1.8: Projectile Motion (2024)

Projectile motionis themotionof an object thrown or projected into the air, subject to only the acceleration of gravity. The object is called aprojectile, and its path is called itstrajectory. The motion of falling objects is a simple one-dimensional type of projectile motion in which there is no horizontal movement. In this section, we consider two-dimensional projectile motion, such as that of a football or other object for whichair resistanceis negligible.

The most important fact to know here is thatmotions along perpendicular axes are independentand thus can be considered separately. In particular, it is often convenient to consider vertical and horizontal motions separately, or independently. The key to analyzing two-dimensional projectile motion is to break it into two motions, one along the horizontal axis and the other along the vertical. And we will assume all forces except gravity are negligible (that is, we ignore forces due to air resistance, wind, friction, etc.). The vertical component of acceleration is, then, \(a_{y}=-g=-9.80 \mathrm{~m} / \mathrm{s}^{2}\), where we take upward direction as the positive \(y\) direction. And because there is no force in the horizontal direction, \(a_{x}=0 \).Figure\(\PageIndex{1}\)illustrates this approach to analyzing projectile motion.

One of the conceptual aspects of projectile motion we can discuss without a detailed analysis is the range. On level ground, we definerangeto be the horizontal distance \(R\) traveled by a projectile. The range of projectiles describes everyday phenomena such as how far a football can be thrown or kicked. Also, investigating the range of projectiles can shed light on other interesting phenomena, such as the orbits of satellites around the Earth. Let us consider projectile range further.

How does the initial velocity of a projectile affect its range? It is intuitive to guess that, the greater the initial speed \(v_{0}\), the greater the range, as shown in Figure \(\PageIndex{2}\) (a). The initial angle \(\theta_{0}\)also has a dramatic effect on the range, as illustrated in Figure \(\PageIndex{2}\) (b). For a fixed initial speed, such as might be produced by a cannon, the maximum range is obtained with \(\theta_{0}=45^{\circ} \). Interestingly, for every initial angle except\(45^{\circ}\), there are two angles that give the same range. The range also depends on the value of the acceleration of gravity \(g\). The lunar astronaut Alan Shepherd was able to drive a golf ball a great distance on the Moon because gravity is weaker there. The range \(R\)of a projectile onlevel groundfor which air resistance is negligible is given by

\[R=\frac{v_{0}^{2} \sin 2 \theta_{0}}{g}, \nonumber\]

where \(v_{0}\)is the initial speed and \(\theta_{0}\) is the initial angle relative to the horizontal. This formula (which can be derived using algebra and trigonometry) fits the major features of projectile range as described.

When we speak of the range of a projectile on level ground, we assume that \(R\)is very small compared with the circumference of the Earth. If, however, the range is large, the Earth curves away below the projectile and acceleration of gravity changes direction along the path. The range is larger than predicted by the range equation given above because the projectile has farther to fall than it would on level ground. (See Figure \(\PageIndex{3}\).) If the initial speed is great enough, the projectile goes into orbit. This possibility was recognized centuries before it could be accomplished. When an object is in orbit, the Earth curves away from underneath the object at the same rate as it falls. The object thus falls continuously but never hits the surface.