Ignore the question: Draw the initial diagram and the final diagram You throw a yo-yo of...

You throw a yo-yo of mass 30.0 g straight down with a linear speed of 1.00...

You throw a yo-yo of mass 30.0 g straight down with a linear speed of 1.00 m/s and an angular speed of 2.00 rotations per second. Once the yo-yo has dropped 1.00 m, it stops and rotates in place. Treat the yo-yo as a hollow cylinder with a radius of 3.00 cm. Assume energy is conserved. Find angular speed (in radians/second) of the yo-yo after it has fallen 1.00 m. Does this speed seem realistic? If not, what might explain...

You throw a yo-yo of mass 30.0 g straight down with a linear speed of 1.00...

You throw a yo-yo of mass 30.0 g straight down with a linear speed of 1.00 m/s and an angular speed of 2.00 rotations per second. Once the yo-yo has dropped 1.00 m, it stops and rotates in place. Treat the yo-yo as a hollow cylinder with a radius of 3.00 cm. Assume energy is conserved. Find angular speed (in radians/second) of the yo-yo after it has fallen 1.00 m. Does this speed seem realistic? If not, what might explain...

You throw a yo-yo of mass 30.0 g straight down with a linear speed of 1.00...

You throw a yo-yo of mass 30.0 g straight down with a linear speed of 1.00 m/s and an angular speed of 2.00 rotations per second. Once the yo-yo has dropped 1.00 m, it stops and rotates in place. Treat the yo-yo as a hollow cylinder with a radius of 3.00 cm. Assume energy is conserved. Find angular speed (in radians/second) of the yo-yo after it has fallen 1.00 m. Does this speed seem realistic? If not, what might explain...

A quarterback is set up to throw the football to a receiver who is running with...

A quarterback is set up to throw the football to a receiver who is running with a constant velocity ~vr directly away from the quarterback and is now a distance D away from the quarterback. The quarterback estimates that the ball must be thrown at an angle θ to the horizontal and the receiver must catch the ball a time interval tc after it is thrown. Assume the ball is thrown and caught at the same height y = 0...

A child pushes her friend (m = 25 kg) located at a radius r = 1.5...

A child pushes her friend (m = 25 kg) located at a radius r = 1.5 m on a merry-go-round (rmgr = 2.0 m, Imgr = 1000 kg*m2) with a constant force F = 90 N applied tangentially to the edge of the merry-go-round (i.e., the force is perpendicular to the radius). The merry-go-round resists spinning with a frictional force of f = 10 N acting at a radius of 1 m and a frictional torque τ = 15 N*m...