A 4 kg object is attached to a spring and will stretch the spring 9.8 cm by itself. A forcing function of the form F(t) = 13 cos (wt) is attached to the object and the system experiences resonance. The object is initially displaced 6.5 cm downward from its equilibrium position and given a velocity of 13 cm/sec upward. Assume there is no damping in the system and displacement and velocity are positive downward. Use g = 9.8 m/s². Keep the coefficients in your answer exact or round them off to at least five decimal places. a) What is the differential equation of the motion. y' + = = b) Solve the differential equation to find the displacement as a function of time (t). y(t) =

Advanced Engineering Mathematics
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ISBN:9780470458365
Author:Erwin Kreyszig
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Chapter2: Second-order Linear Odes
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A 4 kg object is attached to a spring and will stretch the spring 9.8 cm by itself. A
forcing function of the form F(t) = 13 cos (wt) is attached to the object and the
system experiences resonance. The object is initially displaced 6.5 cm downward from
its equilibrium position and given a velocity of 13 cm/sec upward. Assume there is no
damping in the system and displacement and velocity are positive downward. Use
g = 9.8 m/s². Keep the coefficients in your answer exact or round them off to at least
five decimal places.
a) What is the differential equation of the motion.
y'' +
=
y' +
Y
-
b) Solve the differential equation to find the displacement as a function of time (t).
y(t) =
Transcribed Image Text:A 4 kg object is attached to a spring and will stretch the spring 9.8 cm by itself. A forcing function of the form F(t) = 13 cos (wt) is attached to the object and the system experiences resonance. The object is initially displaced 6.5 cm downward from its equilibrium position and given a velocity of 13 cm/sec upward. Assume there is no damping in the system and displacement and velocity are positive downward. Use g = 9.8 m/s². Keep the coefficients in your answer exact or round them off to at least five decimal places. a) What is the differential equation of the motion. y'' + = y' + Y - b) Solve the differential equation to find the displacement as a function of time (t). y(t) =
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