波动性能解决幼稚的投资组合难题吗?

IF 16.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Michael Curran, Ryan Zalla
{"title":"波动性能解决幼稚的投资组合难题吗?","authors":"Michael Curran, Ryan Zalla","doi":"10.1080/14697688.2023.2249996","DOIUrl":null,"url":null,"abstract":"AbstractWe investigate whether sophisticated volatility estimation improves the out-of-sample performance of mean-variance portfolio strategies relative to the naive 1/N strategy. The portfolio strategies rely solely upon second moments. Using a diverse group of portfolios and econometric models across multiple datasets, most models achieve higher Sharpe ratios and lower portfolio volatility that are statistically and economically significant relative to the naive rule, even after controlling for turnover costs. Our results suggest benefits to employing more sophisticated econometric models than the sample covariance matrix, and that mean-variance strategies often outperform the naive portfolio across multiple datasets and assessment criteria.Keywords: Mean-varianceNaive portfoliovolatilityJEL: G11G17 AcknowledgmentsWe thank Caitlin Dannhauser, Jesús Fernández-Villaverde, Alejandro Lopez-Lira, Rabih Moussawi, Michael Pagano, Nikolai Roussanov, Paul Scanlon, Frank Schorfheide, John Sedunov, Raman Uppal, and Raisa Velthuis for helpful comments. Christopher Antonello provided diligent research assistance.Disclosure statementNo potential conflict of interest was reported by the author(s).Supplemental dataSupplemental data for this article can be accessed online at http://dx.doi.org/10.1080/14697688.2023.2249996.Notes1 Instead of the portfolio strategy, our innovation explores a wide variety of econometric models. DeMiguel et al. (Citation2009b) find that the minimum-variance portfolio, though performing well relative to other portfolio strategies, significantly beats the 1/N strategy for only 1 in 7 of their datasets. Jagannathan and Ma (Citation2003) and Kirby and Ostdiek (Citation2012) innovate on the portfolio strategy, illustrating that short-sale constrained minimum-variance strategies and volatility-timing strategies enhance performance.2 We consider a wide range of mostly parametric econometric models. Non-parametric models using higher-frequency data (DeMiguel et al. Citation2013) and shrinkage approaches (Ledoit and Wolf Citation2017) also improve the accuracy of estimation. Daily frequency option-implied volatility reduces portfolio volatility, but never statistically significantly improves the Sharpe ratio relative to the 1/N strategy (DeMiguel et al. Citation2013). Although Johannes et al. (Citation2014) account for both estimation risk and time-varying volatility through eight variations of a similar class of constant and stochastic volatility models, we expand to more varied classes of volatility types with 14 econometric models. Initial investigations reveal our results to be at least as strong as Ledoit and Wolf (Citation2017).3 Our econometric estimation strategies yield improvements beyond the period and frequency differences.4 A portfolio strategy, whose covariance is estimated using a given econometric model, weakly dominates the naive benchmark if, for each performance criterion, the portfolio strategy performs at least as well as the naive benchmark across all datasets and performs significantly better in at least one dataset.5 For each portfolio strategy, we average the Sharpe ratios and portfolio volatility resulting from all 14 econometric models across all six datasets. Then we average Sharpe ratio and portfolio volatility across all three portfolio strategies.6 Our study benefits from incorporating recent advances in the computation of several models as in Vogiatzoglou (Citation2017), Chan and Eisenstat (Citation2018), and Kastner (Citation2019b). To reduce run-time, we employ fast, low-level languages, e.g. C++, that we program in parallel with hyperthreading and execute on clusters.7 Using a shorter time-sample across one dataset with a larger portfolio, they do not consider vector