An Introduction to Portfolio Management



An Introduction to Portfolio Management
•Creation of an optimal portfolio
–Not only combination a lot of individual securities with described risk-return characteristics
•Reaction among investments

Portfolio theory - assumptions
•An investor want to maximize the return from your investments for a given level of risk


Risk Aversion
•Given a choice between two assets with equal rates of return, most investors will select the asset
with the lower level of risk.

Evidence That
Investors are Risk Averse
•Many investors purchase insurance for: Life, Automobile, Health, and Disability Income.
–The purchaser trades known costs for unknown risk of loss
•Yield on bonds increases with risk classifications from AAA to AA to A….

Not all investors are risk averse
•Not everybody buys insurance for everything
•
•Friedman and Savage:
•Risk preference may have to do with amount of money involved - risking small amounts, but insuring
large losses
•Basis assumption
•Positive relationship between expected return and expected risk

Definition of Risk
•1. Uncertainty of future outcomes
•or
•2. Probability of an adverse outcome

Markowitz Portfolio Theory
•In early 1960’s, investment community talked about risk
–No specific measure for them
•Quantifies risk variable
•Model of Harry Markowitz
•Derives the expected rate of return for a portfolio of assets and an expected risk measure
•Shows that the variance of the rate of return is a meaningful measure of portfolio risk
•Derives the formula for computing the variance of a portfolio, showing how to effectively
diversify a portfolio

Assumptions of
Markowitz Portfolio Theory
•1. Investors consider each investment alternative as being presented by a probability distribution
of expected returns over some holding period.

Assumptions of
Markowitz Portfolio Theory
•2. Investors minimize one-period expected utility, and their utility curves demonstrate
diminishing marginal utility of wealth.

Assumptions of
Markowitz Portfolio Theory
•3. Investors estimate the risk of the portfolio on the basis of the variability of expected
returns.

Assumptions of
Markowitz Portfolio Theory
•4. Investors base decisions solely on expected return and risk, so their utility curves are a
function of expected return and the expected variance (or standard deviation) of returns only.

Assumptions of
Markowitz Portfolio Theory
•5. For a given risk level, investors prefer higher returns to lower returns.  Similarly, for a
given level of expected returns, investors prefer less risk to more risk.

Markowitz Portfolio Theory
• Using these five assumptions, a single asset or portfolio of assets is considered to be efficient
if no other asset or portfolio of assets offers higher expected return with the same (or lower)
risk, or lower risk with the same (or higher) expected return.

Alternative Measures of Risk
•Variance or standard deviation of expected return
–Dispersion of returns around the expected value
•Larger variance greater dispersion and greater uncertainity of future returns
•Range of returns
–A larger range of expected returns, from lowest ro the highest return, means greater uncertainty
and risk regarding future expected returns
•Returns below expectations
–Semivariance – a measure that only considers deviations below the mean
•Computed expected returns below zero
–These measures of risk implicitly assume that investors want to minimize the damage from returns
less than some target rate

•Variance or standard deviation
–This measure is intuitive
–It is correct and widely recognized risk measure
–Used in most of the theoretical asset pricing models

Expected Rates of Return
•For an individual asset - sum of the potential returns multiplied with the corresponding
probability of the returns
•For a portfolio of assets - weighted average of the expected rates of return for the individual
investments in the portfolio

Computation of Expected Return for an Individual Risky Investment
Exhibit 7.1


Computation of the Expected Return for a Portfolio of Risky Assets
Exhibit 7.2


Variance (Standard Deviation) of Returns for an Individual Investment
• Standard deviation is the square root of the variance
• Variance is a measure of the variation of possible rates of return Ri, from the expected rate of
return [E(Ri)]

Variance (Standard Deviation) of Returns for an Individual Investment
•where Pi is the probability of the possible rate of return, Ri


Variance (Standard Deviation) of Returns for an Individual Investment
•Standard Deviation


Variance (Standard Deviation) of Returns for an Individual Investment
Exhibit 7.3
Variance (    2) = .0050
Standard Deviation (    ) = .02236

Variance (Standard Deviation) of Returns for a Portfolio
•  Computation of Monthly Rates of Return
Exhibit 7.4

Covariance of Returns
•A measure of the degree to which two variables “move together” relative to their individual mean
values over time
•In portfolio analysis
–Concerned with the covariances of rates of return rather than prices
•Positive – tend to move in the same direction relative to individual means
•Negative – tend to move in different directions
•

Covariance of Returns
•For two assets, i and j, the covariance of rates of return is defined as:
•Covij = E{[Ri - E(Ri)][Rj - E(Rj)]}




Covariance and Correlation
•The correlation coefficient is obtained by standardizing (dividing) the covariance by the product
of the individual standard deviations

