a- Determine the value of the angular frequency of free oscillation with no damping. (w, = ??) b- Deduce the value of friction factor (g=??) c- Write the expression of position as a function of time of the system, if the system is critically damped. (x() = ??) d- Deduce the expression of the velocity of the system. (v(1) = ??)

a- Determine the value of the angular frequency of free oscillation with no damping. (w, = ??) b- Deduce the value of friction factor (g=??) c- Write the expression of position as a function of time of the system, if the system is critically damped. (x() = ??) d- Deduce the expression of the velocity of the system. (v(1) = ??)

Name: Problem2:An automobile suspension system is critically damped, and it
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Description: Problem2:An automobile suspension system is critically damped, and its period of free oscillation with nodamping is 1 s. If the system is initially displaced by an amount and released with zero initialvelocity (at 1 = 0; x(0) =xq and v(0) = 0)a- Det

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter16: Oscillations

Section: Chapter Questions

Problem 74PQ: The total energy of a simple harmonic oscillator with amplitude 3.00 cm is 0.500 J. a. What is the...

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The equations listed in Table 2.2 give position as a function of time, velocity as a function of time, and velocity as a function of position for an object moving in a straight line with constant acceleration. The quantity vxi appears in every equation. (a) Do any of these equations apply to an object moving in a straight line with simple harmonic motion? (b) Using a similar format, make a table of equations describing simple harmonic motion. Include equations giving acceleration as a function of time and acceleration as a function of position. State the equations in such a form that they apply equally to a blockspring system, to a pendulum, and to other vibrating systems. (c) What quantity appears in every equation?
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A simple harmonic oscillator has amplitude A and period T. Find the minimum time required for its position to change from x = A to x = A/2 in terms of the period T.
In an engine, a piston oscillates with simpler 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 = O. find (a) the position of the particle, (b) its velocity, and (c) its acceleration. Find (d) the period and (e) the amplitude of the motion.
The mechanical energy of an undamped block-spring system is constant as kinetic energy transforms to elastic potential energy and vice versa. For comparison, explain what happens to the energy of a damped oscillator in terms of the mechanical, potential, and kinetic energies.
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The total energy of a simple harmonic oscillator with amplitude 3.00 cm is 0.500 J. a. What is the kinetic energy of the system when the position of the oscillator is 0.750 cm? b. What is the potential energy of the system at this position? c. What is the position for which the potential energy of the system is equal to its kinetic energy? d. For a simple harmonic oscillator, what, if any, are the positions for which the kinetic energy of the system exceeds the maximum potential energy of the system? Explain your answer. FIGURE P16.73