Solve $-16t^2+64t+80=120$ to get $2t^2-8t+5=0$, so $t=\frac{4\pm\sqrt{6}}{2}$ and the later time is $\frac{4+\sqrt{6}}{2}$. The other choices use a wrong discriminant, incorrect simplification, or select the earlier time.

Set $h(t)=0$: $-16t^2+32t+48=0\Rightarrow t^2-2t-3=0\Rightarrow(t-3)(t+1)=0$, so $t=3$ or $t=-1$; only $t=3$ is valid. The other positive choices come from algebra slips.

Squaring gives $x+5=x^2-2x+1\Rightarrow x^2-3x-4=0\Rightarrow(x-4)(x+1)=0$. Checking in the original shows $x=4$ works but $x=-1$ is extraneous.

Exactly one real solution requires discriminant $k^2-4(2)(8)=0\Rightarrow k^2=64$, so $k=\pm 8$. Other options miss one value or use the wrong discriminant.

The vertex $x$-coordinate is $-\frac{b}{2a}=\frac{6}{2}=3$. The other options come from sign or factor-of-2 errors.

Set $y=0$ at $x=-2$: $2(-2)^2+p(-2)+8=0\Rightarrow 16-2p=0$, so $p=8$. The other choices reflect sign or arithmetic mistakes (e.g., taking $p=-8$ or miscomputing $2(-2)^2$).

The maximum occurs at the vertex $t=-\frac{b}{2a}=-\frac{32}{2(-16)}=1$. 0.5 and 2 result from arithmetic slips with $-b/(2a)$, and 32 is just $b$.

Exactly one real root means the discriminant $k^2-36=0$, so $|k|=6$ and the positive value is 6. -6 ignores 'positive,' while 0 and 36 come from misusing the discriminant.

The vertex is at $x=\frac{-b}{2a}=\frac{6}{2}=3$, and $y(3)=9-18+11=2$, the minimum. 3 is the x-coordinate, -2 is a sign error, and 11 is the constant term.

Solve $-16t^2 + 32t + 5 = 0$ to get $t = \frac{4 \pm \sqrt{21}}{4}$. The positive solution is $1 + \frac{\sqrt{21}}{4}$.