A mass of 1.42 Kg is connected to a spring of spring constant 8.71 N/m. An oscillation is started by pulling the mass to the right to amplitude 0.522 m before release and the oscillator moves in air. The oscillation decays to 18.2% of the original amplitude in 58.2 seconds. A=0.241m at 26.38 seconds. b=8.31*10^-2 kg/s. Energy lost = 1.15J a. What would the position of the oscillation be 26.38 seconds after release?
A mass of 1.42 Kg is connected to a spring of spring constant 8.71 N/m. An oscillation is started by pulling the mass to the right to amplitude 0.522 m before release and the oscillator moves in air. The oscillation decays to 18.2% of the original amplitude in 58.2 seconds. A=0.241m at 26.38 seconds. b=8.31*10^-2 kg/s. Energy lost = 1.15J a. What would the position of the oscillation be 26.38 seconds after release?
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A mass of 1.42 Kg is connected to a spring of spring constant 8.71 N/m. An oscillation is started by pulling the mass to the right to amplitude 0.522 m before release and the oscillator moves in air. The oscillation decays to 18.2% of the original amplitude in 58.2 seconds. A=0.241m at 26.38 seconds. b=8.31*10^-2 kg/s. Energy lost = 1.15J
a. What would the position of the oscillation be 26.38 seconds after release?
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