(a) [tex]h(t)[/tex] gives the height at time [tex]t[/tex], so the flare's starting height is given by [tex]h(0)[/tex]:
[tex]h(0)=-5(0)^2+90(0)+1=1\,\mathrm m[/tex]
(b) There are several ways to find the maximum height of the flare. One is to complete the square and write [tex]h(t)[/tex] in vertex form:
[tex]-5t^2+90t+1=-5(t^2+18t)+1=-5(t^2-18t+81-81)+1=-5(t-9)^2+406[/tex]
That is, [tex]h(t)[/tex] describes a parabola whose vertex is located at (9, 406); the coefficient of -5 tells us that the parabola is concave, which means the parabola "opens" downward, and the vertex is a maximum. So the maximum height is 406 m.
(C) The flare hits the ground when [tex]h(t)=0[/tex]:
[tex]-5t^2+90t+1=0\implies t=9\pm\sqrt{\dfrac{406}5}[/tex]
or at about [tex]t\approx-0.011[/tex] and [tex]t\approx18.01[/tex]. We ignore the negative solution (negative time makes no physical sense).
