Difference between revisions of "Compound Interest"

Revision as of 10:24, 11 October 2021

Compound interest includes interest earned on the interest that was previously accumulated.

Compare, for example, a bond paying 6 percent semiannually (that is, coupons of 3 percent twice a year) with a certificate of deposit (GIC) that pays 6 percent interest once a year. The total interest payment is $6 per $100 par value in both cases, but the holder of the semiannual bond receives half the $6 per year after only 6 months (time preference), and so has the opportunity to reinvest the first $3 coupon payment after the first 6 months, and earn additional interest.

For example, suppose an investor buys $10,000 par value of a US dollar bond, which pays coupons twice a year, and that the bond's simple annual coupon rate is 6 percent per year. This means that every 6 months, the issuer pays the holder of the bond a coupon of 3 dollars per 100 dollars par value. At the end of 6 months, the issuer pays the holder:

{\frac {r\cdot B\cdot m}{n}}={\frac {6\%\times \$10\,000\times 1}{2}}=\$300

Assuming the market price of the bond is 100, so it is trading at par value, suppose further that the holder immediately reinvests the coupon by spending it on another $300 par value of the bond. In total, the investor therefore now holds:

\$10\,000+\$300=\left(1+{\frac {r}{n}}\right)\cdot B=\left(1+{\frac {6\%}{2}}\right)\times \$10\,000

and so earns a coupon at the end of the next 6 months of:

{\begin{aligned}{\frac {r\cdot B\cdot m}{n}}&={\frac {6\%\times \left(\$10\,000+\$300\right)}{2}}\\&={\frac {6\%\times \left(1+{\frac {6\%}{2}}\right)\times \$10\,000}{2}}\\&=\$309\end{aligned}}

Assuming the bond remains priced at par, the investor accumulates at the end of a full 12 months a total value of:

{\begin{aligned}\$10,000+\$300+\$309&=\$10\,000+{\frac {6\%\times \$10,000}{2}}+{\frac {6\%\times \left(1+{\frac {6\%}{2}}\right)\times \$10\,000}{2}}\\&=\$10\,000\times \left(1+{\frac {6\%}{2}}\right)^{2}\end{aligned}}

and the investor earned in total:

{\begin{aligned}\$10\,000\times \left(1+{\frac {6\%}{2}}\right)^{2}-\$10\,000\\=\$10\,000\times \left(\left(1+{\frac {6\%}{2}}\right)^{2}-1\right)\end{aligned}}

The formula for the annual equivalent compound interest rate is:

\left(1+{\frac {r}{n}}\right)^{n}-1

where

r is the simple annual rate of interest

n is the frequency of applying interest

For example, in the case of a 6% simple annual rate, the annual equivalent compound rate is:

\left(1+{\frac {6\%}{2}}\right)^{2}-1=1.03^{2}-1=6.09\%

Resources

Simple and Compound Interest, Book Chapter
Guided Notes

@@ Line 1: / Line 1: @@
+Compound interest includes interest earned on the interest that was previously accumulated.
+Compare, for example, a bond paying 6 percent semiannually (that is, coupons of 3 percent twice a year) with a certificate of deposit (GIC) that pays 6 percent interest once a year. The total interest payment is $6 per $100 par value in both cases, but the holder of the semiannual bond receives half the $6 per year after only 6 months (time preference), and so has the opportunity to reinvest the first $3 coupon payment after the first 6 months, and earn additional interest.
+For example, suppose an investor buys $10,000 par value of a US dollar bond, which pays coupons twice a year, and that the bond's simple annual coupon rate is 6 percent per year. This means that every 6 months, the issuer pays the holder of the bond a coupon of 3 dollars per 100 dollars par value. At the end of 6 months, the issuer pays the holder:
+:<math>\frac {r \cdot B \cdot m}{n} = \frac {6\% \times \$10\,000 \times 1}{2} = \$300</math>
+Assuming the market price of the bond is 100, so it is trading at par value, suppose further that the holder immediately reinvests the coupon by spending it on another $300 par value of the bond. In total, the investor therefore now holds:
+:<math>\$10\,000 + \$300 = \left(1 + \frac{r}{n}\right) \cdot B = \left(1 + \frac{6\%}{2}\right) \times \$10\,000</math>
+and so earns a coupon at the end of the next 6 months of:
+:<math>\begin{align}\frac {r \cdot B \cdot m}{n}
+&= \frac {6\% \times \left(\$10\,000 + \$300\right)}{2}\\
+&= \frac {6\% \times \left(1 + \frac{6\%}{2}\right) \times \$10\,000}{2}\\
+&=\$309\end{align}</math>
+Assuming the bond remains priced at par, the investor accumulates at the end of a full 12 months a total value of:
+:<math>\begin{align}\$10,000 + \$300 + \$309
+&= \$10\,000 + \frac {6\% \times \$10,000}{2} + \frac {6\% \times \left( 1 + \frac {6\%}{2}\right) \times \$10\,000}{2}\\
+&= \$10\,000 \times \left(1 + \frac{6\%}{2}\right)^2\end{align}</math>
+and the investor earned in total:
+:<math>\begin{align}\$10\,000 \times \left(1 + \frac {6\%}{2}\right)^2 - \$10\,000\\
+= \$10\,000 \times \left( \left( 1 + \frac {6\%}{2}\right)^2 - 1\right)\end{align}</math>
+The formula for the '''annual equivalent compound interest rate''' is:
+:<math>\left(1 + \frac{r}{n}\right)^n - 1</math>
+where
+:r is the simple annual rate of interest
+:n is the frequency of applying interest
+For example, in the case of a 6% simple annual rate, the annual equivalent compound rate is:
+:<math>\left(1 + \frac{6\%}{2}\right)^2 - 1 = 1.03^2 - 1 = 6.09\%</math>
+==Resources==
 * [https://mathresearch.utsa.edu/wikiFiles/MAT1053/Simple_and_Compound_Interest/MAT1053_M7.1Simple_and_Compound_Interest.pdf Simple and Compound Interest], Book Chapter
 * [https://mathresearch.utsa.edu/wikiFiles/MAT1053/Simple_and_Compound_Interest/MAT1053_M7.1Simple_and_Compound_InterestGN.pdf Guided Notes]

Difference between revisions of "Compound Interest"

Revision as of 10:24, 11 October 2021

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