Answer:
Step-by-step explanation:
(i) Since acceleration is constant, velocity is a linear function of time. The average velocity over the interval will serve for the purpose of computing the displacement.
d = (v1+v2)/2×t = (1.5 m/s +3.5 m/s)/2·(10 s) = 25 m
P is displaced 25 meters from O when t=10.
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(ii) Letting the initial velocity be represented by v1, we find the velocity as a function of time to be ...
[tex]\displaystyle v(t)=v_1+\int_0^{t}{a(t)}\,dt=v_1+\int_0^{t}0.03t\,dt=v_1+\dfrac{0.03t^2}{2}\\\\v(10)=v_1+0.015\cdot 10^2 = v_1+1.5\\\\3.5=v_1+1.5\ \rightarrow\ v_1=2.0\quad\text{m/s}\\\\v(t)=2.0+0.015t^2[/tex]
Then the displacement is the integral of velocity ...
[tex]\displaystyle d=\int_0^{10}{v(t)}\,dt=\int_0^{10}{(2.0+0.015t^2)}\,dt\\\\d=2.0(10)+0.015\left(\dfrac{10^3}{3}\right)=20+5=25[/tex]
Q is also displaced 25 meters from O when t=10.
