A damped mass-spring oscillator loses 6% of its energy during each cycle. a.) The period is...

A damped mass-spring oscillator loses 2% of its energy during each cycle. (a) The period is...

A damped mass-spring oscillator loses 2% of its energy during each cycle. (a) The period is 3.0 s, and the mass is 0.50 kg. What is the value of the damping constant? (b) If the motion is started with an initial amplitude of 0.92 m, how many cycles elapse before the amplitude reduces to 0.75 m? (c) Would it take the same number of cycles to reduce the amplitude from 0.75 m to 0.50 m? No calculations are needed for...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A student measures an amplitude of 0.923 m and a duration of 129 s for 65 cycles of oscillation. Find the frequency, ?, the speed at the equilibrium position, ?max, the spring constant, ?, the potential energy at an endpoint, ?max, the potential energy when the particle is located 68.5% of the amplitude away from the equiliibrium position, ?, and the kinetic energy, ?, and...

A horizontal mass spring oscillator is constructed, where the mass of the oscillator is 3 kg,...

A horizontal mass spring oscillator is constructed, where the mass of the oscillator is 3 kg, the spring constant is 3 kg/s, and the friction parameter of the medium b kg/s. Denote the displacement of the oscillator from the equilibrium position by y(t). Find the equation _______=0 The spring is critically damped when b=___ When b=0, the frequency of the oscillation will be ___s^-1. When b=3, the frequency of oscillation will be ____s^-1.

Question 1:A driven and damped mass-spring oscillator has ?= 14.0 g and ?= 1.80 N/m and...

Question 1:A driven and damped mass-spring oscillator has ?= 14.0 g and ?= 1.80 N/m and ?=0.00200 kg/s. The driving frequency is Ω=11.4 rad/s and the driving acceleration is ?=3.33 cm/s2. What is the resulting oscillation amplitude? A.1.56 cm , B.3.32 cm , C.8.20 cm , D.12.7 cm , E.17.7 cm Question 2: A driven and damped mass-spring oscillator has ?= 14.0 g and ?= 1.80 N/m and ?=0.00200 kg/s. The driving frequency is Ω=11.4 rad/s and the driving acceleration...

11.2 A mass oscillates on a spring of force constant 25.0 N/m and is subjected to...

11.2 A mass oscillates on a spring of force constant 25.0 N/m and is subjected to a damping force Fx = ?bvx , where b = 2.40 kg/s. (a) What special value of the mass m determines whether the mass undergoes underdamped oscillations, is critically damped, or is overdamped? (b) If m is eight times this special value, how long does it take for the amplitude to be reduced by 50%? What is the period of the oscillation? Plot the...

A block of mass 2.5 kg is connected to a spring with k=1250 N/m. (a) At...

A block of mass 2.5 kg is connected to a spring with k=1250 N/m. (a) At t = 0 the block is released from rest at x(t = 0) = 28 mm from equilibrium. The motion is linearly damped with b = 50 kg/s. Find the amplitude A and phase angle ?. (Note that the amplitude is not obviously the displacement at t = 0 as it would be for the undamped case!) (b) Now consider a driving force with...

A 10.5-kg object oscillates at the end of a vertical spring that has a spring constant...

A 10.5-kg object oscillates at the end of a vertical spring that has a spring constant of 1.70 ? 104 N/m. The effect of air resistance is represented by the damping coefficient b = 3.00 N · s/m. (a) Calculate the frequency of the damped oscillation. Hz (b) By what percentage does the amplitude of the oscillation decrease in each cycle? % (c) Find the time interval that elapses while the energy of the system drops to 4.00% of its...

A simple harmonic oscillator consists of a block of mass 3.70 kg attached to a spring...

A simple harmonic oscillator consists of a block of mass 3.70 kg attached to a spring of spring constant 410 N/m. When t = 1.60 s, the position and velocity of the block are x = 0.102 m and v = 3.050 m/s. (a) What is the amplitude of the oscillations? What were the (b) position and (c) velocity of the block at t = 0 s?

A simple harmonic oscillator consists of a block of mass 3.00 kg attached to a spring...

A simple harmonic oscillator consists of a block of mass 3.00 kg attached to a spring of spring constant 110 N/m. When t = 2.30 s, the position and velocity of the block are x = 0.127 m and v = 3.580 m/s. (a) What is the amplitude of the oscillations? What were the (b) position and (c) velocity of the block at t = 0 s?

A simple harmonic oscillator consists of a block of mass 2.90 kg attached to a spring...

A simple harmonic oscillator consists of a block of mass 2.90 kg attached to a spring of spring constant 280 N/m. When t = 2.20 s, the position and velocity of the block are x = 0.189 m and v = 3.000 m/s. (a) What is the amplitude of the oscillations? What were the (b) position and (c) velocity of the block at t = 0 s?