The figure shows a ball with mass m = 0.450 kg attached to the end of...

The figure shows a ball with mass m = 0.295 kg attached to the end of...

The figure shows a ball with mass m = 0.295 kg attached to the end of a thin rod with length L = 0.306 m and negligible mass. The other end of the rod is pivoted so that the ball can move in a vertical circle. The rod is held horizontally as shown and then given enough of a downward push to cause the ball to swing down and around and just reach the vertically upward position, with zero speed...

The figure shows a thin rod, of length L = 2.10 m and negligible mass, that...

The figure shows a thin rod, of length L = 2.10 m and negligible mass, that can pivot about one end to rotate in a vertical circle. A heavy ball of mass m = 7.10 kg is attached to the other end. The rod is pulled aside to angle θ0 = 5.3° and released with initial velocity v→0 = 0. (a) What is the speed of the ball at the lowest point? (b) Does the speed increase, decrease, or remain...

A ball with a mass of 1.50 kg is attached to the end of a string...

A ball with a mass of 1.50 kg is attached to the end of a string that is 0.400 m in length. You swing the ball so that it swings in a vertical circle, traveling at a speed of 4.80 m/s at the top of the circle. (a) Draw the free-body diagram of the ball. Make sure you label all your vectors and clearly indicate their direction. (b) What is the tension in the string when the ball is at...

A 3970 kg demolition ball swings at the end of a 34.4 m cable on the...

A 3970 kg demolition ball swings at the end of a 34.4 m cable on the arc of a vertical circle. At the lowest point of the swing, the ball is moving at a speed of 2.08 m/s. Determine the tension in the cable.

A stick of mass M and length L is pivoted at one end. A small mass...

A stick of mass M and length L is pivoted at one end. A small mass m<M is attached to the right-hand end of the stick. The stick is held horizontally and released from rest. Given that the rotational inertia of a uniform rod pivoted around one end is 1/3ML^2, determine the rotational inertia of the described system. Calculate the angular velocity of the system when it reaches a vertical position. You cannot use rotational kinematics here because angular acceleration...

A mass m is moving horizontally with a speed of 3.14 m/s just before it strikes...

A mass m is moving horizontally with a speed of 3.14 m/s just before it strikes a uniform rod of the same mass with length L = 2.12 m, which is initially hanging vertically. The rod is supported by a friction-less axle through a point L/4 down from the upper end of the rod. To what maximum angle (in degrees, with respect to its initial vertical position) will the rod swing before coming back down?

The figure shows a rigid assembly of a thin hoop (of mass m = 0.14 kg...

The figure shows a rigid assembly of a thin hoop (of mass m = 0.14 kg and radius R = 0.11 m) and a thin radial rod (of length L = 2R and also of mass m = 0.14 kg). The assembly is upright, but we nudge it so that it rotates around a horizontal axis in the plane of the rod and hoop, through the lower end of the rod. Assuming that the energy given to the assembly in...

The figure shows a rigid assembly of a thin hoop (of mass m = 0.23 kg...

The figure shows a rigid assembly of a thin hoop (of mass m = 0.23 kg and radius R = 0.16 m) and a thin radial rod (of length L = 2R and also of mass m = 0.23 kg). The assembly is upright, but we nudge it so that it rotates around a horizontal axis in the plane of the rod and hoop, through the lower end of the rod. Assuming that the energy given to the assembly in...

A 0.0410- kg ball swings on the end of a 1.270- m-long string. On one swing...

A 0.0410- kg ball swings on the end of a 1.270- m-long string. On one swing the tension in the string is 1.177 N at the lowest point. By the second swing the ball has lost 9.3 percent of its energy. What is the ball's speed at the lowest point on the second swing?

A schoolyard teeter-totter with a total length of 6.3 m and a mass of 41 kg...

A schoolyard teeter-totter with a total length of 6.3 m and a mass of 41 kg is pivoted at its center. A 16 kg child sits on one end of the teeter-totter. Part A: Where should a parent push vertically downward with a force of 210 N in order to hold the teeter-totter level? Part B: Where should the parent push with a force of 330 N ? Part C: How would your answers to parts A and B change...