To find the displacement of the particle over time, we need to integrate the equation for acceleration with respect to time, and then solve for displacement.
Given: Acceleration (a) = bt Initial velocity (vo)
Let's integrate the equation for acceleration with respect to time (t) to obtain the equation for velocity (v):
∫a dt = ∫(bt) dt v = ∫(bt) dt v = (1/2)bt^2 + C
Here, C represents the constant of integration. To determine this constant, we'll use the initial velocity (vo) at time t = 0:
v(0) = (1/2)b(0)^2 + C vo = C
So, C = vo, and the equation for velocity becomes:
v = (1/2)bt^2 + vo
Now, we integrate the equation for velocity with respect to time (t) to obtain the equation for displacement (s):
∫v dt = ∫[(1/2)bt^2 + vo] dt s = (1/6)bt^3 + vot + D
Here, D represents the constant of integration. To determine this constant, we'll use the initial displacement (so) at time t = 0:
s(0) = (1/6)b(0)^3 + vo(0) + D so = D
So, D = so, and the equation for displacement becomes:
s = (1/6)bt^3 + vot + so
Therefore, the displacement of the particle at time t will be given by the equation:
s = (1/6)bt^3 + vot + so