Answers:
a) [tex]\theta_{2}=38\°[/tex]
b) [tex]t=0.495 s[/tex]
Explanation:
This situation is a good example of the projectile motion or parabolic motion, in which the travel of the snowball has two components: x-component and y-component. Being their main equations as follows for both snowballs:
x-component:
[tex]x=V_{o}cos\theta_{1} t_{1}[/tex] (1)
Where:
[tex]V_{o}=14.1 m/s[/tex] is the initial speed of snowball 1 (and snowball 2, as well)
[tex]\theta_{1}=52\°[/tex] is the angle for snowball 1
[tex]t_{1}[/tex] is the time since the snowball 1 is thrown until it hits the opponent
y-component:
[tex]y=y_{o}+V_{o}sin\theta_{1} t_{1}+\frac{gt_{1}^{2}}{2}[/tex] (2)
Where:
[tex]y_{o}=0[/tex] is the initial height of the snowball 1 (assuming that both people are only on the x axis of the frame of reference, therefore the value of the position in the y-component is zero.)
[tex]y=0[/tex] is the final height of the snowball 1
[tex]g=-9.8m/s^{2}[/tex] is the acceleration due gravity (always directed downwards)
x-component:
[tex]x=V_{o}cos\theta_{2} t_{2}[/tex] (3)
Where:
[tex]\theta_{2}[/tex] is the angle for snowball 2
[tex]t_{2}[/tex] is the time since the snowball 2 is thrown until it hits the opponent
y-component:
[tex]y=y_{o}+V_{o}sin\theta_{2} t_{2}+\frac{gt_{2}^{2}}{2}[/tex] (4)
Having this clear, let's begin with the answers:
Firstly, we have to isolate [tex]t_{1}[/tex] from (2):
[tex]0=0+V_{o}sin\theta_{1} t_{1}+\frac{gt_{1}^{2}}{2}[/tex] (5)
[tex]t_{1}=-\frac{2V_{o}sin\theta_{1}}{g}[/tex] (6)
Substituting (6) in (1):
[tex]x=V_{o}cos\theta_{1}(-\frac{2V_{o}sin\theta_{1}}{g})[/tex] (7)
Rewritting (7) and knowing [tex]sin(2\theta)=sen\theta cos\theta[/tex]:
[tex]x=-\frac{V_{o}^{2}}{g} sin(2\theta_{1})[/tex] (8)
[tex]x=-\frac{(14.1 m/s)^{2}}{-9.8 m/s^{2}} sin(2(52\°))[/tex] (9)
[tex]x=19.684 m[/tex] (10) This is the point at which snowball 1 hits and snowball 2 should hit, too.
With this in mind, we have to isolate [tex]t_{2}[/tex] from (4) and substitute it on (3):
[tex]t_{2}=-\frac{2V_{o}sin\theta_{2}}{g}[/tex] (11)
[tex]x=V_{o}cos\theta_{2} (-\frac{2V_{o}sin\theta_{2}}{g})[/tex] (12)
Rewritting (12):
[tex]x=-\frac{V_{o}^{2}}{g} sin(2\theta_{2})[/tex] (13)
Finding [tex]\theta_{2}[/tex]:
[tex]2\theta_{2}=sin^{-1}(\frac{-xg}{V_{o}^{2}})[/tex] (14)
[tex]2\theta_{2}=75.99\°[/tex]
[tex]\theta_{2}=37.99\° \approx 38\°[/tex] (15) This is the second angle at which snowball 2 must be thrown. Note this angle is lower than the first angle [tex](\theta_{2} < \theta_{1})[/tex].
Now we will find the value of [tex]t_{1}[/tex] and [tex]t_{2}[/tex] from (6) and (11), respectively:
[tex]t_{1}=-\frac{2V_{o}sin\theta_{1}}{g}[/tex]
[tex]t_{1}=-\frac{2(14.1 m/s)sin(52\°)}{-9.8m/s^{2}}[/tex] (16)
[tex]t_{1}=2.267 s[/tex] (17)
[tex]t_{2}=-\frac{2V_{o}sin\theta_{2}}{g}[/tex]
[tex]t_{2}=-\frac{2(14.1 m/s)sin(38\°)}{-9.8m/s^{2}}[/tex] (18)
[tex]t_{2}=1.771 s[/tex] (19)
Since snowball 1 was thrown before snowball 2, we have:
[tex]t_{1}-t=t_{2}[/tex] (20)
Finding the time difference [tex]t[/tex] between both:
[tex]t=t_{1}-t_{2}[/tex] (21)
[tex]t=2.267 s - 1.771 s[/tex]
Finally:
[tex]t=0.495 s[/tex]