autoregression, vector error correction for non-stationarity, or either regime-switching or stochastic volatility models, which are computationally challenging and account for observed nuances of time-varying volatility.8 Preliminary evidence suggests that our results are at least as strong relative to the naive portfolio as what Ledoit and Wolf (Citation2017) find. Direct comparisons are more complicated in Ao et al. (Citation2019). Relative to the naive portfolio, initial experiments suggest that their MAXSER estimator performs better than our econometric models do in some comparisons, but that our models do better in most empirical comparisons.9 To isolate one study by DeMiguel et al. (Citation2009a), our paper employs improved econometric methods rather than more sophisticated portfolio constraints. Although not directly comparable, preliminary investigations reveal that our models improve performance relative to the naive portfolio by a greater ratio than DeMiguel et al. (Citation2009a) in terms of Sharpe ratios, portfolio volatility, and turnover costs.10 The use of shrinkage covariance matrices following Ledoit and Wolf (Citation2004, Citation2017) is less relevant with smaller portfolio choices as in our study.11 Letting wˆ denote our estimate of the optimal vector of portfolio weights w, the MSE bias-variance decomposition from econometrics is MSE(wˆ)=Var(wˆ)+Bias2(wˆ,w), where Bias(wˆ,w)=wˆ−w.12 While we attempt to cover the broad classes of econometric models, our set of econometric models is not exhaustive. For instance, we omit the shrinkage estimators of Hafner and Reznikova (Citation2012) and Ledoit and Wolf (Citation2003, Citation2017). Although these and other econometric models are interesting, our study is the most expansive in its coverage of econometric models.13 Detailed model, implementation, and robustness descriptions are relegated to the online appendix.14 Inference from finite samples is also much more informative regarding the expected return volatility rather than the expected mean return (Andersen and Teräsvirta Citation2009).15 Regularization implied by no short selling ensures invertibility of the resulting covariance matrix.16 First, a variation of our benchmark CP strategy (Equation5(5) wt,jMVP,comv=argminw∈RN|w′1=1⁡wΣˆtcomvw′.(5) ), for each of the strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ), we examine the corresponding portfolio given by naive investments across the 13 portfolios with respect to each of the econometric models. More precisely, consider the minimum-variance portfolio. We form a 14th portfolio strategy, wtMVP,com, which is equally invested across the 13 estimates of the true minimum-variance portfolio, i.e. wtMVP,com=113∑j=113wt,jMVP. Second, with respect to each of the econometric models, we examine the corresponding portfolio given by naive investments across the three strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ). More precisely, consider the VAR econometric model. We form a fourth portfolio strategy, wtVAR,comp that is equally invested across the three vectors of portfolio weights suggested by inputting the volatility estimates from the VAR model into strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ), i.e. wtVAR,comp=13∑k=13wt,VARk. 17 Standard and Poor's established Compustat in 1962 to serve the needs of financial analysts and back-filed information only for the firms that were deemed to be of the greatest interest to the analysts. The result is significantly sparser coverage prior to 1963 for a selected sample of well performing firms.18 Kenneth French provides full description at https://mba.tuck.dartmouth.edu/pages/faculty/ken.french/https://mba.tuck.dartmouth.edu/pages/faculty/ken.french/19 The risk-free (RF) asset is the one-month Treasury bill rate from Ibbotson Associates and proxies the return from investing in the money market. We exclude the risk-free rate from the investor's choice set; therefore, we exclude returns in excess of the risk-free rate.20 We also employ equal-weighting in robustness checks.21 Dataset 2's industry portfolios are popular among academics with the older Standard Industry Classification (SIC) scheme and longer data, while the broader dataset 3's sector portfolios with newer GICS codes are popular amongst practitioners.22 Covariance-based methods such as the minimum-variance portfolio may lower variance relative to the 1/N portfolio and thus raise Sharpe ratios. We therefore also consider returns. While the naive strategy performs well on dataset 1, and despite with weaker dominance over the naive strategy on dataset 6, other strategies dominate the naive strategy on datasets 2 through 5. Results are available upon request.23 Several papers in the literature consider transaction costs of 10 or 50 basis points (Kirby and Ostdiek Citation2012, DeMiguel et al. Citation2014) and others consider transactions costs that vary across stock size and through time (Brandt et al. Citation2009). With high turnover, assuming 50 basis points transactions costs conservatively biases our models away from beating the 1/N strategy.24 The forecast error is defined as the difference between expected returns using estimated portfolio weights and mean returns. The loss differential underlying the test looks at the difference of the squared forecast errors, and we calculate the the loss differential correcting for autocorrelation.25 We report only results for value-weighted data.26 Tables S2.1–3 in the online appendix report pairwise comparisons between the three portfolio variance strategies. For each evaluation criterion across most econometric models and datasets, the minimum-variance strategy performs the best and the volatility-timing strategy performs the weakest.27 To explain the poorer performance of datasets 1 and 3, first, the literature consistently finds weak performance with the Fama-French dataset (DeMiguel et al. Citation2009b); second, a simple correlation matrix of the six datasets shows that dataset 3 is the only dataset to be negatively correlated with the other datasets.28 Allocations can shift, requiring rebalancing turnover even for the naive portfolio. With turnover, expected returns are no larger, but standard deviations may be smaller or larger.29 To clarify, ‘✓’ =1, ‘✓*’ =2/3, ‘ ’ (blanks) =0, and ‘×’ =−1. We discount results that are significant at the 10% level by assigning a value of only 2/3 instead of 1.","PeriodicalId":1,"journal":{"name":"Accounts of Chemical Research","volume":"36 1","pages":"0"},"PeriodicalIF":16.4000,"publicationDate":"2023-09-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Can volatility solve the naive portfolio puzzle?\",\"authors\":\"Michael Curran, Ryan Zalla\",\"doi\":\"10.1080/14697688.2023.2249996\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"AbstractWe investigate whether sophisticated volatility estimation improves the out-of-sample performance of mean-variance portfolio strategies relative to the naive 1/N strategy. The portfolio strategies rely solely upon second moments. Using a diverse group of portfolios and econometric models across multiple datasets, most models achieve higher Sharpe ratios and lower portfolio volatility that are statistically and economically significant relative to the naive rule, even after controlling for turnover costs. Our results suggest benefits to employing more sophisticated econometric models than the sample covariance matrix, and that mean-variance strategies often outperform the naive portfolio across multiple datasets and assessment criteria.Keywords: Mean-varianceNaive portfoliovolatilityJEL: G11G17 AcknowledgmentsWe thank Caitlin Dannhauser, Jesús Fernández-Villaverde, Alejandro Lopez-Lira, Rabih Moussawi, Michael Pagano, Nikolai Roussanov, Paul Scanlon, Frank Schorfheide, John Sedunov, Raman Uppal, and Raisa Velthuis for helpful comments. Christopher Antonello provided diligent research assistance.Disclosure statementNo potential conflict of interest was reported by the author(s).Supplemental