In the previous part of Lesson 2, the use of kinematic equations to solve projectile problems was introduced and demonstrated. These equations were used to solve problems involving the launching of projectiles in a horizontal direction from an elevated position. In this section of Lesson 2, the use of kinematic equations to solve nonhorizontally launched projectiles will be demonstrated. A nonhorizontally launched projectile is a projectile that begins its motion with an initial velocity that is both horizontal and vertical. To treat such problems, the same principles that were discussed earlier in Lesson 2 will have to be combined with the kinematic equations for projectile motion. You may recall from earlier that there are two sets of kinematic equations  a set of equations for the horizontal components of motion and a similar set for the vertical components of motion. For the horizontal components of motion, the equations are
x = v_{i}_{x}•t + 0.5*a_{x}*t^{2}
v_{f}_{x} = v_{i}_{x} + a_{x}•t
v_{f}_{x}^{2} = v_{i}_{x}^{2} + 2*a_{x}•x
where 
x = horiz. displacement 
a_{x} = horiz. acceleration 
t = time 

v_{f}_{x} = final horiz. velocity 
v_{i}_{x} = initial horiz. velocity 
Of these three equations, the top equation is the most commonly used. The other two equations are seldom (if ever) used. An application of projectile concepts to each of these equations would also lead one to conclude that any term with a_{x} in it would cancel out of the equation since a_{x} = 0 m/s/s.
For the vertical components of motion, the three equations are
y = v_{iy}•t + 0.5*ay*t^{2}
v_{fy} = v_{iy} + ay•t
v_{fy}^{2} = v_{iy}^{2} + 2*ay•y
where 
y = vert. displacement 
ay = vert. acceleration 
t = time 

v_{fy} = final vert. velocity 
v_{iy} = initial vert. velocity 
In each of the above equations, the vertical acceleration of a projectile is known to be 9.8 m/s/s (the acceleration of gravity).
As discussed earlier in Lesson 2, the v_{ix} and v_{iy} values in each of the above sets of kinematic equations can be determined by the use of trigonometric functions. The initial xvelocity (v_{ix}) can be found using the equation v_{ix} = v_{i}•cosine(Theta) where Theta is the angle that the velocity vector makes with the horizontal. The initial yvelocity (v_{iy}) can be found using the equation v_{iy} = v_{i}•sine(Theta) where Theta is the angle that the velocity vector makes with the horizontal. The topic of components of the velocity vector was discussed earlier in Lesson 2.
To illustrate the usefulness of the above equations in making predictions about the motion of a projectile, consider their use in the solution of the following problem.
Example
A football is kicked with an initial velocity of 25 m/s at an angle of 45degrees with the horizontal. Determine the time of flight, the horizontal displacement, and the peak height of the football.

The solution of any nonhorizontally launched projectile problem (in which v_{i} and Theta are given) should begin by first resolving the initial velocity into horizontal and vertical components using the trigonometric functions discussed above. Thus,
Horizontal Component

Vertical Component

v_{ix} = v_{i}•cos(Theta)
v_{ix} = 25 m/s•cos(45 deg)
v_{ix} = 17.7 m/s

v_{iy} = v_{i}•sin(Theta)
v_{iy} = 25 m/s•sin(45 deg)
v_{iy} = 17.7 m/s

In this case, it happens that the v_{ix} and the v_{iy} values are the same as will always be the case when the angle is 45degrees.
The solution continues by declaring the values of the known information in terms of the symbols of the kinematic equations  x, y, v_{ix}, v_{iy}, a_{x}, a_{y}, and t. In this case, the following information is either explicitly given or implied in the problem statement:
Horizontal Information

