That's short.
(Note that the question avoids any definition of 'low' or 'high',
so any answer should suffice.)
Using the equation v=fλ, you can rearrange to get λ=v/f If the speed if low and the frequency is high, you will get a low value for the wavelength.
Nothing, as the speed of sound doesn't change (about 340 metres per second in air). If the frequency (or pitch) were to be twice as high it would simply halve the wavelength.
You can infer that it is on or near a fault line. You can also infer that a earthquake is very likely to occur there.
Of course. The wavelength and amplitude have no influence on each other.
It's called ultra high frequency, of UHF.
A light ray is a straight line with speed c=fw. The speed c is a constant and the product of the wavelength, w and the frequency f. The frequency is f=c/w, inverse to the wavelength. If the wavelength is long the frequency is low; if the wavelength is small the frequency is high.
The product of (frequency) times (wavelength) is always the same number ... it's the speed of the wave. So if the frequency increases, the wavelength must decrease, to keep the product constant.
The speed of the vibration. High speed vibration = high frequency = short wavelength = high pitch. Low speed vibration = low frequency = long waves = low pitch.
Using the equation v=fλ, you can rearrange to get λ=v/f If the speed if low and the frequency is high, you will get a low value for the wavelength.
a wave with long wavelength and high frequency.
It depends on what you consider high frequency and long wavelength. However, as frequency increases, wavelength decreases and vice versa. In fact, frequency is inversely proportional to wavelength.
Speed = (frequency) x (wavelength) = (36) x (12) = 432 meters per second.Isn't this a pretty high speed for sound in air . . . ? ? ?
Frequency = (speed) / (wavelength) =(18 miles per second) x (1,609.344 meters per mile) / (50 meters) = 579.4 Hz (rounded)This speed and frequency is awfully high for a water wave, but the math is the math.
Waves are characterized by wavelength, frequency, and speed. Wavelength is the distance between two consecutive peaks or troughs in a wave. The frequency is defined as the number of waves (cycles) per second that pass a given space. Since all types of electromagnetic radiation travel at the speed of light, short-wavelength radiation must have a high frequency and long-wavelength radiation must have a low frequency.
EM radiation with a wavelength of 15 cm has a frequency of 1.9987 GHz. (Giga Hertz) or close enough to 2GHz. Technically this is in the UHF (Ultra High Frequency) section of the radio spectrum which is 300MHz to 3GHz.
High energy light has a small wavelength, and a high frequency.
Lambda( Wavelength) = velocity/frequency Frequency = 18 x 10^3 Hz Velocity = Speed of sound = 340m/s wavelength = 340/18x10^3 = 17/900 m