@Jonel_R, your problem can be solved analytically.

First I'll rename your variables to make it easier to type. I'll also use some notation abuse...

We want to find the values `(a, b)`

such that the roots of `z^2 + a z + b == 0`

satisfy the property `|z|<=1`

.

The roots are given by `(-a +- sqrt(d))/2`

, where `d = a^2 - 4b`

There are 3 possibilities. Two real distinct roots, one real root or two complex conjugate roots.

The middle case happens when `d = 0`

, i. e., `b = a^2 / 4`

. This is a parabola in the `a vs. b`

plane. Not all points in this parabola generate polynomials whose root satisfy `|z|<=1`

, however. The root, is this case, is simply `-a/2`

, so we mus add the condition `-1 <= a/2 <=1`

, i. e., `-2 <= a <= 2`

.

Now let's consider the first case. The points in the `a vs. b`

plae that generate polynomials with two distinct real roots lie *below* the parabola, i. e., they must satisfy `b < a^2/4`

. The additional condition is that `|z| = |(-a +- sqrt(d))/2| <= 1`

.

The condition can be written as `-1 <= (-a +- sqrt(d))/2 <= 1`

, where `+-`

means both roots must satisfy the condition. Working this out we get:

`a-2 <= sqrt(d) <= a+2`

& `a-2 <= -sqrt(d) <= a+2`

Since both `sqrt(d)`

and `-sqrt(d)`

must lie in the interval `[a-2, a+2]`

, and `d > 0`

, then this interval must contain zero in its interior. This means `-2 < a < 2`

.

The conditions can be joined as:
`a-2 <= -sqrt(d) < 0 < sqrt(d) <= a+2`

Squaring gives:
`(a-2)^2 >= d`

& `d <= (a+2)^2`

`d <= a^2 - 4a + 4`

& `d <= a^2 + 4a + 4`

`-4b <= -4a + 4`

& `-4b <= +4a + 4`

`b >= a-1`

& `b >= -a-1`

This means that `b`

must be located above the lines `b = a-1`

and `b=-a-1`

. Also, `a`

must be in `[-2,2]`

. And, of course, we must have `b < a^2/4`

. Wow...

Now the last case: complex roots. This is easier. Since `d < 0`

, the roots are `-a/2 +- i * sqrt(-d)/2`

. The absolute value of this is `a^2/4 - d/4`

. This equals `b`

, simply. So the condition is `b <= 1`

, and, as always, `b`

lying above that parabola.

That's it... Quite interesting problem. :-)

You can try the following test function: It'll plot the points with real roots in blue and complex roots in red.

```
test <- function(x=2, n=10000)
{
plot(c(-x,x), c(-x,x), type="n")
plot(function(a) (a^2)/4, from=-x, to=x, add=T)
plot(function(a) a-1, from=-x, to=x, add=T)
plot(function(a) -a-1, from=-x, to=x, add=T)
a <- runif(n, -x, x)
b <- runif(n, -x, x)
for( i in 1:n )
{
if( all(abs(polyroot(c(b[i],a[i],1))) <= 1) )
{
col <- ifelse(b[i] < 0.25*a[i]^2, "blue", "red")
points(a[i], b[i], pch=".", col=col)
}
}
}
```

BTW: the syntax for `polyroot`

is `polyroot(c(C, B, A))`

gives the roots of `Ax^2 + Bx + C`

. I believe @agstudy response got it wrong.