When the wavelength of a wave increases, the frequency decreases. When the wavelength decreases, the frequency decreases. These two values are said to be inversely proportional. Here is the equation for velocity of a wave: v = f λ where v = velocity (usually 3.0 x 108 meters/second2, which is the speed of light) f = frequency (usually in Hertz or 1/seconds) λ = wavelength (usually in nm or nanometers)
When the wavelength increases, the frequency decreases: wavelength x frequence = speed of the wave, and this speed usually doesn't change, or doesn't change much, for different frequencies/wavelengths.
The frequency gets lower as you increase the wave length. Conversely as you shorten the wavelength the frequency gets higher.
When wavelength increases, frequency decreases.
As wavelength decreases, frequency increases
the wave decreases.
The wavelength decreases since they are inversely proportional.
As wavelength decreases, energy increases, because the two are inversely related. Conversely, as wavelength decreases, frequency increases.
As wavelength increases the frequency decreases.
When wavelength increases, frequency decreases.
As wavelength decreases, frequency increases
the wave decreases.
Frequency Increases
The wavelength decreases since they are inversely proportional.
The wave's wavelength decreases correspondingly.
As wavelength decreases, energy increases, because the two are inversely related. Conversely, as wavelength decreases, frequency increases.
Its frequency increases. Its energy increases (all other parameters being equal).
if the speed increases the frequency increases if the speed decrease the frequency decreases
Using the relationship C = n lambda C - velocity of light, n-frequency of radiation and lambda- the wavelength. So as frequency increases definitely its wavelength decreases.
As a wavelength increases in size, its frequency and energy (E) decrease.