Asset Pricing and Portfolio Choice Theory Kerry E Back

Maccheroni et al. described choice theory which is the closest possible to the modern portfolio theory, while satisfying monotonicity axiom. Modern portfolio theory is inconsistent with main axioms of rational choice theory, most notably with monotonicity axiom, stating that, if investing into portfolio X will, with probability one, return more money than investing into portfolio Y, then a rational investor should prefer X to Y. Black–Litterman model optimization is an extension of unconstrained Markowitz optimization that incorporates relative and absolute ‘views’ on inputs of risk and returns from.

This efficient half-line is called the capital allocation line (CAL), and its formula can be shown to be If the desired portfolio is outside the range spanned by the two mutual funds, then one of the mutual funds must be sold short (held in negative quantity) while the size of the investment in the other mutual fund must be greater than the amount available for investment (the excess being funded by the borrowing from the other fund). Also, many software packages, including MATLAB, Microsoft Excel, Mathematica and R, provide generic optimization routines so that using these for solving the above problem is possible, with potential caveats (poor numerical accuracy, requirement of positive definiteness of the covariance matrix…). Volatility is described by standard deviation and it serves as a measure of risk.

• MPT assumes that investors are risk averse, meaning that given two portfolios that offer the same expected return, investors will prefer the less risky one.
• In particular, variance is a symmetric measure that counts abnormally high returns as just as risky as abnormally low returns.
• It is usually assumed that the risk-free return is less than the return of the global MVP, in order that the tangency portfolio exists.
• Already in the 1960s, Benoit Mandelbrot and Eugene Fama showed the inadequacy of this assumption and proposed the use of more general stable distributions instead.

Stefan Mittnik and Svetlozar Rachev presented strategies for deriving optimal portfolios in such settings. Already in the 1960s, Benoit Mandelbrot and Eugene Fama showed the inadequacy of this assumption and proposed the use of more general stable distributions instead. There many other risk measures (like coherent risk measures) might better reflect investors’ true preferences.

• In theory, an asset is correctly priced when its observed price is the same as its value calculated using the CAPM derived discount rate.
• After the stock market crash (in 1987), they rewarded two theoreticians, Harry Markowitz and William Sharpe, who built beautifully Platonic models on a Gaussian base, contributing to what is called Modern Portfolio Theory.
• Modern portfolio theory is inconsistent with main axioms of rational choice theory, most notably with monotonicity axiom, stating that, if investing into portfolio X will, with probability one, return more money than investing into portfolio Y, then a rational investor should prefer X to Y.
• If nuclear engineers ran risk management this way, they would never be able to compute the odds of a meltdown at a particular plant until several similar events occurred in the same reactor design.
• (There are several approaches to asset pricing that attempt to price assets by modelling the stochastic properties of the moments of assets’ returns – these are broadly referred to as conditional asset pricing models.)

Connection with rational choice theory

In theory, an asset is correctly priced when its observed price is the same as its value calculated using the CAPM derived discount rate. Market neutral portfolios, therefore, will be uncorrelated with broader market indices. Systematic risks within one market can be managed through a strategy of using both long and short positions within one portfolio, creating a “market neutral” portfolio.

The variance of return (or its transformation, the standard deviation) is used as a measure of risk, because it is tractable when assets are combined into portfolios. MPT uses historical variance as a measure of risk, but portfolios of assets like major projects do not have a well-defined “historical variance”. The price paid must ensure that the market portfolio’s risk / return characteristics improve when the asset is added to it. (There are several approaches to asset pricing that attempt to price assets by modelling the stochastic properties of the moments of assets’ returns – these are broadly referred to as conditional asset pricing models.) Asset pricing theory builds on this analysis, allowing MPT to derive the required expected return for a correctly priced asset in this context.

Risk and expected return

Since a security will be purchased only if it improves the risk-expected return characteristics of the market portfolio, the relevant measure of the risk of a security is the risk it adds to the market portfolio, and not its risk in isolation.In this context, the volatility of the asset, and its correlation with the market portfolio, are historically observed and are therefore given. Equivalently, a portfolio lying on the efficient asset pricing and portfolio choice theory frontier represents the combination offering the best possible expected return for given risk level. Combinations along this upper edge represent portfolios (including no holdings of the risk-free asset) for which there is lowest risk for a given level of expected return.

Modern portfolio theory

The model is also extended by assuming that expected returns are uncertain, and the correlation matrix in this case can differ from the correlation matrix between returns. Modern portfolio theory has also been criticized because it assumes that returns follow a Gaussian distribution. In particular, variance is a symmetric measure that counts abnormally high returns as just as risky as abnormally low returns. The risk, return, and correlation measures used by MPT are based on expected values, which means that they are statistical statements about the future (the expected value of returns is explicit in the above equations, and implicit in the definitions of variance and covariance).

Where αi is called the asset’s alpha, βi is the asset’s beta coefficient and SCL is the security characteristic line. Therefore, there is never a reason to buy that asset, and we can remove it from the market. The capital market line (CML) becomes parallel to the upper asymptote line of the hyperbola. In practice, short-term government securities (such as US treasury bills) are used as a risk-free asset, because they pay a fixed rate of interest and have exceptionally low default risk. If the location of the desired portfolio on the frontier is between the locations of the two mutual funds, both mutual funds will be held in positive quantities. Different investors will evaluate the trade-off differently based on individual risk aversion characteristics.

