Frequence of a wave is how often a string oscillates on a specific point between crests. So if the speed of the string is lowered, the crests of the wave will pass the point less often, causing lower frequency
Frequency increases.
if the speed increases the frequency increases if the speed decrease the frequency decreases
it gets divided by 10; frequency = speed/wavelength; wavelength = speed/frequency
The speed halves.
The speed halves.
I believe that the speed will remain constant, and the new wavelength will be half of the original wavelength. Speed = (frequency) x (wavelength). This depends on the method used to increase the frequency. If the tension on the string is increased while maintaining the same length (like tuning up a guitar string), then the speed will increase, rather than the wavelength.
Frequency increases.
if the speed increases the frequency increases if the speed decrease the frequency decreases
Vibrations run up and down the string at the sound of speed. The longer the string the lower the frequency of the wave biting both ends, resulting in a lower pitch. Frequency is simply the frequency of the vibrations.
speed = frequency × wave_length → frequency = speed ÷ wave_length = 1.2 m/s ÷ 60 m = 50 Hz.
The speed changes.
it gets divided by 10; frequency = speed/wavelength; wavelength = speed/frequency
Vibrations run up and down the string at the sound of speed. The longer the string the lower the frequency of the wave biting both ends, resulting in a lower pitch. Frequency is simply the frequency of the vibrations.
The pitch is determined by by the frequency in which the string is swinging, which, in turn, is determined by the speed with which a wave can travel through the string. The higher the tension in the string is, the easier it is for a wave to travel through it, and if the speed of the wave increase, so will the frequency, and by default the pitch of the note. And vice versa. If I remember my physics correctly :)
The speed halves.
The speed halves.
The speed halves.