Consider a mass and spring system with a mass m = 1 kg, spring constant k...

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.)

Consider a system with a vibrating base. The spring constant is given as K = 10.kN/m...

Consider a system with a vibrating base. The spring constant is given as K = 10.kN/m and the mass is also given as M = 200.Kg. If the amplitude of the base is 0.5mm, then what should the damping constant c be for the amplitude of the transmitted force to be equal to 2500.N at resonance.

Assume an object with mass m=1 kg is attached to a spring with stiffness k=2 N/m...

Assume an object with mass m=1 kg is attached to a spring with stiffness k=2 N/m and lies on a surface with damping constant b= 2 kg/s. The object is subject to the external force F(t) = 4cos(t) + 2sin(t). Suppose the object starts at the equilibrium position (y(0)=0) with an initial velocity of y_1 (y'(0) = y_1). In general, when the forcing function F(t) = F*cos(γ*t) + G*sin(γ*t) where γ>0, the solution is the sum of a periodic function...

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 spring-mass system has a spring constant of 3 N/m. A mass of 2 kg is...

A spring-mass system has a spring constant of 3 N/m. A mass of 2 kg is attached to the spring, and the motion takes place in a viscous fluid that offers a resistance numerically equal to the magnitude of the instantaneous velocity. (a) If the system is driven by an external force of (12 cos 3t − 8 sin 3t) N, determine the steady-state response. (b) Find the gain function if the external force is f(t) = cos(ωt). (c) Verify...

8. A 0.40-kg mass is attached to a spring with a force constant of k =...

8. A 0.40-kg mass is attached to a spring with a force constant of k = 387 N/m, and the mass–spring system is set into oscillation with an amplitude of A = 3.7 cm. Determine the following. (a) mechanical energy of the system J (b) maximum speed of the oscillating mass m/s (c) magnitude of the maximum acceleration of the oscillating mass m/s2

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:

1. A mass 0.15 kg is attached to a horizontal spring with spring constant k =...

1. A mass 0.15 kg is attached to a horizontal spring with spring constant k = 100 N/m moves on a horizontal surface. At the initial moment in time, the mass is moving to the right at rate of 3.5 m/s and displacement of 0.2 m to the right of equilibrium. a) What is the angular frequency, period of oscillation, and phase constant? b) What is the amplitude of oscillation (Hint: Use energy.) and maximum speed of the spring-mass system?

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

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