A monkey with mass m and length L swings about a pivot point where his hand...

A thin rod of length ll swings at small amplitude with the pivot point at one...

A thin rod of length ll swings at small amplitude with the pivot point at one end, with a thick rod of length LL and radius RR attached on the other end. The thin rod has a mass mm = 0.14 kg, and the thick rod a mass of MM = 1.36 kg. The radius of the thick rod is 0.09 m. If ll = 0.86 m and LL = 0.06 m, what is the period of oscillation? Answer in...

A long, thin rod of length l and mass m hangs from a pivot point about...

A long, thin rod of length l and mass m hangs from a pivot point about which it is free to swing in a vertical plane like a simple pendulum. Calculate the total angular momentum of the rod about the pivot point as a function of its instantaneous angular frequency ω. Calculate the total kinetic energy of the rod.

A simple pendulum with a length of 2.73 m and a mass of 6.54 kg is...

A simple pendulum with a length of 2.73 m and a mass of 6.54 kg is given an initial speed of 1.36 m/s at its equilibrium position. (a) Assuming it undergoes simple harmonic motion, determine its period. s (b) Determine its total energy. J (c) Determine its maximum angular displacement. (For large v, and/or small l, the small angle approximation may not be good enough here.) °

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.

A block of mass 0.125 kg is hanging on a spring. Nora gently pulls the mass...

A block of mass 0.125 kg is hanging on a spring. Nora gently pulls the mass down a distance of 4.0 cm and then lets go. The mass bobs up and down in simple harmonic motion (i.e. it oscillates) with a period of 0.47 s. (a) What is the value of the spring constant? N/m Nora stops the mass from oscillating. She gently pulls the mass down again, this time to a distance of 5 cm, and lets the mass...

The length of a simple pendulum is 0.85 m and the mass of the particle (the...

The length of a simple pendulum is 0.85 m and the mass of the particle (the "bob") at the end of the cable is 0.26 kg. The pendulum is pulled away from its equilibrium position by an angle of 7.75° and released from rest. Assume that friction can be neglected and that the resulting oscillatory motion is simple harmonic motion. (a) What is the angular frequency of the motion? rad/s (b) Using the position of the bob at its lowest...

A simple pendulum with mass m = 2 kg and length L = 2.67 m hangs...

A simple pendulum with mass m = 2 kg and length L = 2.67 m hangs from the ceiling. It is pulled back to an small angle of θ = 11° from the vertical and released at t = 0. 1)What is the period of oscillation? s   2)What is the magnitude of the force on the pendulum bob perpendicular to the string at t=0? N   3)What is the maximum speed of the pendulum? m/s   4)What is the angular displacement at...

A simple pendulum with mass m = 1.5 kg and length L = 2.51 m hangs...

A simple pendulum with mass m = 1.5 kg and length L = 2.51 m hangs from the ceiling. It is pulled back to an small angle of θ = 9.6° from the vertical and released at t = 0. a) What is the angular displacement at t = 3.69 s? (give the answer as a negative angle if the angle is to the left of the vertical) (- The period of oscillation is 3.18s)

Imagine a small satellite of mass m that describes a circular orbit. If at a point...

Imagine a small satellite of mass m that describes a circular orbit. If at a point in the orbit it receives a small radial impulse when applying its motors very briefly (ignore the loss of mass), then the orbit changes a small distance δ, such that the satellite begins to oscillate with respect to its orbit r_0, it is say r (t) = r0 + δ (t), (δ (t) ≪r0) You may recall from your mechanical course that the gravitational...