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What is the frequency of a sound wave moving in air at room temperature if the wavelength is 78 meters?
The speed of sound in air at room temperature is approximately 343 m/s. To find the frequency, you can use the formula: frequency = speed of sound / wavelength. So, the frequency of a sound wave with a wavelength of 78 meters in air at room temperature would be 343 m/s / 78 m = around 4.4 Hz.
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What is the wavelength of 680 Hz tone moving through air?
The wavelength of a 680 Hz tone moving through air can be calculated using the formula: wavelength = speed of sound / frequency. The speed of sound in air at room temperature is approximately 343 m/s. Therefore, the wavelength of a 680 Hz tone in air would be about 0.504 meters (504 mm).
What is the frequency of a sound wave moving in air at room temperature if the wavelength is 0.686 meters?
At 20 degrees Celsius or 68 degrees Fahrenheit the speed of sound c = 343 m/s. Wavelength lamda is 0.667 meters. Frequency f = c / lambda = 343 / 0.667 = 514.24 Hz.
What is the frequency of a sound wave moving in air at room temperature if the wavelength is 0.686meters?
The speed of sound in air at room temperature is approximately 343 m/s. Using the formula speed = frequency x wavelength, we can calculate the frequency as speed divided by wavelength, which equals 343 / 0.686 ≈ 500 Hz.
If a vacuum has a frequency of 1.01000000000000000000 what is the wave length?
Vacuums don't have frequencies.Electromagnetic waves moving through vacuums have frequencies and wavelengths.They also have speed. Regardless of their frequency and wavelength, their speed is always299,792,458 meters per second.The wavelength of an electromagnetic wave is [ (its speed) divided by (its frequency) ].If its frequency is 1.01 Hz, then its wavelength is 296,824,215.8 meters (about 184,438 miles).
How is wavelength related to frequency for waves moving at a constant speed?
Wavelength and frequency are inversely proportional for waves moving at a constant speed. This means that as the wavelength increases, the frequency decreases, and vice versa. The product of wavelength and frequency is always equal to the speed of the wave.
What is the frequency of a sound wave moving in a room temperature if the wavelength of 0.686 meters?
The speed of sound varies with temperature. At commonly experienced temperatures, it's about 343 meters/sec. Frequency = speed/wavelength = 343/0.686 = 500 Hz
How fast is a wave moving if its wavelength is 10meters and its frequency is 110Hz?
The speed of a wave is equal to its wavelength times its frequency. Since you are using SI units, the answer will be in meters/second.
What is the wavelength of 680 Hz tone moving through air?
The wavelength of a 680 Hz tone moving through air can be calculated using the formula: wavelength = speed of sound / frequency. The speed of sound in air at room temperature is approximately 343 m/s. Therefore, the wavelength of a 680 Hz tone in air would be about 0.504 meters (504 mm).
What is the frequency of a sound wave moving in air at room temperature if the wavelength is 0.686 meters?
At 20 degrees Celsius or 68 degrees Fahrenheit the speed of sound c = 343 m/s. Wavelength lamda is 0.667 meters. Frequency f = c / lambda = 343 / 0.667 = 514.24 Hz.
What is the frequency of a sound wave moving in air at room temperature if the wavelength is 0.686meters?
The speed of sound in air at room temperature is approximately 343 m/s. Using the formula speed = frequency x wavelength, we can calculate the frequency as speed divided by wavelength, which equals 343 / 0.686 ≈ 500 Hz.
If a vacuum has a frequency of 1.01000000000000000000 what is the wave length?
Vacuums don't have frequencies.Electromagnetic waves moving through vacuums have frequencies and wavelengths.They also have speed. Regardless of their frequency and wavelength, their speed is always299,792,458 meters per second.The wavelength of an electromagnetic wave is [ (its speed) divided by (its frequency) ].If its frequency is 1.01 Hz, then its wavelength is 296,824,215.8 meters (about 184,438 miles).
How is wavelength related to frequency for waves moving at a constant speed?
Wavelength and frequency are inversely proportional for waves moving at a constant speed. This means that as the wavelength increases, the frequency decreases, and vice versa. The product of wavelength and frequency is always equal to the speed of the wave.
If a wave is moving at a constant speed and the wavelength is doubled what will happen to the frequency?
IF a wave moving at a constant speed were to have it's wavelength doubled (Wavelength x 2), then the frequency of the wave would be half of what it originally was (Frequency / 2).
If a wave has amplitude of 2 meters a wavelength of 2 meters and a frequency of 10 Hz and a period of 1 second then at what speed is the wave moving?
speed = distance over time = wavelength times frequency = 2 m times 10 hz = 20 m hz = 20 meters per second.
How is wave length related to frequency fro waves moving at a constant speed?
The wavelength and frequency of a wave are inversely related when the wave is moving at a constant speed. This means that as the wavelength increases, the frequency decreases, and vice versa. This relationship is described by the equation: speed = frequency x wavelength.
If a wave has amplitude of 0.2 meters a wavelength of 0.5 meters and a frequency of Hz at what speed is it moving?
The speed of a wave is given by the formula speed = frequency x wavelength. Substituting the given values, the speed of the wave would be 0.25 m/s (1 Hz x 0.5 m).
How is the wavelength related to frequency for waves moving at a constant speed?
Whatever the wavelength and frequency happen to be, their product is always equal to the speed.
