How Do You Calculate Stopping Distance with Velocity-Dependent Resistive Force?

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SUMMARY

The discussion focuses on calculating stopping distance for a block experiencing a velocity-dependent resistive force, defined as -Kv, where K is the proportionality constant. The force balance equation is established as m dv/dt = -Kv, leading to the solution v = v(initial) * e^(-Kt/m). This solution is derived from solving a first-order linear differential equation, which is essential for understanding the dynamics of motion under resistive forces. The discussion highlights the importance of correctly identifying the resistive force as a function of velocity rather than position.

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dynamics problem!

this is a problem about a resistive force that is a function of v, not x.
a block with an initial velocity goes through a medium that resists motion with force proportional to the block's velocity, with proportionality constant K. so basically the resistive force = -Kx (i choose the pos x dir to be in the dir of initial velocity)
i am supposed to find the stopping distance by finding v as a function of x and then i am supposed to find it again by finding v as a function of t.
i cruised wikipedia because it helped me on an escape velocity problem, and it gave me some help, but i don't know how they got what they did and I am not entirely sure if its what i want.

they said:
-Kx = ma = m dv/dt which i have and understand
they say it integrates to
v = v(initial) * e^(-Kt/m)
can anyone explain how they got that? i am missing some math skillz here.
any other insights to the problem would be greatly appreciated. :smile:
 
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The problem statement indicates that a resistive force a function of velocity, i.e. is proportional to velocity, then

force = -Kv, or -K[itex]\dot{x}[/itex], and not force = -Kx.

So the force balance becomes,

m dv/dt = -Kv which is a first order linear differential equation,

which gives the solution

v = v(initial) * e^(-Kt/m) for v=v(initial) at t=0.
 

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