A 0.250 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.500 N to displace the glider to a new equilibrium position, x= 0.070 m. Foooo moooo Find the effective spring constant of the system. The gilder is now released from rest at x= 0.070 m. Find the maximum x-acceleration of the glider. Find the x-coordinate of the glider at time t= 0.350T, where T is the period of the oscillation. Find the kinetic energy of the glider at x=0.00 m. 1.75x10-² J You are correct. Your receipt no. is 157-1051 > Previous Tries
A 0.250 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.500 N to displace the glider to a new equilibrium position, x= 0.070 m. Foooo moooo Find the effective spring constant of the system. The gilder is now released from rest at x= 0.070 m. Find the maximum x-acceleration of the glider. Find the x-coordinate of the glider at time t= 0.350T, where T is the period of the oscillation. Find the kinetic energy of the glider at x=0.00 m. 1.75x10-² J You are correct. Your receipt no. is 157-1051 > Previous Tries
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Transcribed Image Text:A 0.250 kg air-track glider is attached to each end of the track by two coil springs. It takes a horizontal force of 0.500 N to displace the glider to a new
equilibrium position, x= 0.070 m.
voooo
0
+X
Find the effective spring constant of the system.
The giider is now released from rest at x= 0.070 m. Find the maximum x-acceleration of the glider.
Find the x-coordinate of the glider at time t= 0.350T, where T is the period of the oscillation.
Find the kinetic energy of the glider at x=0.00 m.
1.75x10-² J
You are correct.
Your receipt no. is 157-1051
Previous Tries
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