It completes 20 vibrations per second, the the period is 1/20 of a second.
The period of rotation is the time it takes for one full revolution. Since the object completes 15 revolutions in 40 seconds, the time for one revolution is obtained by dividing 40 seconds by 15, which gives a period of rotation of approximately 2.67 seconds per revolution.
The wavelength period of a wave with a frequency of 1000 Hz is 0.001 seconds. This means that the wave completes one full cycle every 0.001 seconds.
The period is the reciprocal of the frequencey. Just divide 1 / (frequency).
If you double the frequency of a vibrating object, its period will be halved. The period is the time taken for one complete cycle of vibration, so increasing the frequency means the object completes more cycles in the same amount of time, resulting in a shorter period.
The frequency of a wave is the number of oscillations or cycles it completes in one second. Since the time period is given as 2 seconds, the frequency can be calculated as 1 divided by the time period, which would be 0.5 Hz.
The period of rotation is the time it takes for one full revolution. Since the object completes 15 revolutions in 40 seconds, the time for one revolution is obtained by dividing 40 seconds by 15, which gives a period of rotation of approximately 2.67 seconds per revolution.
The wavelength period of a wave with a frequency of 1000 Hz is 0.001 seconds. This means that the wave completes one full cycle every 0.001 seconds.
It will be 1/500 of a second = 0.002 seconds.
The period is the reciprocal of the frequencey. Just divide 1 / (frequency).
If you double the frequency of a vibrating object, its period will be halved. The period is the time taken for one complete cycle of vibration, so increasing the frequency means the object completes more cycles in the same amount of time, resulting in a shorter period.
The frequency of a wave is the number of oscillations or cycles it completes in one second. Since the time period is given as 2 seconds, the frequency can be calculated as 1 divided by the time period, which would be 0.5 Hz.
To find the displacement from 2 seconds to 6 seconds, you need to calculate the change in position of the object during that time interval. This can be done by subtracting the position of the object at 2 seconds from its position at 6 seconds. The result will give you the displacement of the object during that time period.
The frequency of a wave with a period of 18 seconds would be 1/18 Hz, which is approximately 0.056 Hz. This means the wave completes one cycle every 18 seconds.
Time period = 1 / frequency. Frequency = 1 / time period. f = 1 / 8 = 0.125 Hz
The period of a 4 Hz wave is 0.25 seconds. Period is the time it takes for one complete cycle of a wave to occur. In this case, for a 4 Hz wave, the wave completes one full cycle every 0.25 seconds.
Frequency = 1/period = 1/0.5 = 2 Hz.
The frequency of the oscillator would be 0.25 Hz (1 divided by 4). This means the oscillator completes one full cycle every 4 seconds.