`uniroot()`

and caution of its use

`uniroot`

is implementing the crude bisection method. Such method is much simpler that (quasi) Newton's method, but need stronger assumption to ensure the existence of a root: `f(lower) * f(upper) < 0`

.

This can be quite a pain,as such assumption is a sufficient condition, but not a necessary one. In practice, if `f(lower) * f(upper) > 0`

, it is still possible that a root exist, but since this is not of 100% percent sure, bisection method can not take the risk.

Consider this example:

```
# a quadratic polynomial with root: -2 and 2
f <- function (x) x ^ 2 - 4
```

Obviously, there are roots on `[-5, 5]`

. But

```
uniroot(f, lower = -5, upper = 5)
#Error in uniroot(f, lower = -5, upper = 5) :
# f() values at end points not of opposite sign
```

In reality, the use of bisection method requires observation / inspection of `f`

, so that one can propose a reasonable interval where root lies. In R, we can use `curve()`

:

```
curve(f, from = -5, to = 5); abline(h = 0, lty = 3)
```

From the plot, we observe that a root exist in `[-5, 0]`

or `[0, 5]`

. So these work fine:

```
uniroot(f, lower = -5, upper = 0)
uniroot(f, lower = 0, upper = 5)
```

**Your problem**

Now let's try your function (I have split it into several lines for readability; it is also easy to check correctness this way):

```
f <- function(y) {
g <- function (u) 1 - exp(-0.002926543 * u^1.082618 * exp(0.04097536 * u))
a <- 1 - pbeta(g(107.2592+y), 0.2640229, 0.1595841)
b <- 1 - pbeta(g(x), 0.2640229, 0.1595841)
a - b^2
}
x <- 0.5
curve(f, from = 0, to = 1000)
```

How could this function be a horizontal line? It can't have a root!

- Check the
`f`

above, is it really doing the right thing you want? I doubt something is wrong with `g`

; you might put brackets in the wrong place?
- Once you get
`f`

correct, use `curve`

to inspect a proper interval where there a root exists. Then use `uniroot`

.

`curve(f(x), 0, 1000)`

. Doesn't look like it crosses 0. – MrFlick Aug 15 '16 at 19:35