(b) For the damped oscillator system, the block has a mass of 1.50 kg and the spring constant is 8.00 N/m. The damping force is given by -b(dx/dt), where b = 230 g/s. The block is pulled down 12.0 cm and released. (a) Calculate the time required for the amplitude of the resulting oscillations to fall to one-third of its initial value. (b) How many oscillations are made by the block in this time?
(b) For the damped oscillator system, the block has a mass of 1.50 kg and the spring constant is 8.00 N/m. The damping force is given by -b(dx/dt), where b = 230 g/s. The block is pulled down 12.0 cm and released. (a) Calculate the time required for the amplitude of the resulting oscillations to fall to one-third of its initial value. (b) How many oscillations are made by the block in this time?
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Transcribed Image Text:(b) For the damped oscillator system, the block has a mass of 1.50 kg and the spring
constant is 8.00 N/m. The damping force is given by -b(dx/dt), where b = 230 g/s. The
block is pulled down 12.0 cm and released. (a) Calculate the time required for the
amplitude of the resulting oscillations to fall to one-third of its initial value. (b) How
many oscillations are made by the block in this time?
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