Vertical Information

x = ???
v_{ix} = 17.7 m/s
v_{fx} = 17.7 m/s
a_{x} = 0 m/s/s

y = ???
v_{iy} = 17.7 m/s
v_{fy} = 17.7 m/s
a_{y} = 9.8 m/s/s

As indicated in the table, the final xvelocity (v_{fx}) is the same as the initial xvelocity (v_{ix}). This is due to the fact that the horizontal velocity of a projectile is constant; there is no horizontal acceleration. The table also indicates that the final yvelocity (v_{fy}) has the same magnitude and the opposite direction as the initial yvelocity (v_{iy}). This is due to the symmetrical nature of a projectile's trajectory.
The unknown quantities are the horizontal displacement, the time of flight, and the height of the football at its peak. The solution of the problem now requires the selection of an appropriate strategy for using the kinematic equations and the known information to solve for the unknown quantities. There are a variety of possible strategies for solving the problem. An organized listing of known quantities in two columns of a table provides clues for the selection of a useful strategy.
From the vertical information in the table above and the second equation listed among the vertical kinematic equations (v_{fy} = v_{iy} + a_{y}*t), it becomes obvious that the time of flight of the projectile can be determined. By substitution of known values, the equation takes the form of
17.7 m/s = 17.7 m/s + (9.8 m/s/s)•t
The physics problem now takes the form of an algebra problem. By subtracting 17.7 m/s from each side of the equation, the equation becomes
35.4 m/s = (9.8 m/s/s)•t
If both sides of the equation are divided by 9.8 m/s/s, the equation becomes
3.61 s = t
(rounded from 3.6077 s)
The total time of flight of the football is 3.61 seconds.
With the time determined, information in the table and the horizontal kinematic equations can be used to determine the horizontal displacement (x) of the projectile. The first equation (x = v_{ix}•t + 0.5•a_{x}•t^{2}) listed among the horizontal kinematic equations is suitable for determining x. With the equation selected, the physics problem once more becomes transformed into an algebra problem. By substitution of known values, the equation takes the form of
x = (17.7 m/s)•(3.6077 s) + 0.5•(0 m/s/s)•(3.6077 s)^{2}
Since the second term on the right side of the equation reduces to 0, the equation can then be simplified to
x = (17.7 m/s)•(3.6077 s)
Thus,
x = 63.8 m
The horizontal displacement of the projectile is 63.8 m.
Finally, the problem statement asks for the height of the projectile at is peak. This is the same as asking, "what is the vertical displacement (y) of the projectile when it is halfway through its trajectory?" In other words, find y when t = 1.80 seconds (onehalf of the total time). To determine the peak height of the projectile (y with t = 1.80 sec), the first equation (y = v_{iy}•t +0.5•a_{y}•t^{2}) listed among the vertical kinematic equations can be used. By substitution of known values into this equation, it takes the form of
y = (17.7 m/s)•(1.80 s) + 0.5*(10 m/s/s)•(1.80 s)^{2}
Using a calculator, this equation can be simplified to
y = 31.9 m + (15.9 m)
And thus,
y = 15.9 m
The solution to the problem statement yields the following answers: the time of flight of the football is 3.61 s, the horizontal displacement of the football is 63.8 m, and the peak height of the football 15.9 m.
(Note that in all calculations performed above, unrounded numbers were used. The numbers reported in the preliminary steps and in the final answer were the rounded form of the actual unrounded values.)
A Typical ProblemSolving Approach
The following procedure summarizes the above problemsolving approach.

Use the given values of the initial velocity (the magnitude and the angle) to determine the horizontal and vertical components of the velocity (v_{ix} and v_{iy}).

Carefully read the problem and list known and unknown information in terms of the symbols of the kinematic equations. For convenience sake, make a table with horizontal information on one side and vertical information on the other side.

Identify the unknown quantity that the problem requests you to solve for.

Select either a horizontal or vertical equation to solve for the time of flight of the projectile. For nonhorizontally launched projectiles, the second equation listed among the vertical equations (v_{fy} = v_{iy} + a_{y}*t) is usually the most useful equation.

With the time determined, use a horizontal equation (usually x = v_{ix}*t + 0.5*a_{x}*t^{2 }) to determine the horizontal displacement of the projectile.

Finally, the peak height of the projectile can be found using a time value that is onehalf the total time of flight. The most useful equation for this is usually y = v_{iy}*t +0.5*a_{y}*t^{2} .
One caution is in order: the sole reliance upon 4 and 5step procedures to solve physics problems is always a dangerous approach. Physics problems are usually just that  problems! And problems can often be simplified by the use of short procedures as the one above. However, not all problems can be solved with the above procedure. While steps 1, 2 and 3 above are critical to your success in solving nonhorizontally launched projectile problems, there will always be a problem that doesn't "fit the mold." Problem solving is not like cooking; it is not a mere matter of following a recipe. Rather, problem solving requires careful reading, a firm grasp of conceptual physics, critical thought and analysis, and lots of disciplined practice. Never divorce conceptual understanding and critical thinking from your approach to solving problems.
Your Turn to Try It!
Use the Range of an AngleLaunched Projectile widget to practice a projectile problem (or two) (or three). Using the given launch velocity and launch angle, determine the expected horizontal displacement (d_{x}). After completing your calculation, use the Submit button to check your answer.
Check Your Understanding
A long jumper leaves the ground with an initial velocity of 12 m/s at an angle of 28degrees above the horizontal. Determine the time of flight, the horizontal distance, and the peak height of the longjumper.