Consider expt, passing in a fractional power as its second argument.

But let's say we didn't know about `expt`

. Could we still compute it?

One way to do it is by applying something like Newton's method. For example, let's say we wanted to compute n^(1/4). Of course, we already know we can just take the `sqrt`

twice to do this, but let's see how Newton's method may apply to this problem.

Given `n`

, we'd like to discover roots `x`

of the function:

```
f(x) = x^4 - n
```

Concretely, if we wanted to look for `16^(1/4)`

, then we'd look for a root for the function:

```
f(x) = x^4 - 16
```

We already know if we plug in `x=2`

in there, we'll discover that `2`

is a root of this function. But say that we didn't know that. How would we discover the `x`

values that make this function zero?

Newton's method says that if we have a guess at `x`

, call it `x_0`

, we can improve that guess by doing the following process:

```
x_1 = x_0 - f(x_0) / f'(x_0)
```

where `f'(x)`

is notation for the derivative of `f(x)`

. For the case above, the derivative of `f(x)`

is `4x^3`

.

And we can get better guesses `x_2`

, `x_3`

, ... by repeating the computation:

```
x_2 = x_1 - f(x_1) / f'(x_1)
x_3 = x_2 - f(x_2) / f'(x_2)
...
```

until we get tired.

Let's write this all in code now:

```
(define (f x)
(- (* x x x x) 16))
(define (f-prime x)
(* 4 x x x))
(define (improve guess)
(- guess (/ (f guess)
(f-prime guess))))
(define approx-quad-root-of-16
(improve (improve (improve (improve (improve 1.0))))))
```

The code above just expresses `f(x)`

, `f'(x)`

, and the idea of improving an initial guess five times. Let's see what the value of `approx-quad-root-of-16`

is:

```
> approx-quad-root-of-16
2.0457437305170534
```

Hey, cool. It's actually doing something, and it's close to `2`

. Not bad for starting with such a bad first guess of `1.0`

.

Of course, it's a little silly to hardcode `16`

in there. Let's generalize, and turn it into a function that takes an arbitrary `n`

instead, so we can compute the quad root of anything:

```
(define (approx-quad-root-of-n n)
(define (f x)
(- (* x x x x) n))
(define (f-prime x)
(* 4 x x x))
(define (improve guess)
(- guess (/ (f guess)
(f-prime guess))))
(improve (improve (improve (improve (improve 1.0))))))
```

Does this do something effective? Let's see:

```
> (approx-quad-root-of-n 10)
1.7800226459895
> (expt (approx-quad-root-of-n 10) 4)
10.039269440807693
```

Cool: it is doing something useful. But note that it's not that precise yet. To get better precision, we should keep calling `improve`

, and not just four or five times. Think loops or recursion: repeat the improvement till the solution is "close enough".

This is a sketch of how to solve these kinds of problems. For a little more detail, look at the section on computing square roots in Structure and Interpretation of Computer Programs.