The angle that the string of a long pendulum makes with the vertical is shown as a function of time. What is the angular frequency of the pendulum?
B) What is the amplitude of the pendulum's motion, in meters?
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1. The angle that the string of a long pendulum makes with the vertical is shown as a function of time. What is the angular frequency of the pendulum? 2. What is the amplitude of the pendulum's motion, in meters? The angle that the string of a long pendulum makes with the vertical is shown as a function of time. What is the angular frequency of the pendulum? What is the amplitude of the pendulum's motion, in meters?
The angle that the string of a long pendulum makes with the vertical is shown as a function of time. a) What is the angular frequency of the pendulum? b)What is the amplitude of the pendulum's motion, in meters?
1. [1pt] The angle that the string of a long pendulum makes with the vertical is shown as a function of time. What is the angular frequency of the pendulum? Answer: 2. [1pt] What is the amplitude of the pendulum's motion, in meters? theta (degrees) NOTOT 0 1 2 4 5 3 t (s)
previous 5 of 7 next Problem 11.46-Copy Part A In the laboratory, a student studles a pendulum by graphing the angle that the string makes with the vertical as a function of time t obtaining the graph shown in the figure (Eigure 1) What is the period of the pendulum's motion? Express your answer in seconds to one decimal place. Submit My Answers Give Up Part B What is the frequency of the pendulum's motion? Figure 1 of 1 Express...
(1 point) Suppose a pendulum with length L (meters) has angle 0 (radians) from the vertical. It can be shown that 0 as a function of time satisfies the differential equation: d20 + -sin 0 = 0 dt2 L where g = 9.8 m/sec/sec is the acceleration due to gravity. For small values of 0 we can use the approximation sin(0) ~ 0, and with that substitution, the differential equation becomes linear A. Determine the equation of motion of a...
(1 point) Suppose a pendulum of length L meters makes an angle of θ radians with the vertical, as n the figure t can be shown that as a function of time, θ satisfies the differential equation d20 + sin θ-0, 9.8 m/s2 is the acceleration due to gravity For θ near zero we can use the linear approximation sine where g to get a linear di erential equa on d20 9 0 dt2 L Use the linear differential equation...
A simple pendulum consists of a point mass, m, attached to the end of a massless string of length 2. It is pulled out of its straight-down equilibrium position by a small angle 8 and released so that it oscillates about the equilibrium position in simple harmonic motion. A graph showing the pendulum's angular position as a function of time is given in the figure. What is the frequency of the pendulum's motion? (degre) 1.07 120 3.0 et one: 0.63...
(radians) from the vertical. It can be shown that as a function of time satisfies the (1 point) Suppose a pendulum with length L (meters) has angle differential equation: d20 + & sin 0 = 0 dt 2 L where g = 9.8 m/sec/sec is the acceleration due to gravity. For small values of we can use the approximation sin() ~ 0, and with that substitution, the differential equation becomes linear. A. Determine the equation of motion of a pendulum...
show all steps please (1 point) Suppose a pendulum with length L (meters) has angle 0 (radians) from the vertical. It can be shown that 0 as a function of time satisfies the differential equation: d20 +sin0 0 dt2 where g 9.8 m/sec/sec is the acceleration due to gravity. For small values of 0 we can use the approximation sin(0)~0, and with that substitution, the differential equation becomes linear. A. Determine the equation of motion of a pendulum with length...
(10 points) Suppose a pendulum with length L (meters) has angle (radians) from the vertical. It can be shown that e as a function of time satisfies the differential equation: de 8 + -sin 0 = 0 dt2 L where g = 9.8 m/sec/sec is the acceleration due to gravity. For small values of we can use the approximation sin(0) - 0, and with that substitution, the differential equation becomes linear. A. Determine the equation of motion of a pendulum...