On a frictionless, horizontal air track, a glider oscillates at the end of an ideal spring of force constant 2.30 N/cm The graph in the figure (Figure 1) shows the acceleration of the glider as a function of time. Part A Find the mass of the glider. For related problemsolving tips and strategies, you may want to view a Video Tutor Solution of Angular frequency, frequency, and period in shm. Express your answer with the appropriate units. m= 5.83 kg Figure < 1 of 1> Part B Find the maximum displacement of the glider from the equilibrium point. Express your answer with the appropriate units. ar (m/s²) 12.0 HA ? 6.0 t (s) 0,10 0.20 0.30 0.40 A = 0.304 m -6.0 -12.0

On a frictionless, horizontal air track, a glider oscillates at the end of an ideal spring of force constant 2.30 N/cm The graph in the figure (Figure 1) shows the acceleration of the glider as a function of time. Part A Find the mass of the glider. For related problemsolving tips and strategies, you may want to view a Video Tutor Solution of Angular frequency, frequency, and period in shm. Express your answer with the appropriate units. m= 5.83 kg Figure < 1 of 1> Part B Find the maximum displacement of the glider from the equilibrium point. Express your answer with the appropriate units. ar (m/s²) 12.0 HA ? 6.0 t (s) 0,10 0.20 0.30 0.40 A = 0.304 m -6.0 -12.0

Name: On a frictionless, horizontal air track, a glider oscillates at theen
Uploaded: 2024-03-20T06:58:04.000Z
Channel: Bartleby
Description: On a frictionless, horizontal air track, a glider oscillates at theend of an ideal spring of force constant 2.30 N/cm. Thegraph in the figure (Figure 1) shows the acceleration of theglider as a function of time.Part AFind the mass of the glider.For

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter12: Oscillatory Motion

Section: Chapter Questions

Problem 48P

See similar textbooks

Similar questions

Some people modify cars to be much closer to the ground than when manufactured. Should they install stiffer springs? Explain your answer.
Can this analogy of SHM to circular motion be carried out with an object oscillating on a spring vertically hung from the ceiling? Why or why not? If given the choice, would you prefer to use a sine function or a cosine function to model the motion?
If a car has a suspension system with a force constant of 5.00104 N/m , how much energy must the car’s shocks remove to dampen an oscillation starting with a maximum displacement of 0.0750 m?
Refer to the problem of the two coupled oscillators discussed in Section 12.2. Show that the total energy of the system is constant. (Calculate the kinetic energy of each of the particles and the potential energy stored in each of the three springs, and sum the results.) Notice that the kinetic and potential energy terms that have 12 as a coefficient depend on C1 and 2 but not on C2 or 2. Why is such a result to be expected?
Give an example of a simple harmonic oscillator, specifically noting how its frequency is independent of amplitude.
Show that the time rate of change of mechanical energy for a damped, undriven oscillator is given by dE/dt = bv2 and hence is always negative. To do so, differentiate the expression for the mechanical energy of an oscillator, E=12mv2+12kx2, and use Equation 12.28.
A diver on a diving board is undergoing SHM. Her mass is 55.0 kg and the period of her motion is 0.800 s. The next diver is a male whose period of simple harmonic oscillation is 1.05 s. What is his mass if the mass of the board is negligible?
Suppose a diving board with no one on it bounces up and down in a SHM with a frequency of 4.00 Hz. The board has an effective mass of 10.0 kg. What is the frequency of the SHM of a 75.0-kg diver on the board?
Do you think there is any harmonic motion in the physical world that is not damped harmonic motion? Try to make a list of five examples of undamped harmonic motion and damped harmonic motion. Which list was easier to make?
Find the frequency of a tuning fork that takes 2.50103 s to complete one oscillation.
In an engine, a piston oscillates with simple harmonic motion so that its position varies according to the expression x=5.00cos(2t+6) where x is in centimeters and t is in seconds. At t = 0, find (a) the position of the piston, (b) its velocity, and (c) its acceleration. Find (d) the period and (e) the amplitude of the motion.
Check Your Understanding Identify one way you could decrease the maximum velocity of a simple harmonic oscillator.