Not every interpretation of direction is that "positive is down". In this problem, assume that if initial position is above equilibrium, then it is positive, and if it is below equilibrium it is negative. This assumption will have implications on the initial velocity as well. A 8 kilogram mass is attached to a spring whose constant is 52.02 N/m, and the entire system is submerged in a liquid that imparts a damping force numerically equal to 41.12 times the instantaneous velocity. Determine the equation of motion f the mass is initially released from rest from 14 meters above equilibrium. #(t)

Not every interpretation of direction is that "positive is down". In this problem, assume that if initial position is above equilibrium, then it is positive, and if it is below equilibrium it is negative. This assumption will have implications on the initial velocity as well. A 8 kilogram mass is attached to a spring whose constant is 52.02 N/m, and the entire system is submerged in a liquid that imparts a damping force numerically equal to 41.12 times the instantaneous velocity. Determine the equation of motion f the mass is initially released from rest from 14 meters above equilibrium. #(t)

Name: Explanation it correctly Not every interpretation of direction is that
Uploaded: 2024-03-20T06:58:04.000Z
Channel: Bartleby
Description: Explanation it correctly Not every interpretation of direction is that "positive is down". In this problem, assume that if initialposition is above equilibrium, then it is positive, and if it is below equilibrium it is negative. Thisassumption will h

Classical Dynamics of Particles and Systems

5th Edition

ISBN:9780534408961

Author:Stephen T. Thornton, Jerry B. Marion

Publisher:Stephen T. Thornton, Jerry B. Marion

Chapter3: Oscillations

Section: Chapter Questions

Problem 3.2P: Allow the motion in the preceding problem to take place in a resisting medium. After oscillating for...

See similar textbooks

Similar questions

Plot a velocity resonance curve for a driven, damped oscillator with Q = 6, and show that the full width of the curve between the points corresponding to is approximately equal to ω0/6.
Suppose you have a 0.750-kg object on a horizontal surface connected to a spring that has a force constant of 150 N/m. There is simple friction between the object and surface with a static coefficient of friction s=0.100 . (a) How far can the spring be stretched without moving the mass? (b) If the object is set into oscillation with an amplitude twice the distance found in part (a), and the kinetic coefficient of friction is k=0.0850 , what total distance does it travel before stopping? Assume it starts at the maximum amplitude.
Allow the motion in the preceding problem to take place in a resisting medium. After oscillating for 10 s, the maximum amplitude decreases to half the initial value. Calculate (a) the damping parameter β, (b) the frequency υ1 (compare with the undamped frequency υ0), and (c) the decrement of the motion.
C, N A uniform plank of length L and mass M is balanced on a fixed, semicircular bowl of radius R (Fig. P16.19). If the plank is tilted slightly from its equilibrium position and released, will it execute simple harmonic motion? If so, obtain the period of its oscillation.
Consider the system shown in Figure P16.68 as viewed from above. A block of mass m rests on a frictionless, horizontal surface and is attached to two elastic cords, each of length L. At the equilibrium configuration, shown by the dashed line, the cords both have tension FT. The mass is displaced a small amount as shown in the figure and released. Show that the net force on the mass is similar to the spring-restoring force and find the angular frequency of oscillation, assuming the mass behaves as a simple harmonic oscillator. You can assume the displacement is small enough to produce negligible change in the tension and length of the cords. FIGURE P16.68
Prove that the expression for quality factor of a damped harmonic oscillator is given by Q= ωd/2y
A mass of 1 slug is attached to a spring whose constant is 25 > 4lb > ft. Initially the mass is released 1 ft above the equilibrium positionwith a downward velocity of 3 ft > sec, and the subsequentmotion takes place in a medium that oers a damping force numericallyequal to 3 times the instantaneous velocity. An externalforce ƒ(t) is driving the system, but assume that initially ƒ(t) K 0.
A 1-kilogram mass is attached to a spring whose constant is 27 N/m, and the entire system is then submerged in a liquid that imparts a damping force numerically equal to 12 times the instantaneous velocity. Determine the equations of motion if the following is true. (a) the mass is initially released from rest from a point 1 meter below the equilibrium position x(t)=_________________________________________m (b) the mass is initially released from a point 1 meter below the equilibrium position with an upward velocity of 11 m/s x(t)=___________________________________________m
A 1-kilogram mass is attached to a spring whose constant is 18 N/m, and the entire system is then submerged in a liquid that imparts a damping force numerically equal to 11 times the instantaneous velocity. Determine the equations of motion if the following is true. (a) the mass is initially released from rest from a point 1 meter below the equilibrium position x(t) = m (b) the mass is initially released from a point 1 meter below the equilibrium position with an upward velocity of 11 m/s x(t) = m
An unhappy 0.400 kg rodent, moving on the end of a spring with force constant 5.50 N/m, is acted on by a damping force Fx=−bv. If the constant bb has the value 0.900 kg/s, what is the frequency of oscillation of the rodent? Express your answer with the appropriate units. For what value of the constant bb will the motion be critically damped? Express your answer in kilogram per second.
A spring is stretched 6 inches by a 12 pound weight. If the weight attached to the spring is pulled down 4 inches below the equilibrium point and is released with an upward velocity of 2 ft/sec while immersed in a liquid that offers a damping force of 0.6 of the instantaneous velocity, find the equation of the motion.
Please explain why beta = 3omega is an example of a critically damping motion for a damped harmonic oscillator?