A compact object with a mass of 5.60 kg oscillates at the end of a vertical spring with a spring constant of 2.00 x 10* N/m. Themotion is damped by air resistance, and the damping coefficient is b = 3.00 N. s/m.(a) What is the frequency (in Hz) of the damped oscillation?Hz(b) By what percentage does the amplitude of the oscillation decrease in each cycle?%(c) Over what time interval (in s) does the energy of the system drop to 5.00% of its initial value?(d) What If? The atmosphere of Venus is 50 times thicker than that on Earth. If the effect of air resistance on Venus isrepresented by b = 150 N s/m, recalculate the answers for parts (a) to (c) for this system if it is set in motion in theatmosphere of Venus.What is the frequency (in Hz) of the damped oscillations?HzWhat is the percentage decrease in amplitude in each cycle?%What is the time interval (in s) for the energy to drop to 5.00% of its initial value?

Given: damped oscillator Value of spring constant, mass of object, Damping coefficient. We will use…

Answered: A compact object with a mass of 5.60 kg…

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