dataSupplemental data for this article can be accessed online at http://dx.doi.org/10.1080/14697688.2023.2249996.Notes1 Instead of the portfolio strategy, our innovation explores a wide variety of econometric models. DeMiguel et al. (Citation2009b) find that the minimum-variance portfolio, though performing well relative to other portfolio strategies, significantly beats the 1/N strategy for only 1 in 7 of their datasets. Jagannathan and Ma (Citation2003) and Kirby and Ostdiek (Citation2012) innovate on the portfolio strategy, illustrating that short-sale constrained minimum-variance strategies and volatility-timing strategies enhance performance.2 We consider a wide range of mostly parametric econometric models. Non-parametric models using higher-frequency data (DeMiguel et al. Citation2013) and shrinkage approaches (Ledoit and Wolf Citation2017) also improve the accuracy of estimation. Daily frequency option-implied volatility reduces portfolio volatility, but never statistically significantly improves the Sharpe ratio relative to the 1/N strategy (DeMiguel et al. Citation2013). Although Johannes et al. (Citation2014) account for both estimation risk and time-varying volatility through eight variations of a similar class of constant and stochastic volatility models, we expand to more varied classes of volatility types with 14 econometric models. Initial investigations reveal our results to be at least as strong as Ledoit and Wolf (Citation2017).3 Our econometric estimation strategies yield improvements beyond the period and frequency differences.4 A portfolio strategy, whose covariance is estimated using a given econometric model, weakly dominates the naive benchmark if, for each performance criterion, the portfolio strategy performs at least as well as the naive benchmark across all datasets and performs significantly better in at least one dataset.5 For each portfolio strategy, we average the Sharpe ratios and portfolio volatility resulting from all 14 econometric models across all six datasets. Then we average Sharpe ratio and portfolio volatility across all three portfolio strategies.6 Our study benefits from incorporating recent advances in the computation of several models as in Vogiatzoglou (Citation2017), Chan and Eisenstat (Citation2018), and Kastner (Citation2019b). To reduce run-time, we employ fast, low-level languages, e.g. C++, that we program in parallel with hyperthreading and execute on clusters.7 Using a shorter time-sample across one dataset with a larger portfolio, they do not consider vector autoregression, vector error correction for non-stationarity, or either regime-switching or stochastic volatility models, which are computationally challenging and account for observed nuances of time-varying volatility.8 Preliminary evidence suggests that our results are at least as strong relative to the naive portfolio as what Ledoit and Wolf (Citation2017) find. Direct comparisons are more complicated in Ao et al. (Citation2019). Relative to the naive portfolio, initial experiments suggest that their MAXSER estimator performs better than our econometric models do in some comparisons, but that our models do better in most empirical comparisons.9 To isolate one study by DeMiguel et al. (Citation2009a), our paper employs improved econometric methods rather than more sophisticated portfolio constraints. Although not directly comparable, preliminary investigations reveal that our models improve performance relative to the naive portfolio by a greater ratio than DeMiguel et al. (Citation2009a) in terms of Sharpe ratios, portfolio volatility, and turnover costs.10 The use of shrinkage covariance matrices following Ledoit and Wolf (Citation2004, Citation2017) is less relevant with smaller portfolio choices as in our study.11 Letting wˆ denote our estimate of the optimal vector of portfolio weights w, the MSE bias-variance decomposition from econometrics is MSE(wˆ)=Var(wˆ)+Bias2(wˆ,w), where Bias(wˆ,w)=wˆ−w.12 While we attempt to cover the broad classes of