The acceleration of the particle as a function of time t is
[tex]a(t) = t + t^2[/tex]
The velocity of the particle at time t is the integral of the acceleration:
[tex]v(t) = \int {a(t)} \, dt = \frac{t^2}{2} + \frac{t^3}{3} + C[/tex]
where the constant C can be found by requiring that the velocity at time t=0 is v=3:
[tex]v(0) = 3[/tex]
and we find [tex]C=v_0=3[/tex]
so the velocity is
[tex]v(t)=3+ \frac{t^2}{2}+ \frac{t^3}{3} [/tex]
The position of the particle at time t is the integral of the velocity:
[tex]x(t)=\int {v(t) } \,dt = 3t + \frac{t^3}{6}+ \frac{t^4}{12} +D[/tex]
where D can be found by requiring that the initial position at time t=0 is zero:
x(0)=0
from which we find D=0, so
[tex]x(t)=3t + \frac{t^3}{6}+ \frac{t^4}{12}[/tex]
To solve the problem, now we just have to substitute t=5 into x(t) and v(t) to find the position and the velocity of the particle at t=5.
The position is:
[tex]x(5)=3(5) + \frac{5^3}{6}+ \frac{5^4}{12}=87.92 [/tex]
and the velocity is:
[tex]v(5) = 3+ \frac{5^2}{2}+ \frac{5^3}{3}=57.17 [/tex]
