Given the equation `ax^2 + bx + c`

, we know that the discriminant `D = b^2 - 4ac`

tells us if the equation will have two distinct roots `D > 0`

, one repeated root `D = 0`

, or no real roots `D < 0`

. Clearly, if the discriminant is zero, then an error could make it either positive or negative, depending on where the error is greater.
Prove that if the discriminant is nonzero, then no error in the floating-point calculation can flip its sign (i.e., from positive to negative, or from negative to positive). Can an error make the discriminant equal to zero?

I know this has little to do with actual programming but exactly how do i show that it is impossible that for `floating point calculation error of the discriminant`

to cause a positive discriminant D to somehow become negative and vice versa.

`b^2`

is always non-negative. Unlike two's-complement integers the sign is stored separately in floating-point representation, so you can't get 'accidental' sign changes due to overflow. – Tim Sylvester Apr 6 '11 at 0:31