The frequency of a pendulum varies with the square of the length.
The frequency of a pendulum is inversely proportional to the square root of its length.
A longer pendulum will have a smaller frequency than a shorter pendulum.
The period of the pendulum is (somewhat) inversely proportional to the square root of the length. Therefore, the frequency, the inverse of the period, is (somewhat) proportional to the square root of the length.
9.7m
The lower the frequency, the larger mass and longer length, The higher the frequency, the smaller the mass, and shorter the length.
The frequency of a pendulum is inversely proportional to the square root of its length.
For relatively small oscillations, the frequency of a pendulum is inversely proportional to the square root of its length.
A longer pendulum will have a smaller frequency than a shorter pendulum.
The period of the pendulum is (somewhat) inversely proportional to the square root of the length. Therefore, the frequency, the inverse of the period, is (somewhat) proportional to the square root of the length.
The pendulum frequency is dependent upon the length of the pendulum. The torque is the turning force of the pendulum.
It doesn't. Only the length of the pendulum and the strength of the gravitational field alter the period/frequency.
9.7m
The lower the frequency, the larger mass and longer length, The higher the frequency, the smaller the mass, and shorter the length.
-- its length (from the pivot to the center of mass of the swinging part) -- the local acceleration of gravity in the place where the pendulum is swinging
It's not always the same. The frequency of a pendulum depends on its length, on gravity, on the pendulum's exact shape, and on the amplitude. For a small amplitude, and for a pendulum that has all of its mass concentrated in one point, the period is 2 x pi x square root of (L / g) (where L=length, g=gravity). The frequency, of course, is the reciprocal of this.
Length of the pendulum (distance of centroid to pivot) - shorter is faster. Gravitational or acceleration field strength - more is faster.Note: The mass of the pendulum is not a factor.
Pulse and pendulum According to his first biographer Viviani, Galileo experimented with synchronizing two clocks -- the human pulse, and a pendulum -- in his student days at Pisa. The resulting invention, the "pulsilogium", represented the pulse rate as the length of the pendulum. Try making a pulsilogium: adjust the length of a pendulum so that its rate of swinging agrees with your own pulse. Mark the length. Then adjust the same pendulum for your lab partner's pulse -- is there a detectable difference in pulse rate? 2. Pendulum length and frequency It would be good to know what pendulum length means as a frequency (or pulse rate). http://www.mtholyoke.edu/courses/mpeterso/galileo/time2.htm