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To calculate the position function x(t) for the particle undergoing acceleration given by a = -bv, you can integrate the equation of motion.

Let's start by solving the differential equation. We have:

a = -bv

Since acceleration is the derivative of velocity with respect to time, we can rewrite the equation as:

dv/dt = -bv

To solve this differential equation, we can separate variables:

dv/v = -b dt

Integrating both sides, we get:

∫(dv/v) = -∫b dt

ln|v| = -bt + C

Where C is the constant of integration. Taking the exponential of both sides:

|v| = e^(-bt+C)

Since the absolute value is used, we can remove the absolute value sign by introducing a positive constant D:

v = De^(-bt)

Now, we need to solve for the position x(t). The velocity v(t) is the derivative of the position x(t) with respect to time:

v = dx/dt

To find x(t), we integrate the velocity expression:

∫v dt = ∫De^(-bt) dt

x(t) = -D/b * e^(-bt) + C'

Where C' is another constant of integration. We can rewrite this equation using initial conditions. Let's assume at t = 0, the velocity is v0, and the position is x0:

v(0) = v0

x(0) = x0

Substituting these initial conditions into the equation:

v(0) = D * e^(-b * 0)

v0 = D

x(0) = -D/b * e^(-b * 0) + C'

x0 = -D/b + C'

C' = x0 + D/b

Substituting the value of D obtained from the initial velocity condition into C':

C' = x0 + v0/b

Finally, we can rewrite the position function x(t) in terms of x0, v0, and the constant b:

x(t) = -v0/b * e^(-bt) + x0 + v0/b * e^(-b * 0)

x(t) = x0 + (v0/b) * (1 - e^(-bt))

So, the answer is x(t) = x0 + (v0/b) * (1 - e^(-bt)).

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