.1251.1231 2 -.68 -.133.1489 3.46 -.1373.118 3 -.451 -.1425.1179 3 -.221 -.1278.1176 3 -.554 -.113.1379 3.28 -.1225.1512 4.857 -.1152.1274 4 -.234 -.1256.1211 4 -.131 -.1139.1545 4 -.626 -.1182.14 4 -.159 -.1147.1335 5 -.6 -.1229.1424 5.883 -.169.1293 5 -.1173 -.1294.126 5.469 -.1199.116 5 -.535 -.165.1314 6.1 -.1179.1324 6.57 -.1277.1144 6.651 -.1367.1446 6.723 -.144.1258 6.36 -.1246.1498 7.396 -.1211.139 7 -.54 -.1263.1176 7.1335 -.1116.1334 7.967 -.1166.1335 7 -.631 -.1215.138 8 -.235 -.1229.1165 8 -.1168 -.1249.1254 8 -.259 -.1466.1118 8.316 -.1412.116 8 -.23 -.155.1426 9 -.695 -.1139.1128 9 -.131 -.1377.126 9 -.1297 -.1334.1261 9.522 -.1363.1226 9 -.266 -.1128.1194 1.651 -.1395.121 1 -.246 -.1392.1231 1.378 -.128.19 1.17 -.1139.1232 1.57 -.127.136 11.351 -.1182.1293 11.58 -.1559.1193 11 -.61 -.1545.188 11 -.719 -.1391.1388 11.78 -.174.1322 12.372 -.1325.1241 12.88 -.119.1615 12 -.364 -.128.199 12.134 -.1197.161 12 -.467 -.1175.1542 23
Appendix 3b: s and Confidence Intervals for 25 Fama French Portfolios using Postwar Data *ME Market Equity, ME/BE Market-to-Book Equity. The quintile naming scheme is as discussed on Page 2. Significant autocorrelations are bolded. ME BE/ME ME BE/ME ME BE/ME ME BE/ME ME BE/ME Small Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1.1 -.762.735 1 -.23 -.747.627 1.42 -.722.668 1 -.366 -.735.676 1.752 -.764.752 2.419 -.713.677 2 -.1 -.794.818 2 -.382 -.721.718 2 -.164 -.738.971 2.386 -.743.89 3 -.34 -.841.723 3.262 -.763.736 3 -.741 -.773.772 3.534 -.745.733 3.47 -.722.727 4 -.462 -.834.715 4.144 -.858.734 4.377 -.82.798 4 -.22 -.822.875 4 -.155 -.84.757 5.53 -.713.77 5.318 -.68.78 5.59 -.615.819 5.119 -.85.745 5 -.464 -.84.862 6.467 -.777.657 6 -.19 -.728.81 6 -.258 -.736.673 6.1 -.745.721 6.445 -.82.79 7 -.218 -.742.75 7 -.259 -.741.798 7.68 -.91.788 7.363 -.887.839 7.259 -.71.729 8 -.52 -.73.837 8 -.414 -.818.814 8.216 -.716.826 8.293 -.73.687 8 -.41 -.689.845 9.65 -.764.726 9 -.94 -.83.842 9 -.37 -.834.758 9.419 -.824.749 9 -.128 -.79.71 1.131 -.797.736 1 -.177 -.81.729 1.177 -.739.781 1 -.626 -.748.813 1.844 -.712.764 11 -.247 -.61.871 11.1616 -.694.749 11 -.145 -.858.841 11.32 -.854.74 11 -.415 -.698.72 12.16 -.797.795 12 -.1 -.789.749 12 -.447 -.898.753 12.121 -.774.881 12.33 -.882.748 4% Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1.574 -.753.832 1.34 -.751.619 1.129 -.838.748 1 -.559 -.744.787 1.144 -.747.822 2 -.527 -.765.727 2 -.961 -.789.87 2.136 -.735.814 2 -.368 -.749.682 2.311 -.71.72 3 -.396 -.86.82 3 -.71 -.756.7 3.25 -.717.718 3 -.318 -.755.668 3 -.163 -.713.761 4.12 -.761.754 4.366 -.834.72 4 -.165 -.699.783 4 -.271 -.731.742 4.415 -.745.731 5.749 -.77.645 5.32 -.73.856 5 -.118 -.86.68 5 -.666 -.832.85 5 -.44 -.726.797 6 -.411 -.747.726 6.86 -.671.946 6 -.9 -.742.727 6.155 -.73.873 6.126 -.73.722 7.541 -.63.797 7 -.57 -.82.723 7 -.3 -.787.772 7.256 -.72.77 7.95 -.784.766 8 -.217 -.75.825 8 -.88 -.888.726 8.7 -.743.729 8.37 -.762.775 8 -.25 -.818.77 9 -.256 -.78.654 9 -.469 -.661.73 9.687 -.724.753 9 -.447 -.875.771 9 -.52 -.718.669 1 -.449 -.811.72 1 -.282 -.754.823 1 -.658 -.836.776 1.383 -.98.739 1 -.24 -.771.798 11 -.173 -.696.913 11.331 -.71.848 11.12 -.744.682 11 -.337 -.794.671 11 -.359 -.824.763 12.38 -.845.658 12 -.116 -.667.717 12 -.244 -.73.716 