A 400 g mass swings in a vertical circle at the end of a string having...

A 50.0 g ball swings in a vertical circle at the end of a string of...

A 50.0 g ball swings in a vertical circle at the end of a string of length 39.8 cm. If the speed of the ball at the bottom is 5.11 m/s, what is the speed of the ball at the top? B) Find the work done by gravity on the ball as it goes from bottom to top.

A ball swings in a vertical circle at a constant speed at the end of a...

A ball swings in a vertical circle at a constant speed at the end of a 1.5-m-long string. When the ball is at the top of the circle, the tension is 10N, at the bottom the tension is 50N. a) What is the mass of the ball? b) What is the speed of the ball?

A 440 g mass is whirled in a circle at the end of a string of...

A 440 g mass is whirled in a circle at the end of a string of length L = 82 cm in a horizontal circle. The string makes an angle of 65° with the vertical. What is the speed of the mass?

A simple pendulum, consisting of a string (of negligible mass) of length L with a small...

A simple pendulum, consisting of a string (of negligible mass) of length L with a small mass m at the end, is initially held horizontal (theta = 90) and then released. a) what is the maximum velocity that the mass attains after release? b) at what angle theta, is the power delivered to the ball by gravity a maximum as the pendulum swings down? take theta = 0 when the pendulum is vertical.

A 1.2-m-long massless rod is pivoted at one end and swings around in a circle on...

A 1.2-m-long massless rod is pivoted at one end and swings around in a circle on a frictionless table. A block with a hole through the center can slide in and out along the rod. Initially, a small piece of wax holds the block 20 cm from the pivot. The block is spun at 40 rpm , then the temperature of the rod is slowly increased. When the wax melts, the block slides out to the end of the rod....

A ball of mass m is tied to a string and is rotating in a vertical...

A ball of mass m is tied to a string and is rotating in a vertical plane. The string is elastic (it stretches), which causes the path to be elongated vertically rather than perfectly circular. At the top of the path, the speed has the minimum value that still allows the ball to complete its circular path. Find: the length of the string when it makes an angle θ with respect to the horizontal. The following quantities are known: Mass...

A 1.2-m-long massless rod is pivoted at one end and swings around in a circle on...

A 1.2-m-long massless rod is pivoted at one end and swings around in a circle on a frictionless table. A block with a hole through the center can slide in and out along the rod. Initially, a small piece of wax holds the block 40 cm from the pivot. The block is spun at 50 rpm , then the temperature of the rod is slowly increased. When the wax melts, the block slides out to the end of the rod....

A simple pendulum is constructed from a string of negligible mass. A mass (bob) 0.91kg that...

A simple pendulum is constructed from a string of negligible mass. A mass (bob) 0.91kg that is essentially a point mass. The string length is 0.65m. The pendulum is started by being released from rest with an angle (respect to the vertical) of 5.87 degrees. Use g=9.81 m/s^2. a) the maximum amplitude (in degrees) of this motion b)Angular frequency (in rad/s) of this motion c) Period (in s) of this motion.

A conical pendulum consists of a mass m suspended by a massless string of length l...

A conical pendulum consists of a mass m suspended by a massless string of length l as shown. The mass rotates in a horizontal circle at fixed angular velocity ω so that the string makes a constant angle β with the vertical. Show that the angular velocity of rotation is given by ω = √g/l cos β.

A stuntman whose mass is 76 kg swings from the end of a 3.5-m-long rope along...

A stuntman whose mass is 76 kg swings from the end of a 3.5-m-long rope along the arc of a vertical circle. Assuming that he starts from rest when the rope is horizontal, find the magnitudes of the tensions in the rope that are required to make him follow his circular path at each of the following points.