After the stock market crash (in 1987), they rewarded two theoreticians, Harry Markowitz and William Sharpe, who built beautifully Platonic models on a Gaussian base, contributing to what is called Modern Portfolio Theory. If nuclear engineers ran risk management this way, they would never be able to compute the odds of a meltdown at a particular plant until several similar events occurred in the same reactor design. This is a major difference as compared to many engineering approaches to risk management. Instead of transforming the normalized expectations using the inverse of the correlation matrix, the invariant portfolio employs the inverse of the square root of the correlation matrix. An optimal approach to capturing trends, which differs from Markowitz optimization by utilizing invariance properties, is also derived from physics. Very often such expected values fail to take account of new circumstances that did not exist when the historical data was generated.

PRINCIPLES OF FINANCIAL ECONOMICS Second Edition

They simply indicate the need to run the optimization with an additional set of mathematically expressed constraints that would not normally apply to financial portfolios. Neither of these necessarily eliminate the possibility of using MPT and such portfolios. When MPT is applied outside of traditional financial portfolios, some distinctions between the different types of portfolios must be considered. Since MPT’s introduction in 1952, many attempts have been made to improve the model, especially by using more realistic assumptions. When applied to certain universes of assets, the Markowitz model has been identified by academics to be inadequate due to its susceptibility to model instability which may arise, for example, among a universe of highly correlated assets.

Asset Pricing and Excess Returns over the Market Return

Systematic risk is therefore equated with the risk (standard deviation) of the market portfolio. Systematic risk (a.k.a. portfolio risk or market risk) refers to the risk common to all securities—except for selling short as noted below, systematic risk cannot be diversified away (within one market). We can remove each such asset from the market, constructing one risk-free asset for each such asset removed. We have some funds, and a portfolio is a way to divide our funds into the assets. It is tangent to the hyperbola at the pure risky portfolio with the highest Sharpe ratio.

The ‘return – standard deviation space’ is sometimes called the space of ‘expected return vs risk’. Its key insight is that an asset’s risk and return should not be assessed by itself, but by how it contributes to a portfolio’s overall risk and return. It is a formalization and extension of diversification in investing, the idea that owning different kinds of financial assets is less risky than owning only one type. Recently, modern portfolio theory has been applied to modelling the uncertainty and correlation between documents in information retrieval. More recently, modern portfolio theory has been used to model the self-concept in social psychology. Alternatively, mean-deviation analysisis a rational choice theory resulting from replacing variance by an appropriate deviation risk measure.

Despite its theoretical importance, critics of MPT question whether it is an ideal investment tool, because its model of financial markets does not match the real world in many ways. A riskier stock will have a higher beta and will be discounted at a higher rate; less sensitive stocks will have lower betas and be discounted at a lower rate. Specific risk is also called diversifiable, unique, unsystematic, or idiosyncratic risk.

Markets Served

By the diagram, the introduction of the risk-free asset as a possible component of the portfolio has improved the range of risk-expected return combinations available, because everywhere except at the tangency portfolio the half-line gives a higher expected return than the hyperbola does at every possible risk level. In this formula P is the sub-portfolio of risky assets at the tangency with the Markowitz bullet, F is the risk-free asset, and C is a combination of portfolios P and F. The implication is that a rational investor will not invest in a portfolio if a second portfolio exists with a more favorable risk vs expected return profile — i.e., if for that level of risk an alternative portfolio exists that has better expected returns.

In practice, such a tangency portfolio would be impossible to achieve, because one cannot short an asset too much due to short sale constraints, and also because of price impact, that is, longing a large amount of an asset would push up its price, breaking the assumption that the asset prices do not depend on the portfolio. As a result, when it is combined with any other asset or portfolio of assets, the change in return is linearly related to the change in risk as the proportions in the combination vary. The risk-free asset has zero variance in returns if held to maturity (hence is risk-free); it is also uncorrelated with any other asset (by definition, since its variance is zero). The MPT is a mean-variance theory, and it compares the expected (mean) return of a portfolio with the standard deviation of the same portfolio. Diversification may allow for the same portfolio expected return with reduced risk. In other words, investors can reduce their exposure to individual asset risk by holding a diversified portfolio of assets.

The psychological phenomenon of loss aversion is the idea that investors are more concerned about losses than gains, meaning that our intuitive concept of risk is fundamentally asymmetric in nature. Mathematical risk measurements are also useful only to the degree that they reflect investors’ true concerns—there is no point minimizing a variable that nobody cares about in practice. But in the Black–Scholes equation and MPT, there is no attempt to explain an underlying structure to price changes. Options theory and MPT have at least one important conceptual difference from the probabilistic risk assessment done by nuclear power plants. Such measures often cannot capture the true statistical features of the risk and return which often follow highly skewed distributions (e.g. the log-normal distribution) and can give rise to, besides reduced volatility, also inflated growth of return. If the observed price is higher than the valuation, then the asset is overvalued; it is undervalued for a too low price.

When risk is put in terms of uncertainty about forecasts and possible losses then the concept is transferable to various types of investment. Furthermore, some of the simplest elements of Modern Portfolio Theory are applicable to virtually any kind of portfolio. When the self attributes comprising the self-concept constitute a well-diversified portfolio, then psychological outcomes at the level of the individual such as mood and self-esteem should be more stable than when the self-concept is undiversified. In a series of seminal works, Michael Conroycitation needed modeled the labor force in the economy using portfolio-theoretic methods to examine growth and variability in the labor force.

Simply, if you remove their Gaussian assumptions and treat prices as scalable, you are left with hot air. The optimization problem is solved under the assumption that expected values are uncertain and correlated. In practice, investors must substitute predictions based on historical measurements of asset return and volatility for these values in the equations.