Question

How do you evaluate `1200=300(1+r)^{5}`?

Answer 1

`r=2^(2/5)-1`

Explanation:

`1200=300(1+r)^5`

First, divide both sides of the equation by `300`:

`1200/300=(300(1+r)^5)/300`

`4=(1+r)^5`

To undo the power of `5`, raise both sides of the equation to the `1//5` power:

`4^(1/5)=((1+r)^5)^(1/5)`

`4^(1/5)=1+r`

Finally, subtract `1` from both sides of the equation:

`r=4^(1/5)-1`

Personally, I prefer the simplification `4^(1/5)=(2^2)^(1/5)=2^(2/5)`:

`r=2^(2/5)-1`

Answer 2

Explanation:

We have:

`1200=300(1+r)^5`

Let `omega=1+r`, and let `z^5 = omega`, then:

`1200 = 300z^5 => z^5 = 4`

First, we will put the equation into polar form:

`|omega| = 4`
`theta =0`

So then in polar form we have:

`z^5 = 4(cos0 + isin0)`

We now want to solve the equation `z^5=4` for `z` (to gain `5` solutions):

Whenever dealing with complex variable equation such as this it is essential to remember that the complex exponential (and therefore the polar representation) has a period of `2pi`, so we can equivalently write (incorporating the periodicity):

`z^5 = 4(cos(0+2npi) + isin(0+2npi)) \ \ \ n in ZZ`

By De Moivre's Theorem we can write this as:

`z = (4(cos(0+2npi) + isin(0+2npi)))^(1/5)`
`\ \ = 4^(1/5)(cos(2npi) + isin(2npi)))^(1/5)`
`\ \ = 4^(1/5)(cos((2npi)/5) + isin((2npi)/5))`
`\ \ = 4^(1/5)(costheta + isintheta)`

Where:

`theta =(2npi)/5`

And we will get `5` unique solutions by choosing appropriate values of `n`. Working to 3dp, and using excel to assist, we get:

After which the pattern continues (due the above mentioned periodicity).

We can plot these solutions on the Argand Diagram: