Harmonic oscillation in classical mechanics

AI Thread Summary
The discussion focuses on analyzing harmonic oscillation for a mass-spring system affected by a resistive force proportional to velocity. The object, with a mass of 300g and a spring constant of 3.0 Nm-1, is displaced and released, prompting the need for a free body diagram and the equation of motion. The equation derived is -c1v - kx = m dv/dt, which leads to a velocity solution of v = -kx/c1(1 - e^(-c1t/m)). Participants express difficulty in deriving the position versus time equation, emphasizing the need to relate velocity and position through the differential equation. The discussion highlights the importance of correctly formulating the second-order differential equation for the position function x(t).
sya deela
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Homework Statement


An object of mass m = 300g is attached to a spring with a constant k = 3.0Nm-1 and is at rest on a smooth horizontal floor in a fluid where the resistive force is assumed to be linearly proportional to the velocity v. the object is then displaced 10mm to the right of the equilibrium position and released. Given the constant of proportionality c1 = 0.2kgs-1;

Homework Equations


i) sketch the free body diagram (FBD) and write the equation of motion for the object immediately after it is set in motion
ii) write the solution to equation of motion in i) and describe the motion, and
iii) sketch the graph of the position versus time for the object.

The Attempt at a Solution


i) F(x) = -kx
Fv-F(x)= m dv/dt
-c1v-kx= m dv/dt

ii) -c1v-kx= m dv/dt after inegrate both sides v0 is zero
then v=-kx/c1(1-e(-c1t/m))

i can't get the equation for position versus time...

 
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Use ##v=dx/dt##.
 
eys_physics said:
Use ##v=dx/dt##.
i already try it..but as i know that for harmonic oscillation the graph should be cos / sin .So i don't know how to relate it.
 
sya deela said:

Homework Statement


An object of mass m = 300g is attached to a spring with a constant k = 3.0Nm-1 and is at rest on a smooth horizontal floor in a fluid where the resistive force is assumed to be linearly proportional to the velocity v. the object is then displaced 10mm to the right of the equilibrium position and released. Given the constant of proportionality c1 = 0.2kgs-1;

Homework Equations


i) sketch the free body diagram (FBD) and write the equation of motion for the object immediately after it is set in motion
ii) write the solution to equation of motion in i) and describe the motion, and
iii) sketch the graph of the position versus time for the object.

The Attempt at a Solution


i) F(x) = -kx
Fv-F(x)= m dv/dt
-c1v-kx= m dv/dt

ii) -c1v-kx= m dv/dt after inegrate both sides v0 is zero
then v=-kx/c1(1-e(-c1t/m))

i can't get the equation for position versus time...

I don't understand what you are doing at ii). Here both ##x## and ##t## depends on ##t##. So, your equation is
$$-c1 v(t)-kx(t)=mdv/dt$$
By using ##v(t)=dx/dt## in this equation, you can derive a second-order differential equation for ##x(t)##.
 

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