Forecasting the Equity Premium and Optimal Portfolios

Bjurgert, Johan, Edstrand, Marcus

January 2008

The expected equity premium is an important parameter in many financial models, especially within portfolio optimization. A good forecast of the future equity premium is therefore of great interest. In this thesis we seek to forecast the equity premium, use it in portfolio optimization and then give evidence on how sensitive the results are to estimation errors and how the impact of these can be minimized. Linear prediction models are commonly used by practitioners to forecast the expected equity premium, this with mixed results. To only choose the model that performs the best in-sample for forecasting, does not take model uncertainty into account. Our approach is to still use linear prediction models, but also taking model uncertainty into consideration by applying Bayesian model averaging. The predictions are used in the optimization of a portfolio with risky assets to investigate how sensitive portfolio optimization is to estimation errors in the mean vector and covariance matrix. This is performed by using a Monte Carlo based heuristic called portfolio resampling. The results show that the predictive ability of linear models is not substantially improved by taking model uncertainty into consideration. This could mean that the main problem with linear models is not model uncertainty, but rather too low predictive ability. However, we find that our approach gives better forecasts than just using the historical average as an estimate. Furthermore, we find some predictive ability in the the GDP, the short term spread and the volatility for the five years to come. Portfolio resampling proves to be useful when the input parameters in a portfolio optimization problem is suffering from vast uncertainty.

equity premium

Bayesian model averaging

linear prediction

estimation errors

Markowitz optimization

Business and economics

Ekonomi

Forecasting the Equity Premium and Optimal Portfolios

Bjurgert, Johan, Edstrand, Marcus

January 2008

<p>The expected equity premium is an important parameter in many financial models, especially within portfolio optimization. A good forecast of the future equity premium is therefore of great interest. In this thesis we seek to forecast the equity premium, use it in portfolio optimization and then give evidence on how sensitive the results are to estimation errors and how the impact of these can be minimized.</p><p>Linear prediction models are commonly used by practitioners to forecast the expected equity premium, this with mixed results. To only choose the model that performs the best in-sample for forecasting, does not take model uncertainty into account. Our approach is to still use linear prediction models, but also taking model uncertainty into consideration by applying Bayesian model averaging. The predictions are used in the optimization of a portfolio with risky assets to investigate how sensitive portfolio optimization is to estimation errors in the mean vector and covariance matrix. This is performed by using a Monte Carlo based heuristic called portfolio resampling.</p><p>The results show that the predictive ability of linear models is not substantially improved by taking model uncertainty into consideration. This could mean that the main problem with linear models is not model uncertainty, but rather too low predictive ability. However, we find that our approach gives better forecasts than just using the historical average as an estimate. Furthermore, we find some predictive ability in the the GDP, the short term spread and the volatility for the five years to come. Portfolio resampling proves to be useful when the input parameters in a portfolio optimization problem is suffering from vast uncertainty. </p>

equity premium

Bayesian model averaging

linear prediction

estimation errors

Markowitz optimization

Business and economics

Ekonomi

Optimalizační modely finančních rizik / Optimization Models of Financial Risk

Danko, Erik

January 2020

This diploma thesis deals with optimization models of financial risks. The first part, which is devoted to the theoretical background, introduces the basic concepts of optimization, modern portfolio theory, fundamental and technical analysis and statistical background. The basic principles of operation of modern portfolio theory are presented. The methods for analysis and selection of assets called Growth at A Reasonable Price and portfolio optimization approach according to Harry Markowitz were used with selected methods. The practical part is focused on the data analysis, selection of assets and design of a portfolio optimization model according to selected conditions with an emphasis on minimizing investment risk. The used models examine the selected data and are solved using the MS Excel add-in Solver version.

Random Matrix Theory with Applications in Statistics and Finance

Saad, Nadia Abdel Samie Basyouni Kotb

22 January 2013

This thesis investigates a technique to estimate the risk of the mean-variance (MV) portfolio optimization problem. We call this technique the Scaling technique. It provides a better estimator of the risk of the MV optimal portfolio. We obtain this result for a general estimator of the covariance matrix of the returns which includes the correlated sampling case as well as the independent sampling case and the exponentially weighted moving average case. This gave rise to the paper, [CMcS]. Our result concerning the Scaling technique relies on the moments of the inverse of compound Wishart matrices. This is an open problem in the theory of random matrices. We actually tackle a much more general setup, where we consider any random matrix provided that its distribution has an appropriate invariance property (orthogonal or unitary) under an appropriate action (by conjugation, or by a left-right action). Our approach is based on Weingarten calculus. As an interesting byproduct of our study - and as a preliminary to the solution of our problem of computing the moments of the inverse of a compound Wishart random matrix, we obtain explicit moment formulas for the pseudo-inverse of Ginibre random matrices. These results are also given in the paper, [CMS]. Using the moments of the inverse of compound Wishart matrices, we obtain asymptotically unbiased estimators of the risk and the weights of the MV portfolio. Finally, we have some numerical results which are part of our future work.

