The pull of earth's gravity causes the motion on the downswing, while momentum keeps it going on the upswing.
The restoring force acting on a swing pendulum is due to gravity pulling the pendulum back towards the equilibrium position. This force is proportional to the displacement of the pendulum from equilibrium, causing the pendulum to oscillate back and forth.
A complete swing of a pendulum is called an oscillation or a cycle. It consists of the pendulum moving from one side to the other and back again.
A pendulum.
The period of a pendulum is the time it takes to complete one full swing back and forth. In this case, the period of the pendulum is 10 seconds (5 seconds for each half of the swing).
The tension in the cord provides the restoring force that makes the pendulum swing back and forth. The force of gravity acts on the mass of the pendulum, contributing to its acceleration. Both factors influence the period and amplitude of the pendulum's motion.
Gravity makes a pendulum swing back and forth. The object starts at one point, and then moves in a circular motion to the apex of it's next point. The kinetic energy becomes less and less as time goes on if no extra energy is added.
The restoring force acting on a swing pendulum is due to gravity pulling the pendulum back towards the equilibrium position. This force is proportional to the displacement of the pendulum from equilibrium, causing the pendulum to oscillate back and forth.
A complete swing of a pendulum is called an oscillation or a cycle. It consists of the pendulum moving from one side to the other and back again.
A pendulum
A pendulum.
The period of a pendulum is the time it takes to complete one full swing back and forth. In this case, the period of the pendulum is 10 seconds (5 seconds for each half of the swing).
The tension in the cord provides the restoring force that makes the pendulum swing back and forth. The force of gravity acts on the mass of the pendulum, contributing to its acceleration. Both factors influence the period and amplitude of the pendulum's motion.
The time required for a pendulum to make one swing over and back is called its period. It is the time it takes for the pendulum to complete one full oscillation.
Some examples of things that move back and forth include a swing, a pendulum, a rocking chair, and a seesaw.
The length of a pendulum affects the time it takes for one complete swing, known as the period. A longer pendulum will have a longer period, meaning it will take more time for one swing. This does not affect the number of swings back and forth, but it does impact the time it takes for each swing.
A pendulum swings due to the force of gravity acting on it as it moves back and forth. When the pendulum is released from a raised position, gravity causes it to fall and start swinging. The length of the pendulum and the angle at which it is released also affect how it swings.
Gravity makes a pendulum swing back and forth. The object starts at one point, and then moves in a circular motion to the apex of it's next point. The kinetic energy becomes less and less as time goes on if no extra energy is added.