12.7 -.789.897 12.85 -.799.88 6% Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1 -.167 -.818.77 1 -.11 -.72.887 1 -.342 -.735.874 1 -.837 -.76.753 1.819 -.813.651 2 -.121 -.73.761 2 -.4 -.66.85 2.261 -.759.797 2 -.315 -.7.79 2 -.435 -.98.875 3.216 -.755.739 3.373 -.89.699 3 -.18 -.872.781 3.595 -.694.739 3 -.277 -.787.763 4 -.225 -.639.721 4.122 -.697.738 4 -.412 -.838.817 4.59 -.757.677 4 -.919 -.762.763 5 -.28 -.693.671 5.33 -.677.668 5.265 -.741.724 5.338 -.743.655 5 -.381 -.745.941 6.171 -.765.766 6 -.782 -.88.853 6 -.47 -.817.872 6 -.395 -.732.742 6 -.188 -.758.83 7 -.453 -.725.825 7 -.21 -.791.675 7 -.1 -.73.728 7.149 -.745.744 7 -.37 -.755.73 8.11 -.738.757 8.739 -.835.786 8.358 -.75.742 8.319 -.82.632 8 -.271 -.857.877 9.133 -.77.81 9 -.176 -.869.835 9 -.162 -.648.84 9 -.42 -.671.799 9.29 -.839.764 1 -.5 -.736.723 1 -.127 -.784.643 1 -.16 -.794.758 1.48 -.694.726 1.121 -.759.767 11.121 -.786.829 11 -.3 -.696.592 11.11 -.627.689 11 -.672 -.788.773 11 -.246 -.744.573 12.534 -.72.76 12.316 -.798.785 12 -.216 -.758.816 12 -.121 -.852.81 12 -.95 -.658.781 8% Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1.327 -.841.638 1.68 -.666.664 1.44 -.839.766 1 -.396 -.757.79 1.411 -.745.632 2.318 -.718.611 2 -.425 -.715.848 2.12 -.687.798 2 -.586 -.84.641 2.496 -.635.718 3.7 -.692.79 3 -.154 -.81.684 3.759 -.698.632 3 -.171 -.716.697 3 -.363 -.696.76 4 -.4 -.773.696 4 -.243 -.816.62 4 -.184 -.713.89 4.314 -.848.772 4 -.196 -.746.758 5.235 -.74.757 5.25 -.748.797 5.219 -.744.796 5.499 -.592.747 5 -.18 -.79.662 6.326 -.67.838 6 -.518 -.761.728 6.94 -.769.751 6 -.2 -.774.745 6 -.22 -.925.747 7 -.91 -.783.748 7 -.13 -.896.735 7 -.511 -.749.721 7 -.146 -.771.693 7.728 -.729.764 8 -.127 -.857.744 8.914 -.729.866 8.82 -.729.78 8.117 -.728.768 8.4 -.793.791 9.29 -.682.758 9.29 -.717.757 9.543 -.753.712 9 -.33 -.88.763 9 -.28 -.715.793 1.728 -.767.737 1 -.23 -.816.69 1.582 -.775.794 1 -.397 -.719.723 1.31 -.689.769 11 -.142 -.672.88 11 -.58 -.851.732 11.12 -.718.89 11.56 -.827.724 11 -.297 -.783.644 12.34 -.746.852 12 -.62 -.787.787 12 -.242 -.727.879 12.69 -.742.87 12.496 -.756.696 Big Low 4% 6% 8% High Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lag Confidence Interval Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound Lower Bound Upper Bound 1 -.81 -.792.94 1 -.4 -.847.846 1.129 -.715.815 1 -.537 -.714.798 1.228 -.721.797 2.584 -.781.74 2 -.42 -.78.673 2.874 -.723.76 2.313 -.72.73 2.21 -.737.798 3.55 -.798.881 3 -.219 -.776.828 3 -.686 -.738.792 3 -.441 -.647.691 3.57 -.67.87 4 -.346 -.668.753 4.31 -.759.797 4 -.229 -.74.765 4.1148 -.658.712 4 -.456 -.88.811 5 -.435 -.779.771 5.21 -.871.746 5 -.59 -.675.881 5.5 -.852.89 5.333 -.719.762 6.982 -.783.775 6.881 -.858.712 6 -.28 -.656.714 6.139 -.743.74 6 -.582 -.712.732 7.748 -.79.84 7 -.483 -.827.745 7.82 -.687.776 7 -.569 -.686.781 7 -.486 -.652.653 8.165 -.689.793 8 -.44 -.832.76 8 -.18 -.84.82 8.72 -.717.796 8 -.12 -.699.688 9.1273 -.749.821 9.451 -.69.65 9.165 -.64.752 9.9 -.678.833 9 -.619 -.672.859 1.43 -.774.88 1.1 -.746.77 1.85 -.733.813 1 -.541 -.811.649 1.231 -.65.766 11 -.199 -.697.793 11 -.13 -.748.821 11.178 -.886.664 11 -.264 -.767.773 11.53 -.748.727 12 -.534 -.892.813 12 -.9 -.836.732 12.249 -.857.868 12.448 -.88.861 12 -.56 -.83.798 24