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x = v 0 x t t = x v 0 x = x v 0 cos θ 0 .

Substituting the expression for t into the equation for the position y = ( v 0 sin θ 0 ) t 1 2 g t 2 gives

y = ( v 0 sin θ 0 ) ( x v 0 cos θ 0 ) 1 2 g ( x v 0 cos θ 0 ) 2 .

Rearranging terms, we have

y = ( tan θ 0 ) x [ g 2 ( v 0 cos θ 0 ) 2 ] x 2 .

This trajectory equation is of the form y = a x + b x 2 , which is an equation of a parabola with coefficients

a = tan θ 0 , b = g 2 ( v 0 cos θ 0 ) 2 .

Range

From the trajectory equation we can also find the range    , or the horizontal distance traveled by the projectile. Factoring [link] , we have

y = x [ tan θ 0 g 2 ( v 0 cos θ 0 ) 2 x ] .

The position y is zero for both the launch point and the impact point, since we are again considering only a flat horizontal surface. Setting y = 0 in this equation gives solutions x = 0, corresponding to the launch point, and

x = 2 v 0 2 sin θ 0 cos θ 0 g ,

corresponding to the impact point. Using the trigonometric identity 2 sin θ cos θ = sin 2 θ and setting x = R for range, we find

R = v 0 2 sin 2 θ 0 g .

Note particularly that [link] is valid only for launch and impact on a horizontal surface. We see the range is directly proportional to the square of the initial speed v 0 and sin 2 θ 0 , and it is inversely proportional to the acceleration of gravity. Thus, on the Moon, the range would be six times greater than on Earth for the same initial velocity. Furthermore, we see from the factor sin 2 θ 0 that the range is maximum at 45 ° . These results are shown in [link] . In (a) we see that the greater the initial velocity, the greater the range. In (b), we see that the range is maximum at 45 ° . This is true only for conditions neglecting air resistance. If air resistance is considered, the maximum angle is somewhat smaller. It is interesting that the same range is found for two initial launch angles that sum to 90 ° . The projectile launched with the smaller angle has a lower apex than the higher angle, but they both have the same range.

Figure a shows the trajectories of projectiles launched at the same initial 45 degree angle above the horizontal and different initial velocities. The trajectories are shown from launch to landing back at the initial elevation. In orange is the trajectory for 30 meters per second, giving a range R (distance from launch to landing) of 91.8 m. In purple is the trajectory for 40 meters per second, giving a range R of 163 m. In blue is the trajectory for 50 meters per second, giving a range R of 255 m. The maximum height of the projectile increases with initial speed. Figure b shows the trajectories of projectiles launched at the same initial speed of 50 meters per second and different launch angles. The trajectories are shown from launch to landing back at the initial elevation. In orange is the trajectory for an angle of 15 degrees above the horizontal, giving a range R of 128 m. In purple is the trajectory for an angle of 45 degrees above the horizontal, giving a range R of 255 m. In blue is the trajectory for an angle of 75 degrees above the horizontal, giving a range R of 128 m, the same as for the 15 degree trajectory. The maximum height increases with launch angle.
Trajectories of projectiles on level ground. (a) The greater the initial speed v 0 , the greater the range for a given initial angle. (b) The effect of initial angle θ 0 on the range of a projectile with a given initial speed. Note that the range is the same for initial angles of 15 ° and 75 ° , although the maximum heights of those paths are different.

Comparing golf shots

A golfer finds himself in two different situations on different holes. On the second hole he is 120 m from the green and wants to hit the ball 90 m and let it run onto the green. He angles the shot low to the ground at 30 ° to the horizontal to let the ball roll after impact. On the fourth hole he is 90 m from the green and wants to let the ball drop with a minimum amount of rolling after impact. Here, he angles the shot at 70 ° to the horizontal to minimize rolling after impact. Both shots are hit and impacted on a level surface.

(a) What is the initial speed of the ball at the second hole?

(b) What is the initial speed of the ball at the fourth hole?

(c) Write the trajectory equation for both cases.

(d) Graph the trajectories.

Strategy

We see that the range equation has the initial speed and angle, so we can solve for the initial speed for both (a) and (b). When we have the initial speed, we can use this value to write the trajectory equation.

Solution

(a) R = v 0 2 sin 2 θ 0 g v 0 = R g sin 2 θ 0 = 90.0 m ( 9.8 m / s 2 ) sin ( 2 ( 70 ° ) ) = 37.0 m / s

(b) R = v 0 2 sin 2 θ 0 g v 0 = R g sin 2 θ 0 = 90.0 m ( 9.8 m / s 2 ) sin ( 2 ( 30 ° ) ) = 31.9 m / s

(c)
y = x [ tan θ 0 g 2 ( v 0 cos θ 0 ) 2 x ] Second hole: y = x [ tan 70 ° 9.8 m / s 2 2 [ ( 37.0 m / s)( cos 70 ° ) ] 2 x ] = 2.75 x 0.0306 x 2 Fourth hole: y = x [ tan 30 ° 9.8 m / s 2 2 [ ( 31.9 m / s)( cos 30 ° ) ] 2 x ] = 0.58 x 0.0064 x 2

(d) Using a graphing utility, we can compare the two trajectories, which are shown in [link] .

Two parabolic functions are shown. The range for both trajectories is 90 meters. One shot travels much higher than the other. The higher shot has an initial velocity of 37 meters per second and an angle of 70 degrees. The lower shot has an initial velocity of 31.9 meters per second and an angle of 30 degrees.
Two trajectories of a golf ball with a range of 90 m. The impact points of both are at the same level as the launch point.

Significance

The initial speed for the shot at 70 ° is greater than the initial speed of the shot at 30 ° . Note from [link] that two projectiles launched at the same speed but at different angles have the same range if the launch angles add to 90 ° . The launch angles in this example add to give a number greater than 90 ° . Thus, the shot at 70 ° has to have a greater launch speed to reach 90 m, otherwise it would land at a shorter distance.

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Source:  OpenStax, University physics volume 1. OpenStax CNX. Sep 19, 2016 Download for free at http://cnx.org/content/col12031/1.5
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