econometric models, our set of econometric models is not exhaustive. For instance, we omit the shrinkage estimators of Hafner and Reznikova (Citation2012) and Ledoit and Wolf (Citation2003, Citation2017). Although these and other econometric models are interesting, our study is the most expansive in its coverage of econometric models.13 Detailed model, implementation, and robustness descriptions are relegated to the online appendix.14 Inference from finite samples is also much more informative regarding the expected return volatility rather than the expected mean return (Andersen and Teräsvirta Citation2009).15 Regularization implied by no short selling ensures invertibility of the resulting covariance matrix.16 First, a variation of our benchmark CP strategy (Equation5(5) wt,jMVP,comv=argminw∈RN|w′1=1⁡wΣˆtcomvw′.(5) ), for each of the strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ), we examine the corresponding portfolio given by naive investments across the 13 portfolios with respect to each of the econometric models. More precisely, consider the minimum-variance portfolio. We form a 14th portfolio strategy, wtMVP,com, which is equally invested across the 13 estimates of the true minimum-variance portfolio, i.e. wtMVP,com=113∑j=113wt,jMVP. Second, with respect to each of the econometric models, we examine the corresponding portfolio given by naive investments across the three strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ). More precisely, consider the VAR econometric model. We form a fourth portfolio strategy, wtVAR,comp that is equally invested across the three vectors of portfolio weights suggested by inputting the volatility estimates from the VAR model into strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ), i.e. wtVAR,comp=13∑k=13wt,VARk. 17 Standard and Poor's established Compustat in 1962 to serve the needs of financial analysts and back-filed information only for the firms that were deemed to be of the greatest interest to the analysts. The result is significantly sparser coverage prior to 1963 for a selected sample of well performing firms.18 Kenneth French provides full description at https://mba.tuck.dartmouth.edu/pages/faculty/ken.french/https://mba.tuck.dartmouth.edu/pages/faculty/ken.french/19 The risk-free (RF) asset is the one-month Treasury bill rate from Ibbotson Associates and proxies the return from investing in the money market. We exclude the risk-free rate from the investor's choice set; therefore, we exclude returns in excess of the risk-free rate.20 We also employ equal-weighting in robustness checks.21 Dataset 2's industry portfolios are popular among academics with the older Standard Industry Classification (SIC) scheme and longer data, while the broader dataset 3's sector portfolios with newer GICS codes are popular amongst practitioners.22 Covariance-based methods such as the minimum-variance portfolio may lower variance relative to the 1/N portfolio and thus raise Sharpe ratios. We therefore also consider returns. While the naive strategy performs well on dataset 1, and despite with weaker dominance over the naive strategy on dataset 6, other strategies dominate the naive strategy on datasets 2 through 5. Results are available upon request.23 Several papers in the literature consider transaction costs of 10 or 50 basis points (Kirby and Ostdiek Citation2012, DeMiguel et al. Citation2014) and others consider transactions costs that vary across stock size and through time (Brandt et al. Citation2009). With high turnover, assuming 50 basis points transactions costs conservatively biases our models away from beating the 1/N strategy.24 The forecast error is defined as the difference between expected returns using estimated portfolio weights and mean returns. The loss differential underlying the test looks at the difference of the squared forecast errors, and we calculate the the loss differential correcting for autocorrelation.25 We report only results for value-weighted data.26 Tables S2.1–3 in the online