I would classify it as a 'short wave' radio wave. Tuning my handy-dandy receiver
to that frequency, I would expect to hear one of the standard time and frequency
stations operated by N.I.S.T., and I would seize upon the opportunity to calibrate
both my wrist watch and the dial on my receiver.
Infrared.
10 to the power 7 Hz is 10 MHz, so that is HF (high frequency); this range of radio waves goes from 3 to 30 MHz.
The frequency of the source that produced the wave.
10 to the power 7 Hz is 10 MHz, so that is HF (high frequency); this range of radio waves goes from 3 to 30 MHz.
If you increase the frequency of a periodic wave, the wave length decreases proportionally.
Infrared.
10 to the power 7 Hz is 10 MHz, so that is HF (high frequency); this range of radio waves goes from 3 to 30 MHz.
10 to the power 7 Hz is 10 MHz, so that is HF (high frequency); this range of radio waves goes from 3 to 30 MHz.
10 to the power 7 Hz is 10 MHz, so that is HF (high frequency); this range of radio waves goes from 3 to 30 MHz.
The frequency of the source that produced the wave.
10 to the power 7 Hz is 10 MHz, so that is HF (high frequency); this range of radio waves goes from 3 to 30 MHz.
If you increase the frequency of a periodic wave, the wave length decreases proportionally.
It's double the frequency of the power source.
The wave length would necessarily be one half. The speed would remain the same independent of the frequency.
Space wave propagation frequency is nothing special, it is the same frequency of the wave in question, for example WLAN Wifi produces 5.2 GHz radio wave from your computer or from router, so that would be the the space wave propagation frequency in question
If the power is constant, the amplitude will decrease.
The cork will move up and down with the wave, since the wave is a transverse wave. I would think that the frequency should be the same as the wave.