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Find The Highest Returns With The Sharpe Ratio

2012-10-26 11:22:25

"When it comes to money, everybody is of the same religion." - Voltaire

Most people would agree that they want to make and have money, but very few

people would agree to the level of risk they are willing to take on to make

that money. Therefore, risk must be the first issue you address when you are

looking at choosing your investments. (For more insight, see Determining Risk

And The Risk Pyramid.)

Tutorial: Top Stock-Picking Strategies

In this article, we'll show you why the Sharpe ratio can help you determine

which asset classes will deliver the highest returns while considering its

risk.

The Sharpe ratio is designed to measure a unit of reward for each unit of risk

taken. Let's take a look at this simple ratio in more detail.

Sharpe Ratio Dynamics

The Sharpe ratio, developed by Nobel Laureate William Sharpe, is designed to

measure how many excess units of returns an investor can achieve over the

risk-free rate for each unit of risk taken.

Thus, the Shape Ratio measures the risk/reward value of investors' assets class

choices beyond the U.S. Treasury.

Let's take a look at the efficient frontier chart below to better illustrate

the concept of risk, return and the Sharpe ratio.

Figure 1: Efficient Frontier - if you plot all the investment choices that you

have at your disposal - stocks, bonds and portfolios of stocks and bonds, etc.

- on the chart above, the resulting chart will be bounded by an upward sloping

curve known as the efficient frontier.

Return Dynamics

Without taking on risk, you can achieve a level of return as indicated on the

chart by the risk-free portfolio, the U.S. Treasury.

To achieve an additional X percent of return, you will need to take Z level of

risk. Portfolio A represents your risk and return payoff. The Sharpe ratio of

Portfolio A can simply be defined as X divided by Z. Portfolios B and C will

deliver a higher level of returns should you choose to take additional risk

beyond Z.

Unlike portfolio B and C, portfolios A' and A'' will deliver a higher level of

returns for the same level of risk Z. Thus, A'' is preferable to A' and A' is

preferable to A. The Sharpe ratio of A' is defined as X+Y divided by Z.

Therefore, the Sharpe ratio of A' is higher than that of A. Given the same

level of risk Z, it can be concluded that any portfolio providing X plus

additional returns should be considered superior. The additional achievable

returns will be limited by the efficient frontier. Applying this same

methodology, we can also presume that Portfolios B and C are superior if their

Sharpe ratios are shown to be higher to that of A. (To learn more, check out

Understanding The Sharpe Ratio and The Sharpe Ratio Can Oversimplify Risk.)

Breaking Down the Sharpe Ratio

A common mathematical definition of the Sharpe ratio for a portfolio is the

excess returns of the portfolio over the risk-free rate divided by the

portfolio's standard deviation.

Here is an illustration of the Sharpe ratio in the same efficient frontier

chart:

Figure 2

It can be concluded that for a given level of risk (sp), Portfolio A can

achieve a higher Sharpe ratio by following the blue arrow toward the efficient

frontier or, for a given level of return (Rp), Portfolio A can also achieve

higher Sharpe ratio by following the red arrow toward the efficient frontier.

Sharpe Ratio and Risk

The charts and the formula demonstrate that the Sharpe ratio penalizes the

excess returns by adding of risk as defined by standard deviation. The standard

deviation is also commonly referred to as the total risk. Mathematically, the

square of standard deviation is the variance, Markowitz's definition of risk.

(For further reading, see Understanding Volatility Measurements.)

So why did Sharpe choose the standard deviation to adjust excess returns for

risk and why should we care? We know that Markowitz defined variance as

something not to be desired by investors. Variance is defined as a measure of

statistical dispersion or an indication of how far away it is from the expected

value. The square root of variance, or standard deviation, has the same unit

form as the data series being analyzed and is such more commonly used to

measure risk.

The following example illustrates why investors should care about variance:

An investor has a choice of three portfolios, all with expected returns of 10%

for the next 10 years. The average returns in the table below indicates the

stated expectation. The returns achieved for the investment horizon is

indicated by annualized returns, which takes compounding into account. As the

data table and the chart clearly illustrates below, the standard deviation

takes returns away from the expected return. If there is no risk, zero standard

deviation, your returns will equal your expected returns.

Expected Average Returns

Year Portfolio A Portfolio B Portfolio C

Year 1 10.00% 9.00% 2.00%

Year 2 10.00% 15.00% -2.00%

Year 3 10.00% 23.00% 18.00%

Year 4 10.00% 10.00% 12.00%

Year 5 10.00% 11.00% 15.00%

Year 6 10.00% 8.00% 2.00%

Year 7 10.00% 7.00% 7.00%

Year 8 10.00% 6.00% 21.00%

Year 9 10.00% 6.00% 8.00%

Year 10 10.00% 5.00% 17.00%

Average Returns 10.00% 10.00% 10.00%

Annualized Returns 10.00% 9.88% 9.75%

Standard Deviation 0.00% 5.44% 7.80%

Figure 3

Figure 4

Conclusion

Risk and reward must be evaluated together when considering investment choices;

this is focal point presented in modern portfolio theory. In a common

definition of risk, the standard deviation or variance takes rewards away from

the investor. As such, the risk must always be addressed along with the reward

when you are looking to choose your investments. The Sharpe ratio can help you

determine the investment choice that will deliver the highest returns while

considering its risk.

by Edward Aw

Edward Aw currently heads the quantitative research efforts at a privately held

wealth management company based in New York. His main responsibilities include

developing analyst tools, enhancing security selection and risk management. He

served as a quantitative analyst for five years at Deutsche Investment

Management Americas. Aw also held analytical roles at the Dreyfus Corporation,

Goldman Sachs and Morgan Stanley. He holds a Chartered Financial Analyst

designation, a Bachelor of Arts from the State University of New York and an

Master of Business Administration from Hofstra University. He is a member of

the New York Society of Security Analysts.