A projectile is shot from the ground at an angle of #( pi)/3 # and a speed of #9 m/s#. Factoring in both horizontal and vertical movement, what will the projectile's distance from the starting point be when it reaches its maximum height?

2 Answers
Feb 21, 2018

The distance is #=4.74m#

Explanation:

Resolving in the vertical direction #uarr^+#

The initial velocity is #u_0=9sin(1/3pi)ms^-1#

Applying the equation of motion

#v^2=u^2+2as#

At the greatest height, #v=0ms^-1#

The acceleration due to gravity is #a=-g=-9.8ms^-2#

Therefore,

The greatest height is #h_y=s=(0-(9sin(1/3pi))^2)/(-2g)#

#h_y=(9sin(1/3pi))^2/(2g)=3.1m#

The time to reach the greatest height is #=ts#

Applying the equation of motion

#v=u+at=u- g t #

The time is #t=(v-u)/(-g)=(0-9sin(1/3pi))/(-9.8)=0.795s#

Resolving in the horizontal direction #rarr^+#

The velocity is constant and #u_x=9cos(1/3pi)#

The distance travelled in the horizontal direction is

#s_x=u_x*t=9cos(1/3pi)*0.795=3.58m#

The distance from the starting point is

#d=sqrt(h_y^2+s_x^2)=sqrt(3.1^2+3.58^2)=4.74m#

Feb 21, 2018

#~~ 4.733# m

Explanation:

The maximum height the projectile reaches is
#H = {u^2 sin^2 alpha}/{2g} = {81times 3/4}/{2 times 9.8} ~~3.1 # m

At this point, the horizontal distance traveled is half of the horizontal range #D = u^2/{ g} sin alpha cos alpha ~~ 3.578# m

The distance from the starting point is, then

#sqrt{H^2+D^2} ~~ 4.733# m