A tire swing of length L = 6.3 m hangs from a tree over the water. On a hot day, a swimmer uses the swing to jump into the lake, and afterward the swing oscillates as a simple pendulum. What is the period of this pendulum?
A tire swing of length L = 6.3 m hangs from a tree over the water....
Question 1 (1 point) A tire swing of length L = 6.3 m hangs from a tree over the water. On a hot day, a swimmer uses the swing to jump into the lake, and afterward the swing oscillates as a simple pendulum. What is the period of this pendulum? none the 5.0 s 4.3 S 3.1 s 6.0 5
A tire swing of length L = 6.3 m hangs from a tree over the water. On a hot day, a swimmer uses the swing to jump into the lake, and afterward the swing oscillates as a simple pendulum. What is the period of this pendulum? Question options: 5.0 s 6.0 s none of these 3.1 s 4.3 s Question An electric field of magnitude 100. N/c points vertically downward near Earth's surface. What force does a free electron experience...
Kids at a swimming hole swing over the water on a tire swing (essentially a simple pendulum) and then drop in the water. If the tire+kid takes 3.0·s to swing from the launching point to its farthest point over the water. How long will it take the empty tire to return for the next kid? Assuming the tire is launched without a push from its highest point, what is the frequency of the tire-swing-pendulum (unloaded)? How long is the rope?
A tire swing that hangs 1.00m from a tree limb that experiences simple harmonic motion completes a cycle in 1.00s on Earth. Identify the acceleration due to gravity of a larger celestial body within the solar system if the same tire swing that experiences simple harmonic motion completes a cycle in 1.66s.
A simple pendulum with mass m = 2.3 kg and length L = 2.62 m hangs from the ceiling. It is pulled back to an small angle of θ = 9.2° from the vertical and released at t = 0. 1) What is the period of oscillation? 2) What is the magnitude of the force on the pendulum bob perpendicular to the string at t=0? 3) What is the maximum speed of the pendulum? 4) What is the angular displacement...
A simple pendulum with mass m = 2.1 kg and length L = 2.79 m hangs from the ceiling. It is pulled back to a small angle of θ = 11.5° from the vertical and released at t = 0. 1) What is the period of oscillation? 2) What is the magnitude of the force on the pendulum bob perpendicular to the string at t=0? 3) What is the maximum speed of the pendulum? 4) What is the angular displacement...
A simple pendulum with mass m = 1.8 kg and length L = 2.77 m hangs from the ceiling. It is pulled back to an small angle of θ = 9° from the vertical and released at t = 0. 1) What is the period of oscillation? Answer= 3.34 s 2) What is the magnitude of the force on the pendulum bob perpendicular to the string at t=0? Answer= 2.76 N 3) What is the maximum speed of the pendulum?...
A simple pendulum with mass m = 2.1 kg and length L = 2.3 m hangs from the ceiling. It is pulled back to an small angle of θ = 11.9° from the vertical and released at t = 0. 1)What is the period of oscillation? 2)What is the magnitude of the force on the pendulum bob perpendicular to the string at t=0? 3)What is the maximum speed of the pendulum? 5)What is the magnitude of the tangential acceleration as...
A simple pendulum with mass m = 2.1 kg and length L = 2.3 m hangs from the ceiling. It is pulled back to an small angle of θ = 11.9° from the vertical and released at t = 0. 4)What is the angular displacement at t = 3.56 s? (give the answer as a negative angle if the angle is to the left of the vertical) 6)What is the magnitude of the radial acceleration as the pendulum passes through...
A simple pendulum with mass m = 1.7 kg and length L = 2.47 m hangs from the ceiling. It is pulled back to an small angle of = 11.8° from the vertical and released at t = 0. 1) What is the period of oscillation? s Submit Help You currently have 10 submissions for this question. Only 15 submission are allowed. You can make 5 more submissions for this question. Your sih missions: Computed value: 2.9 Submitted: Thursday, November...