)   If you triple the amplitude of a simple harmonic oscillator how does this          change...

Q1: Select all true statements. The KE of a simple harmonic oscillator is maximum at the...

Q1: Select all true statements. The KE of a simple harmonic oscillator is maximum at the maximum absolute displacements. The frequency of a simple harmonic oscillator is independent of its amplitude. A harmonic oscillator, the motion of which is reduced and brought to rest over time by friction, is an example of a damped harmonic oscillator. The period of an object moving in simple harmonic motion is the number of cycles that occur per second. Young’s Modulus depends on the...

If I have a simple harmonic oscillator with an amplitude 4.2cm and has a total energy...

If I have a simple harmonic oscillator with an amplitude 4.2cm and has a total energy of 0.400J What would be the max speed of the the mass if the mass hanging on the oscillator is 3kg, and what is it's period of oscillation. Also, what is the kinetic energy of the entire system when the position of the oscillator is 0.850 cm from the center?

A simple harmonic oscillator consists of a mass of 100g attached to a constant spring is...

A simple harmonic oscillator consists of a mass of 100g attached to a constant spring is 10^4 dynas/cm. At time t=0, the mass is about 3 cm from the equilibrium point and with an initial velocity of 5cm/s, both in the positive direction.A dissipative force is now added. Assume that you start moving from rest at the maximum amplitude position, and after oscillating for 10 s, your maximum amplitude is reduced to half of the initial value. Calculate: A- dissipation...

A simple harmonic oscillator is made from a mass on a spring. If you start the...

A simple harmonic oscillator is made from a mass on a spring. If you start the mass oscillating by pulling the mass downward by a distance A and releasing it from rest, let us assume the maximum velocity it achieves during its oscillation is v. What would the maximum velocity be if you instead pulled the mass down by 2A then released it from rest?

Consider a simple harmonic oscillator made of a mass sliding on a frictionless surface, and attached...

Consider a simple harmonic oscillator made of a mass sliding on a frictionless surface, and attached to a massless linear spring. Which of the following statements are true? (If A and E are, and the others are not, enter TFFFT).      A) Doubling the mass will not change the period.      B) Doubling the amplitude will halve the frequency.      C) Quadrupling the spring constant will double the frequency.      D) Doubling the mass will double the frequency.      E)...

How would you solve the rate of energy dissipation of a damped simple harmonic oscillator?

How would you solve the rate of energy dissipation of a damped simple harmonic oscillator?

In Classical Physics, the typical simple harmonic oscillator is a mass attached to a spring. The...

In Classical Physics, the typical simple harmonic oscillator is a mass attached to a spring. The natural frequency of vibration (radians per second) for a simple harmonic oscillator is given by ω=√k/m and it can vibrate with ANY possible energy whatsoever. Consider a mass of 135 grams attached to a spring with a spring constant of k = 1 N/m. What is the Natural Frequency (in rad/s) of vibration for this oscillator? In Quantum Mechanics, the energy levels of a...

A simple harmonic oscillator consists of a block of mass 3.10 kg attached to a spring...

A simple harmonic oscillator consists of a block of mass 3.10 kg attached to a spring of spring constant 240 N/m. When t = 1.80 s, the position and velocity of the block are x = 0.155 m and v = 4.360 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? (really need help with part c for part a i got .52 and...

A simple harmonic oscillator has a mass of 1.4 kg, a maximum speed of 0.55 m/s,...

A simple harmonic oscillator has a mass of 1.4 kg, a maximum speed of 0.55 m/s, and a spring constant of 20.5 N/m. Use Conservation of Energy to find the amplitude of the system. Assume that there are no frictional losses.

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?