the following questions, please refer to the graph of the position of a simple harmonic oscillator...
A simple harmonic oscillator at the position x=0 generates a
wave on a string. The oscillator moves up and down at a frequency
of 40.0 Hz and with an amplitude of 3.00 cm. At time t =
0, the oscillator is passing through the origin and moving down.
The string has a linear mass density of 50.0 g/m and is stretched
with a tension of 5.00 N.
A simple harmonic oscillator at the position x = 0 generates a wave...
In Capstone, you might acquire position vs. time data for your simple harmonic oscillator that look like the example below. How could you measure the period of oscillation directly from the sinusoidal graph? A sine function has also been fit to these data, with parameters in the white box. In particular, the angular frequency of the fit function is omega = 5.19 rad/s. Compare the period you measured graphically to the period you would get from the omega value. If...
This scenario is for questions 1-2. A simple harmonic oscillator at the position x = 0 generates a wave on a string. The oscillator moves up and down at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. At time t = 0, the oscillator is passing through the origin and moving down. The string has a linear mass density of 50.0 g/m and is stretched with a tension of 5.00 N. a) Find the angular frequency...
A simple harmonic oscillator of mass 0.400 kg oscillates with frequency 1.50 Hz. At t0, the oscillator is at position x 4.00 cm and is moving right with speed 42.0 cm/s a) Find the amplitude and phase constant for the oscillator. b) Write the equation for displacement of the oscillator (with numbers) c) Find the position, velocity, and acceleration at t 3.00 s. di Find the first tw o times the oscillation has position x -2 .75 cm.
can you help with a-f please
This scenario is for questions 1-2 A simple harmonic oscillator at the position x-Ogenerates a wave on a string. The oscillator moves up and down at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. At time t = 0, the oscillator is passing through the origin and moving down. The string has a linear mass density of 50,0 g/m and is stretched with a tension of 5.00 N. a) Find...
A simple harmonic oscillator at the position x = 0
generates a wave on a string. The oscillator moves up and down at a
frequency of 40.0 Hz and with an amplitude of 3.00 cm. At time
t = 0, the oscillator is passing through the origin and
moving down. The string has a linear mass density of 50.0 g/m and
is stretched with a tension of 5.00 N.
Question 2 9 pts Consider the piece of string at x...
1. The solution for a SHO (simple harmonic oscillator) is given as: x(t) = 0.1 sin(3t − π/6) meters. Include appropriate units in your answers. (a) What is the amplitude of oscillation? (b) What is the initial position of the oscillator? (c) What is the maximum velocity of the oscillator and at what value of x does it occur? (d) What is the maximum acceleration of the oscillator and where does it occur? (e) What are the period and frequency...
A simple harmonic oscillator consists of a block attached to a spring, moving back and forth on a frictionless horizontal surface. Suppose the mass of the box is 5.0 kg. The motion is started by holding the box at .50m from its central position, using a force of 40.0 N. Then the box is let go and allowed to perform simple harmonic motion. What is the amplitude of the motion? What is the spring constant k? What is the maximum...
5) A damped simple harmonic oscillator consists of a.40 kg mass oscillating vertically on a spring with k- 15 N/m with a damping coefficient of .20 kg/s. The spring is initially stretched 17 cm downwards and the mass is released from rest. a) What is the angular frequency of the mass? b) What is the position of the mass at t-3 seconds? c) Sketch a position vs time graph for the mass, showing at least 5 full cycles of oscillation....
A simple harmonic oscillator consists of a block of mass 2.00 kg attached to a spring of spring constant 100 N/m. When t = 1.00 s, the position and velocity of the block are x = 0.129 m and v = 3.415 m/s respectively. a) What is the amplitude of oscillations? b) What were the position and velocity of the mass at time t = 0?