Covariance and Correlation
•Correlation coefficient varies from -1 to +1


Correlation Coefficient
•It can vary only in the range +1 to -1.
–A value of +1 would indicate perfect positive correlation.  This means that returns for the two
assets move together in a completely linear manner.
–A value of –1 would indicate perfect correlation.  This means that the returns for two assets have
the same percentage movement, but in opposite directions

Portfolio Standard Deviation Formula



Portfolio Standard Deviation Calculation
•Any asset of a portfolio may be described by two characteristics:
–The expected rate of return
–The expected standard deviations of returns
•The correlation, measured by covariance, affects the portfolio standard deviation
•Low correlation reduces portfolio risk while not affecting the expected return

Combining Stocks with Different Returns and Risk
•    Case      Correlation Coefficient     Covariance
•       a                        +1.00                     .0070
•       b                        +0.50                     .0035
•       c                          0.00                     .0000
•       d                         -0.50                    -.0035
•       e                         -1.00                    -.0070
1                         .10              .50          .0049       .07
2                         .20              .50          .0100       .10

Combining Stocks with Different Returns and Risk
•Assets may differ in expected rates of return and individual standard deviations
•Negative correlation reduces portfolio risk
•Combining two assets with -1.0 correlation reduces the portfolio standard deviation to zero only
when individual standard deviations are equal

Constant Correlation
with Changing Weights
1                         .10                            rij = 0.00
2                         .20

Constant Correlation
with Changing Weights


Portfolio Risk-Return Plots for Different Weights
Standard Deviation of Return
E(R)
Rij = +1.00
1
2
With two perfectly correlated assets, it is only possible to create a two asset portfolio with
risk-return along a line between either single asset

Portfolio Risk-Return Plots for Different Weights
Standard Deviation of Return
E(R)
Rij = 0.00
Rij = +1.00
f
g
h
i
j
k
1
2
With uncorrelated assets it is possible to create a two asset portfolio with lower risk than either
single asset

Portfolio Risk-Return Plots for Different Weights
Standard Deviation of Return
E(R)
Rij = 0.00
Rij = +1.00
Rij = +0.50
f
g
h
i
j
k
1
2
With correlated assets it is possible to create a two asset portfolio between the first two curves

Portfolio Risk-Return Plots for Different Weights
Standard Deviation of Return
E(R)
Rij = 0.00
Rij = +1.00
Rij = -0.50
Rij = +0.50
f
g
h
i
j
k
1
2
        With negatively correlated assets it is possible to create a two asset portfolio with much
lower risk than either single asset

Portfolio Risk-Return Plots for Different Weights
Standard Deviation of Return
E(R)
Rij = 0.00
Rij = +1.00
Rij = -1.00
Rij = +0.50
f
g
h
i
j
k
1
2
With perfectly negatively correlated assets it is possible to create a two asset portfolio with
almost no risk
Rij = -0.50
Exhibit 7.13

Estimation Issues
•Results of portfolio allocation depend on accurate statistical inputs
•Estimates of
–Expected returns
–Standard deviation
–Correlation coefficient
•Among entire set of assets
•With 100 assets, 4,950 correlation estimates
•Estimation risk refers to potential errors

Estimation Issues
•With assumption that stock returns can be described by a single market model, the number of
correlations required reduces to the number of assets
•Single index market model:
bi = the slope coefficient that relates the returns for security i to the returns for the aggregate
stock market
Rm = the returns for the aggregate stock market

Estimation Issues
•If all the securities are similarly related to the market and a bi derived for each one, it can be
shown that the correlation coefficient between two securities i and j is given as:

The Efficient Frontier
•The efficient frontier represents that set of portfolios with the maximum rate of return for every
given level of risk, or the minimum risk for every level of return
•Frontier will be portfolios of investments rather than individual securities
–Exceptions being the asset with the highest return and the asset with the lowest risk

Efficient Frontier
for Alternative Portfolios
Efficient Frontier
A
B
C
Exhibit 7.15
E(R)
Standard Deviation of Return

The Efficient Frontier
and Investor Utility
•An individual investor’s utility curve specifies the trade-offs he is willing to make between
expected return and risk
•The slope of the efficient frontier curve decreases steadily as you move upward
•These two interactions will determine the particular portfolio selected by an individual investor

The Efficient Frontier
and Investor Utility
•The optimal portfolio has the highest utility for a given investor
•It lies at the point of tangency between the efficient frontier and the utility curve with the
highest possible utility

Selecting an Optimal Risky Portfolio
X
Y
U3
U2
U1
U3’
U2’
U1’
Exhibit 7.16

The Internet
Investments Online
•www.pionlie.com
•www.investmentnews.com
•www.micropal.com
•www.riskview.com
•www.altivest.com

Future topics
Chapter 8
•Capital Market Theory
•Capital Asset Pricing Model
•Beta
•Expected Return and Risk
•Arbitrage Pricing Theory