Consider the initial value problem my" + cy' + ky = F(t), y(0) = 0, y'(0)=0 modeling the motion of a spring-mass-dashpot system initially at rest and subjected to an applied force F(t), where the unit of force is the Newton (N). Assume that m = 2 kilograms, c = 8 kilograms per second, k = 80 Newtons per meter, and the applied force in Newtons is if 0 ≤t≤n/2, if t > T/2. a. Solve the initial value problem, using that the displacement y(t) and velocity y'(t) remain continuous when the applied force is discontinuous. For 0 ≤ t ≤/2, y(t) = help (formulas) 20 - {2⁰ For very large positive values of t, y(t) ≈ 0 F(t) = 4 For t>/2, y(t) = b. Determine the long-term behavior of the system. Is lim y(t) = 0? If it is, enter zero. If not, enter a function that approximates y(t) for very large positive 1-4x values of t. help (formulas) help (formulas)

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Consider the initial value problem my" + cy' + ky = F(t), y(0) = 0, y'(0) = 0 modeling the motion of a spring-mass-dashpot system initially at rest and subjected to an applied force F(t), where the unit of force is the Newton (N). Assume that m = 2 kilograms, c = 8 kilograms per second, k 80 Newtons per meter, and the applied force in Newtons is if 0 < t < π/2, if t > π/2. a. Solve the initial value problem, using that the displacement y(t) and velocity y'(t) remain continuous when the applied force is discontinuous. For 0 <t</2, y(t) = F(t) = { 2 0 For very large positive values of t, y(t)≈ 0 20 ہے help (formulas) Fort > T/2, y(t) = b. Determine the long-term behavior of the system. Is lim y(t) = (0)? If it is, enter zero. If not, enter a function that approximates y(t) for very large positive 1-80 values of t. help (formulas) help (formulas)