What is the equation of motion here? Hint: The general form of solution is:physicsgurl123 said:A weight of mass m = 300 g hangs vertically from a spring that has a spring constant k = 1.50 N/m. The mass is set into vertical oscillation and after 28 s you find that the amplitude of the oscillation is 1/10 that of the initial amplitude. What is the damping constant b associated with the motion (in kg/s)? Also what would the graphs of the mechanical and kinetic energies look like?
A damped oscillation is a type of motion where an object (in this case, a mass of 300 g) oscillates back and forth due to a restoring force (in this case, a spring with a stiffness of 1.50 N/m) but is also subject to a damping force (in this case, a damping coefficient of b in kg/s). This results in the amplitude of the oscillations decreasing over time until the object reaches a state of equilibrium.
The damping coefficient (b) directly affects the rate of decay of the oscillations. The larger the value of b, the faster the oscillations will decay. This is because a higher damping coefficient means there is more resistance to the motion of the object, resulting in a quicker loss of energy and a shorter period of oscillation.
The formula for calculating the period of a damped oscillation is T = 2π/ω, where T is the period and ω is the angular frequency. The angular frequency is calculated by taking the square root of the stiffness (k) divided by the mass (m) minus half of the damping coefficient (b/2m).
Changing the mass will affect the damped oscillations in a few ways. Firstly, a larger mass will result in a longer period of oscillation. Secondly, a larger mass will also result in a lower angular frequency, meaning the oscillations will occur at a slower rate. Finally, a larger mass will also result in a slower rate of decay of the oscillations.
No, a damped oscillation system will never reach a state of permanent oscillation. This is because the damping force will always act to decrease the amplitude of the oscillations, eventually bringing the object to a state of equilibrium where there is no more oscillation. However, the time it takes to reach this state of equilibrium will vary depending on the values of the mass, stiffness, and damping coefficient.