appendix report pairwise comparisons between the three portfolio variance strategies. For each evaluation criterion across most econometric models and datasets, the minimum-variance strategy performs the best and the volatility-timing strategy performs the weakest.27 To explain the poorer performance of datasets 1 and 3, first, the literature consistently finds weak performance with the Fama-French dataset (DeMiguel et al. Citation2009b); second, a simple correlation matrix of the six datasets shows that dataset 3 is the only dataset to be negatively correlated with the other datasets.28 Allocations can shift, requiring rebalancing turnover even for the naive portfolio. With turnover, expected returns are no larger, but standard deviations may be smaller or larger.29 To clarify, ‘✓’ =1, ‘✓*’ =2/3, ‘ ’ (blanks) =0, and ‘×’ =−1. We discount results that are significant at the 10% level by assigning a value of only 2/3 instead of 1.\",\"PeriodicalId\":1,\"journal\":{\"name\":\"Accounts of Chemical Research\",\"volume\":\"36 1\",\"pages\":\"0\"},\"PeriodicalIF\":16.4000,\"publicationDate\":\"2023-09-26\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"1\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Accounts of Chemical Research\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.1080/14697688.2023.2249996\",\"RegionNum\":1,\"RegionCategory\":\"化学\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q1\",\"JCRName\":\"CHEMISTRY, MULTIDISCIPLINARY\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Accounts of Chemical Research","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1080/14697688.2023.2249996","RegionNum":1,"RegionCategory":"化学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"CHEMISTRY, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 1

摘要

在Ledoit和Wolf (Citation2004, Citation2017)之后,收缩协方差矩阵的使用与我们研究中较小的投资组合选择不太相关设w´表示我们对投资组合权重w的最优向量的估计,计量经济学的MSE偏差方差分解为MSE(w´)=Var(w´)+Bias2(w´,w),其中Bias(w´,w)=w´−w.12虽然我们试图涵盖广泛的计量经济模型类别,但我们的计量经济模型集并不详尽。例如,我们忽略了Hafner和Reznikova (Citation2012)和Ledoit和Wolf (Citation2003, Citation2017)的收缩估计量。虽然这些和其他计量经济模型很有趣,但我们的研究在计量经济模型的覆盖范围上是最广泛的详细的模型、实现和鲁棒性描述归到在线附录中有限样本的推断在预期收益波动方面也比预期平均收益更有信息量(Andersen和Teräsvirta Citation2009)不卖空所隐含的正则化保证了所得到的协方差矩阵的可逆性首先,我们的基准CP策略(Equation5(5) wt,jMVP,comv=argminw∈RN|w ' 1=1′wΣ´tcomvw ' .(5))的一个变体,对于每个策略(Equation2(2) wt,jMVP=argminw∈RN|w ' 1=1′wΣtj´w ' .(2)) - (Equation4(4) (wt,jVT)i=1/(Σ´tj)i,i∑i=1N1/(Σ´tj)i,ii=1,…,N.(4)),我们检查了相对于每个计量经济模型的13个投资组合中由naive投资给出的相应投资组合。更准确地说,考虑最小方差投资组合。我们形成了第14个投资组合策略wtMVP,com,该策略平均投资于13个真实最小方差投资组合的估计,即wtMVP,com=113∑j=113wt,jMVP。其次,对于每个计量经济模型,我们检查了三种策略(Equation2(2) wt,jMVP=argminw∈RN|w ' 1=1′wΣtj´w ' .(2)) - (Equation4(4) (wt,jVT)i=1/(Σ´tj)i,i∑i=1N1/(Σ´tj)i,ii=1,…,n(4))中由朴素投资给出的相应投资组合。更准确地说,考虑VAR计量经济模型。我们形成了第四个投资组合策略,wtVAR,comp,通过将VAR模型的波动率估计输入到策略(Equation2(2) wt,jMVP=argminw∈RN|w ' 1=1′wΣtj´w ' .(2)) - (Equation4(4) (wt,jVT)i=1/(Σ´tj)i,i∑i=1N1/(Σ´tj)i,ii=1,…,n(4))中,即wtVAR,comp=13∑k=13wt,VARk)。标准普尔于1962年建立了Compustat,以满足金融分析师的需求,并只向分析师认为最感兴趣的公司提供后台信息。结果表明,在1963年之前,对业绩良好的公司的选定样本的覆盖率明显较低无风险(RF)资产是Ibbotson Associates的一个月国库券利率,代表投资于货币市场的回报。我们将无风险利率从投资者的选择集中排除;因此,我们排除了超过无风险利率的收益我们还在稳健性检查中使用了等权重数据集2的行业组合在使用较旧的标准行业分类(SIC)方案和较长的数据的学者中很受欢迎,而更广泛的数据集3的行业组合使用较新的GICS代码在从业者中很受欢迎基于协方差的方法,如最小方差投资组合,相对于1/N的投资组合,可以降低方差,从而提高夏普比率。因此,我们也要考虑回报。虽然朴素策略在数据集1上表现良好,尽管在数据集6上优于朴素策略,但其他策略在数据集2到5上优于朴素策略。结果可应要求提供文献中的几篇论文认为交易成本为10或50个基点(Kirby and Ostdiek Citation2012, DeMiguel et al.)。Citation2014)和其他人考虑交易成本因股票规模和时间而异(Brandt等人)。Citation2009)。在高周转率的情况下,保守地假设50个基点的交易成本会使我们的模型偏离1/N策略预测误差定义为使用估计的投资组合权重的预期收益与平均收益之间的差值。测试背后的损失差分着眼于预测误差的平方之差,我们计算自相关的损失差分校正我们只报告价值加权数据的结果在线附录中的表S2.1-3报告了三种投资组合方差策略之间的两两比较。对于大多数计量经济模型和数据集的每个评估标准,最小方差策略表现最好,波动率定时策略表现最差。 27为了解释数据集1和3较差的性能,首先,文献一致发现Fama-French数据集的性能较差(DeMiguel等人)。Citation2009b);其次,6个数据集的简单相关矩阵显示,数据集3是唯一与其他数据集负相关的数据集配置可能会发生变化,即使对于幼稚的投资组合,也需要重新平衡周转。考虑到营业额,预期收益不会更大,但标准差可能更小,也可能更大澄清一下,“✓”= 1,“✓*”= 2/3,“(空白)= 0,=−1“×”。我们通过只赋值2/3而不是1来贴现在10%水平上显著的结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Can volatility solve the naive portfolio puzzle?
