How to Solve a Damped Harmonic Oscillator Problem?

AI Thread Summary
To solve the damped harmonic oscillator problem, first, use the equation for amplitude decay, A(t) = A₀ e^(-bt/2m), where A₀ is the initial amplitude. Given that the amplitude decreases to 3/4 of its initial value after four oscillations, substitute t with 4T (where T is the period) to find the damping coefficient b. The period T has already been calculated as 2.8 seconds. To determine the energy lost during the four oscillations, calculate the initial and final energy using the total energy formula and find the difference. This approach will yield the required values for b and the energy lost.
wannabeadoc05
Messages
2
Reaction score
0
Hi,

I'm having a lot of trouble with a damped harmonic oscillator problem:

A damped harmonic oscillator consists of a block (m=2.00kg), a spring (k=10 N/m), and a damping force (F=-bv). Initially it oscillates with an amplitude of 25.0cm. Because of the damping force, the amplitude falls to 3/4 of this initial value at the completion of four osciallations. (a) What is the value of b? (b) How much energy has been "lost" during these four oscillations?

The truth is. I'm not really sure where to start. My book only gives a few equations to work with and I'm not sure how to relate them to find the value of b.

The first thing I did was find the period (T), by the equation
T=2∏ √(2.0Kg/10N/m) = 2.8s

...,but I'm not really sure what to do with it.

Any help with this would be awesome!

Thanks
 
Physics news on Phys.org
wannabeadoc05 said:
Hi,

I'm having a lot of trouble with a damped harmonic oscillator problem:

A damped harmonic oscillator consists of a block (m=2.00kg), a spring (k=10 N/m), and a damping force (F=-bv). Initially it oscillates with an amplitude of 25.0cm. Because of the damping force, the amplitude falls to 3/4 of this initial value at the completion of four osciallations. (a) What is the value of b? (b) How much energy has been "lost" during these four oscillations?

The truth is. I'm not really sure where to start. My book only gives a few equations to work with and I'm not sure how to relate them to find the value of b.

The first thing I did was find the period (T), by the equation
T=2∏ √(2.0Kg/10N/m) = 2.8s

...,but I'm not really sure what to do with it.

Any help with this would be awesome!

Thanks

The equation for the damped oscillator along let's say the "x" axis reads:
m\frac{d^2 x}{dt^2}+v\frac{dv}{dt}+kx=0..
The period is T=2\pi\sqrt{\frac{m}{k}}.The amplitude of the oscillations descreases with time exponentially as it would be shown by solving the differential equation above:
A(t)=A_{0} \exp({-\frac{b}{2m}t}).
Use tha fac that 4 periods mean a certain amount of time (4T=t) and the fact that A(4T)=3/4 A,plug it in the equation,simplify through A,take the logaritm,substitute t=4T and the value of m to find your answer.
Use the total energy formula (kinetic+potential)in which u plug the correct figures u have.The result should be pretty simple.The energy lost is just the difference between the one at the intial time and the one after 4T.BTW,your first calculation for the period of oscillation was correct.

Good luck!
 
Last edited:
Thanks!

Thanks,

You are awesome!:smile:
 
wannabeadoc05 said:
Thanks,

You are awesome!:smile:

Thank You! :blushing:
 

Thread 'Errors and significant figures'

I multiplied the values first without the error limit. Got 19.38. rounded it off to 2 significant figures since the given data has 2 significant figures. So = 19. For error I used the above formula. It comes out about 1.48. Now my question is. Should I write the answer as 19±1.5 (rounding 1.48 to 2 significant figures) OR should I write it as 19±1. So in short, should the error have same number of significant figures as the mean value or should it have the same number of decimal places as...
View full post »
Thread 'Calculation of Tensile Forces in Piston-Type Water-Lifting Devices at Elevated Locations'

Thread 'Calculation of Tensile Forces in Piston-Type Water-Lifting Devices at Elevated Locations'

Figure 1 Overall Structure Diagram Figure 2: Top view of the piston when it is cylindrical A circular opening is created at a height of 5 meters above the water surface. Inside this opening is a sleeve-type piston with a cross-sectional area of 1 square meter. The piston is pulled to the right at a constant speed. The pulling force is(Figure 2): F = ρshg = 1000 × 1 × 5 × 10 = 50,000 N. Figure 3: Modifying the structure to incorporate a fixed internal piston When I modify the piston...
View full post »
Thread 'A cylinder connected to a hanging mass'

Thread 'A cylinder connected to a hanging mass'

Let's declare that for the cylinder, mass = M = 10 kg Radius = R = 4 m For the wall and the floor, Friction coeff = ##\mu## = 0.5 For the hanging mass, mass = m = 11 kg First, we divide the force according to their respective plane (x and y thing, correct me if I'm wrong) and according to which, cylinder or the hanging mass, they're working on. Force on the hanging mass $$mg - T = ma$$ Force(Cylinder) on y $$N_f + f_w - Mg = 0$$ Force(Cylinder) on x $$T + f_f - N_w = Ma$$ There's also...
View full post »

Similar threads

Estimating damped harmonic oscillator parameters from this plot of the oscillations
Replies
9
Views
2K
Damped harmonic motion
Replies
3
Views
607
What is the value of b for a damped harmonic oscillator with given parameters?
Replies
2
Views
2K
Finding the damping force for a critically damped oscillator
Replies
2
Views
2K
Rotating simple harmonic oscillator
Replies
11
Views
1K
Damped harmonic oscillation of a swingboat
Replies
6
Views
1K
What is the meaning of the intercept of a particular solution to damped oscillator?
Replies
7
Views
876
Oscillation of free surface of water in parallelepiped container
Replies
13
Views
2K
Modeling the Driven Damped Oscillations in a Material
Replies
7
Views
2K
Acceleration amplitude of a damped harmonic oscillator
Replies
1
Views
2K

Hot Threads

Recent Insights

Back
Top