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A pendulum can swing through any angle you want. But because of the mathematical approximations you make when you analyze the motion of the pendulum, your predictions are only accurate for a pendulum with a small arc.
The pendulum frequency is dependent upon the length of the pendulum. The torque is the turning force of the pendulum.
The length ,mass and angle :)
The angle narrows as speed goes up
The time period of a simple pendulum is calculated using the following conditions: Length of the pendulum: The longer the length of the pendulum, the longer it takes for one complete back-and-forth swing. Acceleration due to gravity: The time period is inversely proportional to the square root of the acceleration due to gravity. Higher gravity results in a shorter time period. Angle of displacement: The time period is slightly affected by the initial angle of displacement, but this effect becomes negligible for small angles.
A pendulum can swing through any angle you want. But because of the mathematical approximations you make when you analyze the motion of the pendulum, your predictions are only accurate for a pendulum with a small arc.
(4/27)*pi*R3*tan(x) R being the radius of the base of the cone.
The pendulum frequency is dependent upon the length of the pendulum. The torque is the turning force of the pendulum.
The period of a pendulum is affected by the angle created by the swing of the pendulum, the length of the attachment to the mass, and the weight of the mass on the end of the pendulum.
The period of the pendulum is unchanged by the angle of swing. See link.
Only the length of the pendulum has an influence on the pendulum's speed, not the mass or angle of it. Although if the pendulum is red it may blow-up depending on its status.
The length ,mass and angle :)
This is done in order to get unbalanced force act on the pendulum. A torque will act due to gravitation of the earth and the tension in the string as they then act at different points and opposite direction on the pendulum. Have the forces act at the same point, the formation of torque would have been ruled out and the pendulum would not swing.
Yes. The derivation of the simple formula for the period of the pendulum requires the angle, theta (in radians) to be small so that sin(theta) and theta are approximately equal. There are more exact formulae, though.
The length of the pendulum, the angular displacement of the pendulum and the force of gravity. The displacement can have a significant effect if it is not through a small angle.
Any angle that you like. The only limitation on any single angle of an octagon is that it lies between 0 and 360 degrees..
the angle at which you hold and whether it runs out