Given:
Speed = 2.70 m
Time, t = 2.10 seconds
Let's solve for the following:
• (a) The horizontal component of the velocity.
To find the horizontal component, apply the formula:
[tex]V_{ox}=V_o\cos \theta[/tex]
Where:
Vo is the initial speed = 2.70 m
θ = 0 degrees
Hence, we have:
[tex]\begin{gathered} V_{ox}=2.70\cos 0 \\ \\ V_{ox}=2.7\text{ m/s} \end{gathered}[/tex]
The horizontal component of the velocity just before it lands is 2.70 m/s.
• (b) The vertical component of the velocity.
To find the vertical component, apply the formula:
[tex]V_{oy}=V_{0y}-gt=\text{V}_{oy}\text{ sin}\Theta-gt[/tex]
Where:
g is the acceleration due to gravity = 9.8 m/s²
t is the time = 2.10 s
Hence, we have:
[tex]\begin{gathered} V_{oy}=V_{oy}\sin \theta-gt \\ \\ V_{oy}=2.70\sin 0-9.8(2.10) \\ \\ V_{oy}=0-20.58 \\ \\ V_{oy}=-20.58\text{ m/s} \end{gathered}[/tex]
The vertical component of the velocity just before it lands is -20.58 m/s.
(c) Here, the initial speed is equal to the constant horizontal speed.
Therefore, in part (a) the horizontal component will increase in the x-direction if the speed of the crow is increased.
The initial vertical velocity is 0 m/s in both cases.
Therefore, in part (b) the vertical component will remain constant.
ANSWER:
(a) 2.70 m/s
(b) -20.58
(c) In part (a) the horizontal component will increase, while in part (b) the vertical component will remain constant.
