Answer: 89.803 ft
Explanation:
The complete question is written below:
An astronaut on the moon throws a baseball upward. The astronaut is 6ft, 6 in. tall and the initial velocity of the ball is 30 ft per second. The height s of the ball in feet is given by the equation,s=-2.7t^2+30t+6.5, where t is the number of seconds after the ball is thrown.
The ball will never reach a height of 100ft. How can this be determined algebraically?
We have the following equation that expresses the height [tex]s[/tex] as a function of time:
[tex]s=-2.7t^{2}+30t+6.5[/tex] (1)
Now, if we wan to find the maximum height the baseball reaches and prove it is less than 100 ft, we firstly have to find the time [tex]t_{total}[/tex] the whole parabolic movement lasts and then find [tex]t_{smax}=\frac{t_{total}}{2}[/tex] which is the time it takes the baseball to reach its maximum height.
So, if we want to calculate [tex]t_{total}[/tex], this is fulfilled when [tex]s=0[/tex], when the baseball hits the ground:
[tex]0=-2.7t^{2}+30t+6.5[/tex] (2)
This is a quadratic equation of the form [tex]0=at^{2}+bt+c[/tex], and we have to use the quadratic formula if we want to find [tex]t_{total}[/tex]:
[tex]t=\frac{-b\pm\sqrt{b^{2}-4ac}}{2a}[/tex] (3)
Where [tex]a=-2.7[/tex], [tex]b=30[/tex], [tex]c=6.5[/tex]
Substituting the known values and choosing the positive result of the equation:
[tex]t_{total}=11.323 s[/tex] (4)
Then we can calculate [tex]t_{smax}[/tex]:
[tex]t_{smax}=\frac{t_{total}}{2}[/tex] (5)
[tex]t_{smax}=\frac{11.323 s}{2}[/tex]
[tex]t_{smax}=5.661 s[/tex] (6)
Substituting (6) in (1):
[tex]s=-2.7(5.661 s)^{2}+30(5.661 s)+6.5[/tex] (7)
[tex]s=89.803 ft[/tex] (8) This is the maximum height the baseball reaches, as we can see it is less than 100 ft
