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The formula for the Gordon growth model is:

$\hspace{1in}P= \sum_{t=1}^{\infty} D\times\frac{(1+g)^t}{(1+k)^t}$

So summing the infinite series we get:

$\hspace{1in}P=\frac{D(1+g)}{k-g} \hspace{2in}\mbox{(1)}$

Here's my attempt to arrive at equation (1):

The sum of a geometric series is:

$\hspace{1in}\frac{a}{1-r}$

So, plugging in the values:

$\hspace{1in}\frac{D}{1-\frac{1+g}{1+k}}$

$\hspace{1in}\frac{D}{\frac{1+k-(1+g)}{1+k}}$

$\hspace{1in}\frac{D}{\frac{k-g}{1+k}}$

Therefore,

$\hspace{1in}P=\frac{D(1+k)}{1+g}$

Appreciate if someone could highlight where I made a mistake.

Thanks you.

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    $\sum\nolimits_{t = 1}^\infty {x^t } = x\sum\nolimits_{t = 0}^\infty {x^t } = \frac{x}{{1 - x}}$, if |x|<1. So,...2011-01-13

1 Answers 1

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The question was basically answered already in comments. I'll add some details so that the question does not remain unanswered.

In the formula $\frac{a}{1-r}$ you should have used $a=D\frac{1+g}{1+k} \text{ and }r=\frac{1+g}{1+k}.$ (You have used $a=D$.)

With this change, using the same as you posted in your question, you will arrive to $\frac a{1-r} = D\frac{1+g}{1+k} \frac1{1-\frac{1+g}{1+k}} = D\frac{1+g}{1+k} \frac1{\frac{k-g}{1+k}} = D\frac{1+g}{k-g}.$