A mass m = 2.5 kg is connected to a spring. The mass is pulled back a distance Ax = 0.20 m to the right (positive%3Ddirection) and the mass vibrates back and forth (1 complete motion) once every 6.0 seconds.a) What is the stiffness (k) of the spring?N/mb) What is the frequency of the vibration?Hzc) How much force was needed to pull back the mass before being released?Nd) How far would the mass shift from the equilibrium position if 1.2 N of force was used to pull it?e) Complete the following table.Position (m)PE (J)KE (J)ME (J)Speed (m/s)Accel. (m/s²)Ax = -0.20Ax = 0.0Ax = +0.20f) How long would a pendulum have to be to have the same period?g) The spring and mass are brought along with a grandfather clock on the first human voyage to Mars. Whatwould the period of mass and spring be on Mars where gravitational acceleration g = 3.6 m/s? ?S

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Description: A mass m = 2.5 kg is connected to a spring. The mass is pulled back a distance Ax = 0.20 m to the right (positive%3Ddirection) and the mass vibrates back and forth (1 complete motion) once every 6.0 seconds.a) What is the stiffness (k) of the spring

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A mass m = 2.5 kg is connected to a spring. The mass is pulled back a distance Ax = 0.20 m to the right (positive direction) and the mass vibrates back and forth (1 complete motion) once every 6.0 seconds. a) What is the stiffness (k) of the spring? N/m b) What is the frequency of the vibration? Hz c) How much force was needed to pull back the mass before being released?

A mass m = 2.5 kg is connected to a spring. The mass is pulled back a distance Ax = 0.20 m to the right (positive direction) and the mass vibrates back and forth (1 complete motion) once every 6.0 seconds. a) What is the stiffness (k) of the spring? N/m b) What is the frequency of the vibration? Hz c) How much force was needed to pull back the mass before being released?

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter13: Vibrations And Waves

Section: Chapter Questions

Problem 27P: The position of an object connected to a spring varies with time according to the expression x =...

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