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If the speed of a wave doubles while the wavelength remains the same what happens to the wavelength?
Wiki User
∙ 14y ago
You actually answered your own question. The wavelength remains the same since it is stated as part of the problem. However, the frequency, which I am betting you are more interested in will double. The frequency is releated to the wavelength and the speed of the wave by the following equation
f = v/l
where f is the frequency, v is the speed, and l is the wavelength. So if the velocity doubles and the wavelength is constant, then the frequency will double.
Wiki User
∙ 14y ago
If the speed of a wave doubles while the wavelength remains constant, the frequency of the wave must also double. This is governed by the equation speed = frequency x wavelength. So, if speed doubles and wavelength remains the same, frequency increases correspondingly.
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What happens to the wavelength of a wave when the frequency of the wave is doubled but the wave speed stays the same?
If the frequency of a wave is doubled while the wave speed remains constant, the wavelength of the wave will be halved. This is because wavelength and frequency are inversely proportional in a wave, so when one doubles, the other is halved to keep the wave speed constant.
What happens to frequency when you double wavelength?
When you double the wavelength of a wave, its frequency is halved. This relationship is described by the formula: speed = wavelength x frequency. Since the speed of the wave remains constant, any change in wavelength must be accompanied by a corresponding change in frequency to maintain this equilibrium.
If the speed of a wave while the wavelength remains the same what happens to the frequency?
If the speed of a wave remains the same while the wavelength stays constant, the frequency also remains unchanged. This is because the relationship between the speed, wavelength, and frequency of a wave is given by the equation speed = frequency x wavelength. So, if two of these values are constant, the third one will be constant as well.
What happens to the speed of a wave if the frequency decreases and the waveleNgth increases?
If the frequency decreases and the wavelength increases, the speed of the wave remains constant. This is because the speed of a wave is determined by the medium it's traveling through, not by its frequency or wavelength.
How will the wavelength of a wave be affected if its speed increases and its frequency remains the same?
If the speed of a wave increases while the frequency remains constant, the wavelength of the wave will also increase. This is because the speed of a wave is directly proportional to its wavelength and frequency according to the formula speed = wavelength x frequency.
If the speed of a wave doubles while the frequency remains the same what happens to the wavelength?
The wavelength stays constant.
What happens when you increase the speed of a wave what happens to the wavelength?
If the frequency remains constant, then the wavelength increases.
What happens to the wavelength of a wave when the frequency of the wave is doubled but the wave speed stays the same?
If the frequency of a wave is doubled while the wave speed remains constant, the wavelength of the wave will be halved. This is because wavelength and frequency are inversely proportional in a wave, so when one doubles, the other is halved to keep the wave speed constant.
What happens to frequency when you double wavelength?
When you double the wavelength of a wave, its frequency is halved. This relationship is described by the formula: speed = wavelength x frequency. Since the speed of the wave remains constant, any change in wavelength must be accompanied by a corresponding change in frequency to maintain this equilibrium.
If the speed of a wave while the wavelength remains the same what happens to the frequency?
If the speed of a wave remains the same while the wavelength stays constant, the frequency also remains unchanged. This is because the relationship between the speed, wavelength, and frequency of a wave is given by the equation speed = frequency x wavelength. So, if two of these values are constant, the third one will be constant as well.
What happens to the frequency of a wave if the wavelength is reduced by half and it stays the same speed?
it doubles
What happens to the speed of a wave if the frequency decreases and the waveleNgth increases?
If the frequency decreases and the wavelength increases, the speed of the wave remains constant. This is because the speed of a wave is determined by the medium it's traveling through, not by its frequency or wavelength.
What happens to the wavelength the if we increase the frequency of vibration?
Provided the speed of the wave remains constant, as we increase the frequency of wave then wavelength decreases. Because frequency and wavelength are inversely related.
When frequency increases what happens to wavelength?
The wavelength gets shorter. If the propagation speed remains the same, the wavelength (L) decreases by the inverse of the frequency f. For electromagnetic waves c = fL is a constant.
How will the wavelength of a wave be affected if its speed increases and its frequency remains the same?
If the speed of a wave increases while the frequency remains constant, the wavelength of the wave will also increase. This is because the speed of a wave is directly proportional to its wavelength and frequency according to the formula speed = wavelength x frequency.
What happens to a wave if the wavelength changes?
If the wavelength of a wave changes, the frequency of the wave will also change because the speed of the wave remains constant in the same medium. This means that if the wavelength increases, the frequency decreases, and vice versa, according to the equation: frequency = speed of the wave / wavelength.
If frequency is tripled what happens to wavelength?
If frequency is tripled, the wavelength will be one-third of its original value. This is because the speed of the wave remains constant, so as frequency increases, wavelength decreases to maintain a constant speed.
