Frequency and distance are directly proportional the higher the frequency the more distance for the sound to dissipate th lower the frequency th shorter the distance for the sound to dissipate
There is no factual relation between these, but there is a common rule known as the Nyquist-Shannon theorem, that states that to reproduce a waveform with only reasonably errors, the sampling frequency must be at least twice the wave frequency.
As genetic distance increases, the recombination frequency first increases in a linear fashion, but then levels off to a frequency of 0.5.
The inverse of frequency is the period, which is the distance between two consecutive crests. If you are given frequency (f), period = 1/f
Miles is a measure of distance, not time. The relation between distance and time is the measurement of how much time it takes an object to travel a specific distance at a specific rate of travel (speed).
edge length divided by the root of sum of squares of the indices of the plane.
The most effective frequency at a specified time for ionosperic propagation of radio waves between two specified points: also known as Frequency Optimum Traffic; Optimum Traffic Frequency
the relation between frequency and time period is ''t=1/f''
Frequency = 1 / period
Time of period=1/frequency
frequency = speed of light/wavelength
yes!
voltage and frequency both are different quantity.. don't mix it...
the lower the frequency the lower the pitch; higher pitch lower frequency
If you mean the distance along the direction of propagation, that's a half-wavelength. If you mean the distance perpendicular to propagation (i.e. the "height" of the wave), it's the amplitude.
There is no factual relation between these, but there is a common rule known as the Nyquist-Shannon theorem, that states that to reproduce a waveform with only reasonably errors, the sampling frequency must be at least twice the wave frequency.
There is no such equation. The main reason is that there is no relationship between current and frequency.
For any wave, frequency x wavelength = speed of the wave.