That simply means that the pendulum doesn't feel any gravity, which would make it move.
Yes, a pendulum can vibrate in an artificial satellite since motion in a satellite is relative and independent of gravity. However, because artificial satellites are typically in a state of free fall or orbit around a celestial body, the motion of a pendulum may appear more complex due to the satellite's acceleration and movement.
A simple pendulum will not swing when it's aboard a satellite in orbit. While in orbit, the satellite and everything in it are falling, which produces a state of apparent zero gravity, and pendula don't swing without gravity.
The angle of the satellite period, depends on where the satellite is positioned. When you figure out where the satellite is you position the angle to be where and what you need.
An artificial satellite is a man-made structure that orbits the Earth or other astronomical object that is used for conducting scientific experiments such as recording weather conditions or is used for communication such as television and radio reception.
No Sputniks are still in orbit. When they were, the period of an orbit was about 88 minutes.
Yes, a pendulum can vibrate in an artificial satellite since motion in a satellite is relative and independent of gravity. However, because artificial satellites are typically in a state of free fall or orbit around a celestial body, the motion of a pendulum may appear more complex due to the satellite's acceleration and movement.
∞
Perhaps if either:The length of the pendulum is infiniteThe pendulum is in perfect zero gravity and has no momentumBut in each of those cases, does it really qualify as a pendulum?
A simple pendulum will not swing when it's aboard a satellite in orbit. While in orbit, the satellite and everything in it are falling, which produces a state of apparent zero gravity, and pendula don't swing without gravity.
It would tend towards infinity
The period of a pendulum is directly proportional to the square root of its length. As the length of a pendulum increases, its period increases. Conversely, if the length of a pendulum decreases, its period decreases.
The time period of a simple pendulum at the center of the Earth would theoretically be zero because there is no gravitational force acting on it. A simple pendulum's period is determined by the acceleration due to gravity, which would be zero at the center of the Earth.
The period of a pendulum is the time it takes for the pendulum to complete one full swing, from its highest point to its lowest point and back. It is influenced by the length of the pendulum and the acceleration due to gravity.
The time period of a simple pendulum at the center of the Earth would be almost zero. This is because there is no gravitational force acting at the center of the Earth due to a balanced pull in all directions. Thus, the pendulum would not experience any acceleration and would not oscillate.
The period of a pendulum is not affected by the mass of the pendulum bob. The period depends only on the length of the pendulum and the acceleration due to gravity.
A longer pendulum has a longer period.
Height does not affect the period of a pendulum.