4.3 Projectile motion  (Page 4/13)

(a) Choose the top of the cliff where the rock is thrown from the origin of the coordinate system. Although it is arbitrary, we typically choose time t = 0 to correspond to the origin. (b) The equation that describes the horizontal motion is $x=x_0+v_{x}t.$ With $x_0=0,$ this equation becomes $x=v_{x}t.$ (c) [link] through [link] and [link] describe the vertical motion, but since $y_0=0\text{and}{v}_{0y}=0,$ these equations simplify greatly to become $y=\frac{1}{2}(v_{0y}+v_y)t=\frac{1}{2}{v}_{y}t,$ $v_y=\text{−}gt,$ $y=-\frac{1}{2}g{t}^2,$ and $v_y^2=\mathrm{-2}gy.$ (d) We use the kinematic equations to find the x and y components of the velocity at the point of impact. Using $v_y^2=\mathrm{-2}gy$ and noting the point of impact is −100.0 m, we find the y component of the velocity at impact is $v_y=44.3\text{m}\text{/}\text{s}.$ We are given the x component, $v_x=15.0\text{m}\text{/}\text{s},$ so we can calculate the total velocity at impact: v = 46.8 m/s and $\theta =71.3\text{°}$ below the horizontal.