AbstractWe investigate whether sophisticated volatility estimation improves the out-of-sample performance of mean-variance portfolio strategies relative to the naive 1/N strategy. The portfolio strategies rely solely upon second moments. Using a diverse group of portfolios and econometric models across multiple datasets, most models achieve higher Sharpe ratios and lower portfolio volatility that are statistically and economically significant relative to the naive rule, even after controlling for turnover costs. Our results suggest benefits to employing more sophisticated econometric models than the sample covariance matrix, and that mean-variance strategies often outperform the naive portfolio across multiple datasets and assessment criteria.Keywords: Mean-varianceNaive portfoliovolatilityJEL: G11G17 AcknowledgmentsWe thank Caitlin Dannhauser, Jesús Fernández-Villaverde, Alejandro Lopez-Lira, Rabih Moussawi, Michael Pagano, Nikolai Roussanov, Paul Scanlon, Frank Schorfheide, John Sedunov, Raman Uppal, and Raisa Velthuis for helpful comments. Christopher Antonello provided diligent research assistance.Disclosure statementNo potential conflict of interest was reported by the author(s).Supplemental dataSupplemental data for this article can be accessed online at http://dx.doi.org/10.1080/14697688.2023.2249996.Notes1 Instead of the portfolio strategy, our innovation explores a wide variety of econometric models. DeMiguel et al. (Citation2009b) find that the minimum-variance portfolio, though performing well relative to other portfolio strategies, significantly beats the 1/N strategy for only 1 in 7 of their datasets. Jagannathan and Ma (Citation2003) and Kirby and Ostdiek (Citation2012) innovate on the portfolio strategy, illustrating that short-sale constrained minimum-variance strategies and volatility-timing strategies enhance performance.2 We consider a wide range of mostly parametric econometric models. Non-parametric models using higher-frequency data (DeMiguel et al. Citation2013) and shrinkage approaches (Ledoit and Wolf Citation2017) also improve the accuracy of estimation. Daily frequency option-implied volatility reduces portfolio volatility, but never statistically significantly improves the Sharpe ratio relative to the 1/N strategy (DeMiguel et al. Citation2013). Although Johannes et al. (Citation2014) account for both estimation risk and time-varying volatility through eight variations of a similar class of constant and stochastic volatility models, we expand to more varied classes of volatility types with 14 econometric models. Initial investigations reveal our results to be at least as strong as Ledoit and Wolf (Citation2017).3 Our econometric estimation strategies yield improvements beyond the period and frequency differences.4 A portfolio strategy, whose covariance is estimated using a given econometric model, weakly dominates the naive benchmark if, for each performance criterion, the portfolio strategy performs at least as well as the naive benchmark across all datasets and performs significantly better in at least one dataset.5 For each portfolio strategy, we average the Sharpe ratios and portfolio volatility resulting from all 14 econometric models across all six datasets. Then we average Sharpe ratio and portfolio volatility across all three portfolio strategies.6 Our study benefits from incorporating recent advances in the computation of several models as in Vogiatzoglou (Citation2017), Chan and Eisenstat (Citation2018), and Kastner (Citation2019b). To reduce run-time, we employ fast, low-level languages, e.g. C++, that we program in parallel with hyperthreading and execute on clusters.7 Using a shorter time-sample across one dataset with a larger portfolio, they do not consider vector autoregression, vector error correction for non-stationarity, or either regime-switching or stochastic volatility models, which are computationally challenging and account for observed nuances of time-varying volatility.8 Preliminary evidence suggests that our results are at least as strong relative to the naive portfolio as what Ledoit and Wolf (Citation2017) find. Direct comparisons are more complicated in Ao et al. (Citation2019). Relative to the naive portfolio, initial experiments suggest that their MAXSER estimator performs better than our econometric models do in some comparisons, but that our models do better in most empirical comparisons.9 To isolate one study by DeMiguel et al. (Citation2009a), our paper employs improved econometric methods rather than more sophisticated portfolio constraints. Although not directly comparable, preliminary investigations reveal that our models improve performance relative to the naive portfolio by a greater ratio than DeMiguel et al. (Citation2009a) in terms of Sharpe ratios, portfolio volatility, and turnover costs.10 The use of shrinkage covariance matrices following Ledoit and Wolf (Citation2004, Citation2017) is less relevant with smaller portfolio choices as in our study.11 Letting wˆ denote our estimate of the optimal vector of portfolio weights w, the MSE bias-variance decomposition from econometrics is MSE(wˆ)=Var(wˆ)+Bias2(wˆ,w), where Bias(wˆ,w)=wˆ−w.12 While we attempt to cover the broad classes of econometric models, our set of econometric models is not exhaustive. For instance, we omit the shrinkage estimators of Hafner and Reznikova (Citation2012) and Ledoit and Wolf (Citation2003, Citation2017). Although these and other econometric models are interesting, our study is the most expansive in its coverage of econometric models.13 Detailed model, implementation, and robustness descriptions are relegated to the online appendix.14 Inference from finite samples is also much more informative regarding the expected return volatility rather than the expected mean return (Andersen and Teräsvirta Citation2009).15 Regularization implied by no short selling ensures invertibility of the resulting covariance matrix.16 First, a variation of our benchmark CP strategy (Equation5(5) wt,jMVP,comv=argminw∈RN|w′1=1⁡wΣˆtcomvw′.