random matrices

Markowitz optimization problem

unitary (orthogonally) invariance

optimal portfolio

risk underestimation

inverse of compound Wishart matrices

Weingarten Calculus

Random Matrix Theory with Applications in Statistics and Finance

Saad, Nadia Abdel Samie Basyouni Kotb

22 January 2013

This thesis investigates a technique to estimate the risk of the mean-variance (MV) portfolio optimization problem. We call this technique the Scaling technique. It provides a better estimator of the risk of the MV optimal portfolio. We obtain this result for a general estimator of the covariance matrix of the returns which includes the correlated sampling case as well as the independent sampling case and the exponentially weighted moving average case. This gave rise to the paper, [CMcS]. Our result concerning the Scaling technique relies on the moments of the inverse of compound Wishart matrices. This is an open problem in the theory of random matrices. We actually tackle a much more general setup, where we consider any random matrix provided that its distribution has an appropriate invariance property (orthogonal or unitary) under an appropriate action (by conjugation, or by a left-right action). Our approach is based on Weingarten calculus. As an interesting byproduct of our study - and as a preliminary to the solution of our problem of computing the moments of the inverse of a compound Wishart random matrix, we obtain explicit moment formulas for the pseudo-inverse of Ginibre random matrices. These results are also given in the paper, [CMS]. Using the moments of the inverse of compound Wishart matrices, we obtain asymptotically unbiased estimators of the risk and the weights of the MV portfolio. Finally, we have some numerical results which are part of our future work.

random matrices

Markowitz optimization problem

unitary (orthogonally) invariance

optimal portfolio

risk underestimation

inverse of compound Wishart matrices

Weingarten Calculus

Random Matrix Theory with Applications in Statistics and Finance

Saad, Nadia Abdel Samie Basyouni Kotb

January 2013

This thesis investigates a technique to estimate the risk of the mean-variance (MV) portfolio optimization problem. We call this technique the Scaling technique. It provides a better estimator of the risk of the MV optimal portfolio. We obtain this result for a general estimator of the covariance matrix of the returns which includes the correlated sampling case as well as the independent sampling case and the exponentially weighted moving average case. This gave rise to the paper, [CMcS]. Our result concerning the Scaling technique relies on the moments of the inverse of compound Wishart matrices. This is an open problem in the theory of random matrices. We actually tackle a much more general setup, where we consider any random matrix provided that its distribution has an appropriate invariance property (orthogonal or unitary) under an appropriate action (by conjugation, or by a left-right action). Our approach is based on Weingarten calculus. As an interesting byproduct of our study - and as a preliminary to the solution of our problem of computing the moments of the inverse of a compound Wishart random matrix, we obtain explicit moment formulas for the pseudo-inverse of Ginibre random matrices. These results are also given in the paper, [CMS]. Using the moments of the inverse of compound Wishart matrices, we obtain asymptotically unbiased estimators of the risk and the weights of the MV portfolio. Finally, we have some numerical results which are part of our future work.

random matrices

Markowitz optimization problem

unitary (orthogonally) invariance

optimal portfolio

risk underestimation

inverse of compound Wishart matrices

Weingarten Calculus

[pt] ENSAIOS EM GESTÃO DE CARTEIRAS E PREVISÃO DE RETORNOS DE AÇÕES / [en] ESSAYS IN PORTFOLIO MANAGEMENT AND STOCKS RETURN FORECASTING

ARTUR MANOEL PASSOS

29 November 2021

[pt] A dissertação é composta por três ensaios empíricos que usam dados históricos de ações americanas. O primeiro avalia o desempenho de uma abordagem de otimização de carteiras baseada na otimização de Markowitz. Os resultados mostram valor econômico positivo do portfólio resultante, mesmo na presença de custos de transação. O segundo artigo visa comparar e combinar a técnica desenvolvida no artigo anterior à abordagem paramétrica e avalia o desempenho da combinação das técnicas. Os resultados mostram que o desempenho da técnica paramétrica é inferior à técnica de Markowitz modificada e pouco melhor do que o mercado agregado. Isto sugere que o valor econômico de explorar a estrutura de covariância entre as ações é superior a aumentar pesos em ações cujas características oferecem relações risco-retorno maiores até o período. O terceiro ensaio avalia modelos de previsão da variação de retornos entre ações. As estatísticas utilizadas apontam que os modelos padrão não possuem poder preditivo superior a modelos que supõem que não há variação ou que usam a média histórica. Por meio do uso tanto de combinações de modelos lineares quanto estimação restrita de modelos com muitos fatores, mostro que é possível obter resultados ligeiramente superiores. / [en] The dissertation consists of three empirical essays which use historical data of stocks listed in NYSE. The first essay evaluates a portfolio selection approach based on the Markowitz optimization. Results show the portfolios have positive economic value, even after including transaction costs. The second essay compares the technique proposed in the first essay to the parametric approach. Results show the parametric approach performs worse than the modified Markowitz approach and shlightly better than the aggregated market. This suggests that exploring the covariance structure of stocks provides better results than overweighting stocks with characteristics associated to better riskreturn ratios in the past. The third essay evaluates models that forecast the cross-sectional variation in stock returns. Given the statistics used, benchmark models do not show greater forecasting power than skeptical or naive models. By using linear model combination or lasso technique on a model with several factors, I show it is possible to obtain slightly better results.

[pt] OTIMIZACAO DE MARKOWITZ

[pt] GESTAO DE CARTEIRAS

[pt] COMBINACAO DE MODELOS

[pt] ESTIMACAO COM LASSO

[pt] MODELOS DE MULTIPLOS FATORES

[pt] PREVISAO DE RETORNOS DE ACOES

[en] MARKOWITZ OPTIMIZATION

[en] PORTFOLIO MANAGEMENT

[en] MODEL COMBINATION

[en] LASSO ESTIMATION

[en] MULTIPLE FACTOR MODELS

[en] STOCK RETURN FORECASTING