@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
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
-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
(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
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(c(C, B, A)) gives the roots of
Ax^2 + Bx + C. I believe @agstudy response got it wrong.