A spring-mass-dashpot system has a mass of 1 kg and its damping constant is 0.2 N−Sec...

A 5​-kg mass is attached to a spring with stiffness 225 N/m. The damping constant for...

A 5​-kg mass is attached to a spring with stiffness 225 N/m. The damping constant for the system is 30√5 N-sec/m. If the mass is pulled 20 cm to the right of equilibrium and given an initial rightward velocity of 3 ​m/sec, what is the maximum displacement from equilibrium that it will​ attain? ​(Type an exact​ answer, using radicals as​ needed.)

A 4 kg mass is attached to a spring with stiffness 48 N/m. The damping constant...

A 4 kg mass is attached to a spring with stiffness 48 N/m. The damping constant for the spring is 16\sqrt{3} N - sec/m. If the mas is pulled 30 cm to the right of equilibrium and given an initial rightward velocity of 3 m/sec, what is the maximum displacement from equilibrium that it will attain?

A 4kg mass is attached to a spring with stiffness 80 N/m. The damping constant for...

A 4kg mass is attached to a spring with stiffness 80 N/m. The damping constant for the system is 16sqrt(5) N-sec/m. If the mass is pulled 10 cm to the right of equilibrium and given an initial rightward velocity of 4 m/sec, what is the maximum displacement from equilibrium that is will attain? The maximum displacement is [ ] meters. Type an exact answer, using radicals as needed

A 1/4​-kg mass is attached to a spring with stiffness 52 N/m. The damping constant for...

A 1/4​-kg mass is attached to a spring with stiffness 52 N/m. The damping constant for the system is 6 ​N-sec/m. If the mass is moved 3/4 m to the left of equilibrium and given an initial rightward velocity of 1 ​m/sec, determine the equation of motion of the mass y(t) = and give its damping​ factor, quasiperiod, and quasifrequency.

A 1/2 kg mass is attached to a spring with 20 N/m. The damping constant for...

A 1/2 kg mass is attached to a spring with 20 N/m. The damping constant for the system is 6 N-sec/m. If the mass is moved 12/5 m to the left of equilibrium and given an initial rightward velocity of 62/5 m/sec, determine the equation of motion of the mass and give its damping factor, quasiperiod, and quasifrequency. What is the equation of motion? y(t)= The damping factor is: The quasiperiod is: The quasifrequency is:

A spring has a mass of 1 kg and its damping constant is c = 10....

A spring has a mass of 1 kg and its damping constant is c = 10. The spring starts from its equilibrium position with a velocity of 1 m/s. Graph the position function for the following values of the spring constant k: 10, 20, 25, 30, 40. What type of damping occurs in each case

A 1-kg mass is attached to a spring whose constant is 16 N/m and the entire...

A 1-kg mass is attached to a spring whose constant is 16 N/m and the entire system is then submerged in a liquid that imparts a damping force numerically equal to 10 times the instantaneous velocity. Determine the equation if (A) The weight is released 60 cm below the equilibrium position. x(t)= ; (B) The weight is released 60 cm below the equilibrium position with an upward velocity of 17 m/s. x(t)= ; Using the equation from part b, (C)...

A spring with spring constant 4 N/m is attached to a 1kg mass and a dashpot...

A spring with spring constant 4 N/m is attached to a 1kg mass and a dashpot with damping constant 4 Ns/m.A periodic force equal to 2 cos(t) N is applied to this system. Assume that the system starts withx(0) = 1 andx′(0) = 2,

A small object of mass 1 kg is attached to a spring with spring constant 2...

A small object of mass 1 kg is attached to a spring with spring constant 2 N/m. This spring mass system is immersed in a viscous medium with damping constant 3 N· s/m. At time t = 0, the mass is lowered 1/2 m below its equilibrium position, and released. Show that the mass will creep back to its equilibrium position as t approaches infinity.

A mass of 3 kg stretches a spring 61.25 cm. Supposing that there is no damping...

A mass of 3 kg stretches a spring 61.25 cm. Supposing that there is no damping and that the mass is set in motion from 0.5 m above its equilibrium position with a downward velocity of 2 m/s, determine the position of the mass at any time. Find the amplitude, the frequency, the period and the phase shift of the motion.