(5) ), for each of the strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ), we examine the corresponding portfolio given by naive investments across the 13 portfolios with respect to each of the econometric models. More precisely, consider the minimum-variance portfolio. We form a 14th portfolio strategy, wtMVP,com, which is equally invested across the 13 estimates of the true minimum-variance portfolio, i.e. wtMVP,com=113∑j=113wt,jMVP. Second, with respect to each of the econometric models, we examine the corresponding portfolio given by naive investments across the three strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ). More precisely, consider the VAR econometric model. We form a fourth portfolio strategy, wtVAR,comp that is equally invested across the three vectors of portfolio weights suggested by inputting the volatility estimates from the VAR model into strategies (Equation2(2) wt,jMVP=argminw∈RN|w′1=1⁡wΣtjˆw′.(2) )–(Equation4(4) (wt,jVT)i=1/(Σˆtj)i,i∑i=1N1/(Σˆtj)i,ii=1,…,N.(4) ), i.e. wtVAR,comp=13∑k=13wt,VARk. 17 Standard and Poor's established Compustat in 1962 to serve the needs of financial analysts and back-filed information only for the firms that were deemed to be of the greatest interest to the analysts. The result is significantly sparser coverage prior to 1963 for a selected sample of well performing firms.18 Kenneth French provides full description at https://mba.tuck.dartmouth.edu/pages/faculty/ken.french/https://mba.tuck.dartmouth.edu/pages/faculty/ken.french/19 The risk-free (RF) asset is the one-month Treasury bill rate from Ibbotson Associates and proxies the return from investing in the money market. We exclude the risk-free rate from the investor's choice set; therefore, we exclude returns in excess of the risk-free rate.20 We also employ equal-weighting in robustness checks.21 Dataset 2's industry portfolios are popular among academics with the older Standard Industry Classification (SIC) scheme and longer data, while the broader dataset 3's sector portfolios with newer GICS codes are popular amongst practitioners.22 Covariance-based methods such as the minimum-variance portfolio may lower variance relative to the 1/N portfolio and thus raise Sharpe ratios. We therefore also consider returns. While the naive strategy performs well on dataset 1, and despite with weaker dominance over the naive strategy on dataset 6, other strategies dominate the naive strategy on datasets 2 through 5. Results are available upon request.23 Several papers in the literature consider transaction costs of 10 or 50 basis points (Kirby and Ostdiek Citation2012, DeMiguel et al. Citation2014) and others consider transactions costs that vary across stock size and through time (Brandt et al. Citation2009). With high turnover, assuming 50 basis points transactions costs conservatively biases our models away from beating the 1/N strategy.24 The forecast error is defined as the difference between expected returns using estimated portfolio weights and mean returns. The loss differential underlying the test looks at the difference of the squared forecast errors, and we calculate the the loss differential correcting for autocorrelation.25 We report only results for value-weighted data.26 Tables S2.1–3 in the online appendix report pairwise comparisons between the three portfolio variance strategies. For each evaluation criterion across most econometric models and datasets, the minimum-variance strategy performs the best and the volatility-timing strategy performs the weakest.27 To explain the poorer performance of datasets 1 and 3, first, the literature consistently finds weak performance with the Fama-French dataset (DeMiguel et al. Citation2009b); second, a simple correlation matrix of the six datasets shows that dataset 3 is the only dataset to be negatively correlated with the other datasets.28 Allocations can shift, requiring rebalancing turnover even for the naive portfolio. With turnover, expected returns are no larger, but standard deviations may be smaller or larger.29 To clarify, ‘✓’ =1, ‘✓*’ =2/3, ‘ ’ (blanks) =0, and ‘×’ =−1. We discount results that are significant at the 10% level by assigning a value of only 2/3 instead of 1.
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来源期刊
Accounts of Chemical Research
Accounts of Chemical Research 化学-化学综合
CiteScore
31.40
自引率
1.10%
发文量
312
审稿时长
2 months
期刊介绍: Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.
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