Mass m=1 is attached to a spring with constant k = 4 and dashpot constant c=2....

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 body of mass equal to 4 kg is attached to a spring of constant k...

A body of mass equal to 4 kg is attached to a spring of constant k = 64 N / m. If an external force F (t) = 3/2 cos 4t is applied to the system, determine the position and speed of the body at all times; suppose that the mass was in position x (0) = 0.3 m and, at rest, at time t = 0 s

Consider an undamped spring with spring constant k = 9N/m and with a mass attached with...

Consider an undamped spring with spring constant k = 9N/m and with a mass attached with mass 4kg. We apply a driving force of F(t) = sin(3t/2). Solve the IVP for the position of the mass x(t) with the string initially at rest at the equilibrium (so x(0) = 0 and ˙x(0) = 0). (Hint: Guess a particular solution of the form Ct cos(3t/2) and find the constant C.)

A mass m is attached to a spring with stiffness k=25 N/m. The mass is stretched...

A mass m is attached to a spring with stiffness k=25 N/m. The mass is stretched 1 m to the left of the equilibrium point then released with initial velocity 0. Assume that m = 3 kg, the damping force is negligible, and there is no external force. Find the position of the mass at any time along with the frequency, amplitude, and phase angle of the motion. Suppose that the spring is immersed in a fluid with damping constant...

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.

3. Consider a mass m attached to a horizontal spring with spring constant k.  Suppose the mass...

3. Consider a mass m attached to a horizontal spring with spring constant k.  Suppose the mass is pulled a distance A from the equilibrium position.   a. Find the total energy at the amplitude in terms of k and A b. Using conservation of energy, find an expression for the maximum speed at the equilibrium position in terms of k, A and m

A 1-kilogram mass is attached to a spring whose constant is 18 N/m, and the entire...

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...

When a mass of 4 kilograms is attached to a spring whose constant is 64 N/m,...

When a mass of 4 kilograms is attached to a spring whose constant is 64 N/m, it comes to rest in the equilibrium position. Starting at t = 0, a force equal to f(t) = 80e−4t cos 4t is applied to the system. Find the equation of motion in the absence of damping.

A mass of 4 Kg attached to a spring whose constant is 20 N / m...

A mass of 4 Kg attached to a spring whose constant is 20 N / m is in equilibrium position. From t = 0 an external force, f (t) = et sin t, is applied to the system. Find the equation of motion if the mass moves in a medium that offers a resistance numerically equal to 8 times the instantaneous velocity. Draw the graph of the equation of movement in the interval.

A 1 kg mass is on a horizontal frictionless surface and is attached to a horizontal...

A 1 kg mass is on a horizontal frictionless surface and is attached to a horizontal spring with a spring constant of 144 N/m. The spring's unstretched length is 20 cm. You pull on the mass and stretch the spring 5 cm and release it. The period of its oscillations is T=.524s The amplitude of the block's oscillatory motion is 5cm The maximum velocity of the oscillating mass is 60cm/s Part E) While the frictionless surface is working well, the...