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An object vibrating relatively slowly produces sound waves that have low frequency and long wavelength.
This question can't be answered as asked. A string vibrating at its fundamental frequency has nothing to do with the speed of the produced sound through air, or any other medium. Different mediums transmit sound at different speeds. The formula for wavelength is L = S/F, were L is the wavelength, S is the speed through the medium and F is the frequency. Therefore, the wavelength depends on the speed of sound through the medium and directly proportional to the speed and inversely proportional to the frequency.
When frequency of a vibrating body becomes equal to its natural frequency the body starts vibrating vigorously due to resonance.
The frequency of a radio wave compares to the frequency of the vibrating electrons that make it because the frequency of a radio wave is proportional to the frequency of the vibrating electrons that make it.
More energy would be transferred in the wave, so a sound wave would get louder and a light wave would get brighter. The wavespeed, frequency, and wavelength of the wave will remain the same.
The wavelength decreases. Frequency and wavelength are inversely related.
Waves are generated by some vibrating object. The frequency with which this object vibrates will be the frequency of the wave. The speed depends upon the medium through which the wave is propagated, and the wavelength then is the mathematical result of the speed divided by the frequency.
An object vibrating relatively slowly produces sound waves that have low frequency and long wavelength.
This question can't be answered as asked. A string vibrating at its fundamental frequency has nothing to do with the speed of the produced sound through air, or any other medium. Different mediums transmit sound at different speeds. The formula for wavelength is L = S/F, were L is the wavelength, S is the speed through the medium and F is the frequency. Therefore, the wavelength depends on the speed of sound through the medium and directly proportional to the speed and inversely proportional to the frequency.
If it's vibrating in air, then the wavelength of the sound it produces is(343) divided by (the tuning fork's frequency) meters
it is a classical theory which gives us the relationship between energy and no. of vibrating particles and temperature,frequency and wavelength.
Assuming this happens in phase, the pitch of the sound will increase. If only one of the loudspeakers does this, they'll be out of phase, which will initially sound like a slow pulsed beat, but eventually will form a chord.
When frequency of a vibrating body becomes equal to its natural frequency the body starts vibrating vigorously due to resonance.
The frequency of a radio wave compares to the frequency of the vibrating electrons that make it because the frequency of a radio wave is proportional to the frequency of the vibrating electrons that make it.
More energy would be transferred in the wave, so a sound wave would get louder and a light wave would get brighter. The wavespeed, frequency, and wavelength of the wave will remain the same.
frequency is the inverse of time: 1/f=t therefore if you increase frequency by 3 the time (or cycle) will be 1/3
As all EM waves do a constant speed ('c'). If the frequency increases (i.e. the waves are more frequent) the distance between the wave peaks (wavelength) must reduce. For visible light waves, this produces a 'blue shift.'