Frequency is how close waves follow one another, usually given for one second of time. This can alos be measure in the length between successive waves.
For example, a frequency of 14.5 megaHertz has a wavelength of about 20 meters.
For electromagnetic waves, the relationship is simple:
Energy of the photon equals the frequency of the EM wave times Planck's Constant.
Frequency is 1 of 3 variables that determine wave energy. The other two are amplitude and velocity.
Frequency = (wave speed) divided by (wavelength)Wavelength = (wave speed) divided by (frequency)Wave speed = (frequency) multiplied by (wavelength)
normally by its frequency....more the frequency greater is the energy of the wave
The higher the frequency of a wave, the higher its energy.
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Energy of radio signal E = hf, Planck's constant times the frequency.
Frequency is 1 of 3 variables that determine wave energy. The other two are amplitude and velocity.
The product of (wavelength x frequency) is the wave's speed.
The higher the frequency of a wave, the higher its energy.
Wave frequency f, and period of wave T are inverses, related by fT=1.
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The speed of any wave is the product of (wavelength) x (frequency) .
Frequency = (wave speed) divided by (wavelength)Wavelength = (wave speed) divided by (frequency)Wave speed = (frequency) multiplied by (wavelength)
normally by its frequency....more the frequency greater is the energy of the wave
The higher the frequency of a wave, the higher its energy.
As frequency increases the energy of a wave also increases.
No. Energy content of wave packet is directly proportional to the frequency.