A forced oscillator is driven at a frequency of 30 Hz with a peak force of...
A damped oscillator with natural frequency wo and damping K is driven by a period square wave force with amplitude A such that F(t)= A Find the Fourier series for F(t), and solve for the amplitude of the motion of the oscillator. For which frequency wn is the resonance condition the most closely satisfied? Plot the maximum amplitude (in units of A) as a function of wn for the conditions with the spring constant k 1, m 2, K 0.1,...
ineers can determine properties of a structure that is modeled as damped spring oscillator-such as a bridge-by applying a driving force to it. A weakly damped spring oscillator of mass 0.242 kg is driven by a sinusoidal force at the oscillator's resonance frequency of 34.0 Hz. Find the value of the spring constant Number N/ m The amplitude of the driving force is 0.471 N and the amplitude of the oscillator's steady-state motion in response to this driving force is...
Problem 5: A block weighing 40.0 N is suspended from a spring that has a force constant of 200 N/m. The system is undamped (b 0) and is subjected to a harmonic driving force of frequency 10.0 Hz, resulting in a forced-motion amplitude of 2.00 cm. (a) Determine the maximum value of the driving force. The same system of block and spring are now moving in a fluid with damping coefficient b25 kg/s. The system is driven by an external...
A driving force of the form F(t) = (0.212 N) sin (2xft) acts on a weakly damped spring oscillator with mass 6.98 kg, spring constant 362 N/m, and damping constant 0.261 kg/s. What frequency fo of the driving force will maximize the response of the oscillator? fo = Hz Find the amplitude Ao of the oscillator's steady-state motion when the driving force has this frequency Find the amplitude Ap of the oscillator's steady-state motion when the driving force has this...
3.4. A harmonic oscillator with mass m, natural angular frequency wo, and damping constant r is driven by an external force FCt) Fo cos(wot)N. W show that xp A sin(wot) is a solution if A Fo/rwo. rite the equation of motion and use it to
help with 1-3 1) A simple harmonic oscillator consists of a 0.100 kg mass attached to a spring whose force constant is 10.0 N/m. The mass is displaced 3.00 cm and released from rest. Calculate (a) the natural frequency fo and period T (b) the total energy , and (c) the maximum speed 2) Allow the motion in problem 1 to take place in a resisting medium. After oscillating for 10 seconds, the maximum amplitude decreases to half the initial...
QUESTION 6 130 MARKS For a vibrating system, the body mass is 10 kg, stiffness is 2.5 kN/m, and damping constant is 45 Ns/m. A harmonic force of amplitude 180 N and frequency 3.5 Hz acts on the mass. If the initial displacement and velocity of the mass are 15 mm and 5 m/s, compute the complete solution representing the motion of the mass. 45 (30 Marks) QUESTION 6 130 MARKS For a vibrating system, the body mass is 10...
Please don't answer if you are unsure or inexperienced! People are paying their hard-earned money for this service! Engineers can determine properties of a structure that is modeled as a damped spring oscillator, such as a bridge, by applying a driving force to it. A weakly damped spring oscillator of mass 0.225 kg is driven by a sinusoidal force at the oscillator's resonance frequency of 28.0 Hz. Find the value of the spring constant. spring constant: N/m The amplitude of...
A driving force of the form F(t) = (0.215 N) sin (2 ft) acts on a weakly damped spring oscillator with mass 6.86 kg, spring constant 322 N/m, and damping constant 0.217 kg/s. What frequency of the driving force will maximize the response of the oscillator? frequency: Find the amplitude of the oscillator's steady-state motion when the driving force has this frequency amplitude:
A harmonic oscillator with mass m , natural angular frequency ω0 , and damping constant r is driven by an external force F(t) = F0cos(ωt). Show that if ω = ω0, then the instantaneous power supplied by the driving force is exactly absorbed by the damping force.