Approximately 2*pi*sqrt(l/g) where
l is the length of the pendulum (in metres) and g = 9.8 ms-2, the acceleration due to gravity.
Yes. Given a constant for gravity, the period of the pendulum is a function of it's length to the center of mass. In a higher gravity, the period would be shorter for the same length of pendulum.
Hardly at all, at small displacements or amplitudes. At larger displacements (larger angles), the period will get somewhat longer.
A longer pendulum has a longer period.
Height does not affect the period of a 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.
Its length.
Yes. Given a constant for gravity, the period of the pendulum is a function of it's length to the center of mass. In a higher gravity, the period would be shorter for the same length of pendulum.
A pendulum with a period of five seconds has a length of 6.21 meters.
The answer is cleverly embedded in the question. If it takes one second to make a complete vibration, then that's the period.
Hardly at all, at small displacements or amplitudes. At larger displacements (larger angles), the period will get somewhat longer.
A shorter pendulum has a shorter period. A longer pendulum has a longer period.
Suppose that a pendulum has a period of 1.5 seconds. How long does it take to make a complete back and forth vibration? Is this 1.5 second period pendulum longer or shorter in length than a 1 second period pendulum?
A longer pendulum has a longer period. A more massive pendulum has a longer period.
A longer pendulum has a longer period.
Height does not affect the period of a pendulum.
The To and Fro motion about the mean position of any system is known as the vibration or oscillation. Example- A simple 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.