Difference between revisions of "SOCR EduMaterials Activities ApplicationsActivities Portfolio"
| Line 15: | Line 15: | ||
<math> | <math> | ||
| − | \mbox{Minimize} \ \ mbox{Var}(x_A R_A+x_BR_B) <br | + | \mbox{Minimize} \ \ mbox{Var}(x_A R_A+x_BR_B) <\br> |
\mbox{subject to} \ \ x_A+x_B=1 | \mbox{subject to} \ \ x_A+x_B=1 | ||
</math> | </math> | ||
Revision as of 23:44, 2 August 2008
Portfolio theory
An investor has a certain amount of dollars to invest into two stocks \(IBM\) and \(TEXACO\). A portion of the available funds will be invested into IBM (denote this portion of the funds with \(x_A\) and the remaining funds into TEXACO (denote it with \(x_B\)) - so \(x_A+x_B=1\). The resulting portfolio will be \(x_A R_A+x_B R_B\), where \(R_A\) is the monthly return of \(IBM\) and \(R_B\) is the monthly return of TEXACO. The goal here is to find the most efficient portfolios given a certain amount of risk. Using market data from January 1980 until February 2001 we compute that $E(R_A)=0.010$, $E(R_B)=0.013$, $Var(R_A)=0.0061$, $Var(R_B)=0.0046$, and $Cov(R_A,R_B)=0.00062$. \\ We first want to minimize the variance of the portfolio. This will be\[ \mbox{Minimize} \ \ mbox{Var}(x_A R_A+x_BR_B) <\br> \mbox{subject to} \ \ x_A+x_B=1 \]
