Answer:
a.[tex]\rm -1.49\ m/s^2.[/tex]
b. [tex]\rm 50.49\ m.[/tex]
Explanation:
Given:
The acceleration of the particle at a time is defined as the rate of change of velocity of the particle at that time.
[tex]\rm a = \dfrac{dv}{dt}\\=\dfrac{d}{dt}(3\cos(0.5\ t ))\\=3(-0.5\sin(0.5\ t.))\\=-1.5\sin(0.5\ t).[/tex]
At time t = 3 seconds,
[tex]\rm a=-1.5\sin(0.5\times 3)=-1.49\ m/s^2.[/tex]
Note: The arguments of the sine is calculated in unit of radian and not in degree.
The velocity of the particle at some is defined as the rate of change of the position of the particle.
[tex]\rm v = \dfrac{dr}{dt}.\\\therefore dr = vdt\Rightarrow \int dr=\int v\ dt.[/tex]
For the time interval of 2 seconds,
[tex]\rm \int\limits^2_0 dr=\int\limits^2_0 v\ dt\\r(t=2)-r(t=0)=\int\limits^2_0 3\cos(0.5\ t)\ dt[/tex]
The term of the left is the displacement of the particle in time interval of 2 seconds, therefore,
[tex]\Delta r=3\ \left (\dfrac{\sin(0.5\ t)}{0.05} \right )\limits^2_0\\=3\ \left (\dfrac{\sin(0.5\times 2)-sin(0.5\times 0)}{0.05} \right )\\=3\ \left (\dfrac{\sin(1.0)}{0.05} \right )\\=50.49\ m.[/tex]
It is the displacement of the particle in 2 seconds.
