3) A 5 kg mass is attached to a spring with spring constant k = 100 N/m, and moves along a horizontal surface which produces a resistive force R = -bv where b = 8 N/m/s. a. Calculate what the angular frequency co would be if there were no resistive force/damping. Is the damped angular frequency greater of less than this? b. Calculate the damping constant a, and what type of damped motion (under critical or over critical damped) occurs? c. Calculate the actuals (damped) angular frequency of the motion. d. The position of the object at any time is x(t) = e-at [Pcos(wot) + Qsin(wot)], where P and Q are constants. Differentiate this to obtain its velocity at any time. e. If the object is released from rest at 1=0 at position xo=0.1 m, find the values of P and Q. f. Convert your solution to the form x(t) = Ae-at cos(wot-d) by finding the values of A and from P and Q. How long does it take the mass to reach the equilibrium point (x = 0) for the first time? g. Differentiate your solution in the new form to get the velocity. How long does is take the mass to reach its furthest distance from the starting point, and how far is this maximum distance from the initial position? [Hint: v=0 at the furthest point] h. Calculate the energy of the system, firstly at its initial point, secondly as it passes through the equilibrium position for the first time (you will have to calculate the velocity there), and thirdly as it reaches the point furthest from its initial point. i. Using the expression for the average energy of an under critically damped harmonic oscillator, calculate how long it takes before the average energy of the system is halved j. Calculate the relaxation time, the logarithmic decrement and the quality factor of the system.

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3) A 5 kg mass is attached to a spring with spring constant k = 100 N/m, and moves along a horizontal surface which produces a resistive force R = -bv where b = 8 N/m/s. a. Calculate what the angular frequency o would be if there were no resistive force/damping. Is the damped angular frequency greater of less than this? b. Calculate the damping constant a, and what type of damped motion (under critical or over critical damped) occurs? c. Calculate the actuals (damped) angular frequency of the motion. d. The position of the object at any time is x(t) = e-at [Pcos (wot) + Qsin(wot)], where P and Q are constants. Differentiate this to obtain its velocity at any time. f. e. If the object is released from rest at 1 = 0 at position xo = 0.1 m, find the values of P and Q. Convert your solution to the form x(t) = Ae-at cos(wot-d) by finding the values of A and from P and Q. How long does it take the mass to reach the equilibrium point (x = 0) for the first time? g. Differentiate your solution in the new form to get the velocity. How long does is take the mass to reach its furthest distance from the starting point, and how far is this maximum distance from the initial position? [Hint: v=0 at the furthest point] h. Calculate the energy of the system, firstly at its initial point, secondly as it passes through the equilibrium position for the first time (you will have to calculate the velocity there), and thirdly as it reaches the point furthest from its initial point. i. Using the expression for the average energy of an under critically damped harmonic oscillator, calculate how long it takes before the average energy of the system is halved j. Calculate the relaxation time, the logarithmic decrement and the quality factor of the system.