-- Red light has the lowest frequency of those three.
-- Green light has lower frequency than violet light has.
-- The wavelength of all light is inversely proportional to its frequency.
It is electromagnetic radiation, which is the same in composition as visible light but has a much higher frequency/shorter wavelength, and will do damage to any biological material it passes through. Both travel at the same speed ('velocity of light') but gamma radiation can penetrate material opaque to visible light.
-- Compare: They're both electromagnetic radiation. -- Contrast: X-rays have longer wavelength, lower frequency, and carry less energy, than gamma rays.
advantages: -very informative when examining how values are changing within the data set. -shows the running total of frequencies from the lowest interval up. disadvantages: -difficult to compare the frequencies between each data group. by Mr. Hsia
Radio waves are longer than X-rays and because energy is inversely proportional to wavelength, X-Rays have more energy. The formula is 1.25uevm/wavelength, that is the energy is 1.25 micro electron volt divided by the wavelength in meters.
Smaller instruments produce higher frequencies. Compare, for example, the violin, the viola, and the bass. All have the same shape, but increasing size, with correspondingly lower pitch.
very nice answer.
the frequencies are same.
The formula goes: c = lambda times f where c is the speed in the medium (air) in meters per second lambdathe wavelength in meters and f the frequency in Hz. If the frequency is doubled, the wavelength will be halved.
The frequency of blue light is roughly double the frequency of red light.
All electromagnetic waves travel at the same speed in a vacuum, but they have different wavelengths and different frequenciesSource- IS textbook 7th gradeHow do Electromagnetic Waves compare? from this received answers
Provided you compare waves that all have the same speed, the longest wave has the lowest frequency.
The longer the pipe, the longer the wavelength, and the lower the frequency. The pipe organ is the world's best workshop for fully understanding those concepts.
There's no dependence or connection between a wave's amplitude and its frequency.
The wavelength of an X-ray is much shorter than the wavelength of a red light from a neon sign. The frequency is much longer in an X-ray than the frequency of a red light from a neon sign.
Assuming that both notes are in the range of C4 (middle C) and C5, G has a frequency of 392Hz, and A has a frequency of 440Hz. Assuming that both sound waves are travelling through air, through which sound travels at 340ms-1, then the wavelengths for G and A can be found to be 0.87m and 0.77m, respectively.An easier way to assess a change in wavelength would be to look at the equation v=fλ, where v is the speed of sound, f is the frequency of the note, and λ is the wavelength of the note. A higher pitch note means a higher frequency, and since the speed of sound is constant, then if the pitch is increased the wavelength must compensate by decreasing.Simply put, higher pitch means smaller wavelength.
Assuming that both notes are in the range of C4 (middle C) and C5, G has a frequency of 392Hz, and A has a frequency of 440Hz. Assuming that both sound waves are travelling through air, through which sound travels at 340ms-1, then the wavelengths for G and A can be found to be 0.87m and 0.77m, respectively.An easier way to assess a change in wavelength would be to look at the equation v=fλ, where v is the speed of sound, f is the frequency of the note, and λ is the wavelength of the note. A higher pitch note means a higher frequency, and since the speed of sound is constant, then if the pitch is increased the wavelength must compensate by decreasing.Simply put, higher pitch means smaller wavelength.
Visible light has a higher frequency, a higher energy per photon, and a smaller wavelength, compared to infrared.