Consider a simple pendulum immersed in a viscous fluid. If the resistance of the fluid can...

A torsional pendulum executes simple harmonic motion by rotating about its axis. It consists of a...

A torsional pendulum executes simple harmonic motion by rotating about its axis. It consists of a coil spring attached to a balance wheel (a disk in this case). Recall that a torsional pendulum is similar to a normal pendulum with force replaced by torque, linear displacement replaced by angle turned, and mass replaced by moment of inertia. The spring constant is replaced by torsion constant. Assume the balance wheel of such a torsional pendulum is doubled in size but the...

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...

Consider a simple harmonic oscillator made of a mass sliding on a frictionless surface, and attached...

Consider a simple harmonic oscillator made of a mass sliding on a frictionless surface, and attached to a massless linear spring. Which of the following statements are true? (If A and E are, and the others are not, enter TFFFT).      A) Doubling the mass will not change the period.      B) Doubling the amplitude will halve the frequency.      C) Quadrupling the spring constant will double the frequency.      D) Doubling the mass will double the frequency.      E)...

A pendulum of mass 2.0 kg is raised to a height of 0.4 m above the...

A pendulum of mass 2.0 kg is raised to a height of 0.4 m above the lowest point in its swing and then is released from rest. If air resistance can be ignored, how high will the pendulum swing on the other side of its motion? A) Half as high B) One fourth as high C) One third as high D) Just as high E) Not move 9) 3pt For the pendulum in the previous problem, how fast will it...

Consider a simple pendulum with a bob of mass 4.0 kg and a string of length...

Consider a simple pendulum with a bob of mass 4.0 kg and a string of length 45 cm. Part A: Which of the following is true for small angular displacement? a. The net torque is proportional to the negative of the angle displaced from the equilibrium b. The period is inversely proportional to the amplitude c. The kinetic energy is always equal to the potential energy d. The minimum velocity is achieved when the bob is at equilibrium Part B:...

Simple Pendulum Please write your answers on a color of your choice. Purpose To determine the...

Simple Pendulum Please write your answers on a color of your choice. Purpose To determine the value of the gravitational acceleration by using a simple pendulum. Lab goals To be able to perform an experiment independently. To be able to take measurements, obtain results, and interpret them correctly.               To be able to estimate the accuracy of experimental results. Equipment A small object with a hole such as a bead or nut, and a long string A measuring tape...

Consider a block attached to a horizontal spring that undergoes simple harmonic motion as shown with...

Consider a block attached to a horizontal spring that undergoes simple harmonic motion as shown with an amplitude of A =10 cm If the kinetic energy of the block is increasing the block must be (a) moving away from the equilibrium position (b) moving towards the equilibrium position c) at equilibrium position (d) maximum displacement

A series of experiments is conducted to analyze the effect of fluid resistance on the motion...

A series of experiments is conducted to analyze the effect of fluid resistance on the motion of various small objects of mass m falling from rest in columns of different fluids. In all cases the acceleration due to gravity is g = 10 m/s2 and the magnitude of the fluid resistance force can be modeled by the equation FR = kv where k is a constant and v is the magnitude of the velocity of the object. Which of the...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A student measures an amplitude of 0.923 m and a duration of 129 s for 65 cycles of oscillation. Find the frequency, ?, the speed at the equilibrium position, ?max, the spring constant, ?, the potential energy at an endpoint, ?max, the potential energy when the particle is located 68.5% of the amplitude away from the equiliibrium position, ?, and the kinetic energy, ?, and...

a) Consider a brass cylinder that is suspended in air. Air is also a fluid, with...

a) Consider a brass cylinder that is suspended in air. Air is also a fluid, with density ρair = 1.29 × 10−3 g/cm3 and yet you seldom consider the buoyant force exerted by air when you deal with an object like this. To see why determine the ratio, FB/Fgrav, of the buoyant force exerted by the air on the cylinder to the gravitational force exerted on the cylinder, whose density can be assumed to be 8.5 × 103 kg/m3 ....