In the figure, a stick of length L oscillates as a physical pendulum. (a) What value...

The pendulum in the figure consists of a uniform disk with radius r = 11.0 cm...

The pendulum in the figure consists of a uniform disk with radius r = 11.0 cm and mass 470 g attached to a uniform rod with length L = 640 mm and mass 240 g. (a) Calculate the rotational inertia of the pendulum about the pivot point. (b) What is the distance between the pivot point and the center of mass of the pendulum? (c) Calculate the period of oscillation

The pendulum in the figure consists of a uniform disk with radius r = 13.0 cm...

The pendulum in the figure consists of a uniform disk with radius r = 13.0 cm and mass 880 g attached to a uniform rod with length L = 610 mm and mass 290 g. (a)Calculate the rotational inertia of the pendulum about the pivot point. (b) What is the distance between the pivot point and the center of mass of the pendulum? (c)Calculate the period of oscillation.

A uniform thin stick of length L=3.00 m and mass m=2.00 kg is undergoing small oscillations...

A uniform thin stick of length L=3.00 m and mass m=2.00 kg is undergoing small oscillations about a pivot point x away from its center of mass. For the oscillation period to be the minimum possible value, what should be the value of x? Enter the value in meters.

A uniform thin stick of length L=2.25 m and mass m=1.75 kg is undergoing small oscillations...

A uniform thin stick of length L=2.25 m and mass m=1.75 kg is undergoing small oscillations about a pivot point x away from its center of mass. For the oscillation period to be the minimum possible value, what should be the value of x? Enter the value in meters.

Consider a ‘physical pendulum’ made of a meter stick (length L = 1 m, mass 0.2...

Consider a ‘physical pendulum’ made of a meter stick (length L = 1 m, mass 0.2 kg) with a hole drilled through it at the 5 cm mark. The stick is free to rotate (in a vertical plane) around a nail that goes through the hole and into a wall. Assume no friction between the nail and the hole. The stick’s moment of inertia about the nail is I=0.1 kgm2. (Use g=10 m/s2) If the pendulum is released from rest...

Your aim is to measure the total length, Y, of a physical pendulum, which consists of...

Your aim is to measure the total length, Y, of a physical pendulum, which consists of a thin rod and a square block welded to the end of the rod. You need to determine the distance from the upper end of the rod (the pivot) to the center of the block. You measure the length L of the rod and the vertical height of the block, b. Naturally, Y = L + (b / 2). The meter stick is quite...

The uniform thin rod in the figure below has mass M = 2.00 kg and length...

The uniform thin rod in the figure below has mass M = 2.00 kg and length L = 2.87 m and is free to rotate on a frictionless pin. At the instant the rod is released from rest in the horizontal position, find the magnitude of the rod's angular acceleration, the tangential acceleration of the rod's center of mass, and the tangential acceleration of the rod's free end. HINT An illustration shows the horizontal initial position and vertical final position...

(1) A simple pendulum oscillates back and forth with a maximum angular displacement of θMax “...

(1) A simple pendulum oscillates back and forth with a maximum angular displacement of θMax “ (pi/12) radians. At t = 1.2s, the pendulum is at its maximum displacement. The length of the pendulum is L = 35cm and the mass of the bob attached to the end of it is m = 300g. (a) What is the angular frequency of this oscillation? (b) What is the angular position as a function of time? (c) What is the angular speed...

A simple pendulum oscillates back and forth with a maximum angular displacement of pi/12 radians. At...

A simple pendulum oscillates back and forth with a maximum angular displacement of pi/12 radians. At t=1.2s, the pendulum is at its maximum displacement. The length (L) of the pendulum is 35cm and the mass (m) of the bob attached to the end of it is 300g. (a) What's the angular frequency of this oscillation? (b) What's the angular position as a function of time? (c) What's the angular speed as a function of time? (d) If damping is introduced...

pendulum of mass m= 0.8 kg and length l=1 m is hanging from the ceiling. The...

pendulum of mass m= 0.8 kg and length l=1 m is hanging from the ceiling. The massless string of the pendulum is attached at point P. The bob of the pendulum is a uniform shell (very thin hollow sphere) of radius r=0.4 m, and the length l of the pendulum is measured from the center of the bob. A spring with spring constant k= 7 N/m is attached to the bob (center). The spring is relaxed when the bob is...