I need to find the frequency of a sample, stored (in vb) as an array of byte. Sample is a sine wave, known frequency, so I can check), but the numbers are a bit odd, and my mathsfoo is weak. Full range of values 0255. 99% of numbers are in range 235 to 245, but there are some outliers down to 0 and 1, and up to 255 in the remaining 1%. How do I normalise this to remove outliers, (calculating the 235245 interval as it may change with different samples), and how do I then calculate zerocrossings to get the frequency? Apologies if this description is rubbish!

The FFT is probably the best answer, but if you really want to do it by your method, try this: To normalize, first make a histogram to count how many occurrances of each value from 0 to 255. Then throw out X percent of the values from each end with something like:
Now normalize with
Throw away results outside the 128..127 range. Now you can count zero crossings. To make sure you are not fooled by noise, you might want to keep track of the slope over the last several points, and only count crossings when the average slope is going the right way. 


The standard method to attack this problem is to consider one block of data, hopefully at least twice the actual frequency (taking more data isn't bad, so it's good to overestimate a bit), then take the FFT and guess that the frequency corresponds to the largest number in the resulting FFT spectrum. By the way, very similar problems have been asked here before  you could search for those answers as well. 


Use the Fourier transform, it's much more noise insensitive than counting zero crossings Edit: @WaveyDavey I found an F# library to do an FFT: From here
Now I'm sure you can call F# lib from VB.net, C# etc, that should be in their docs 


If I understood well from your description, what you have is a signal which is a combination of a sine plus a constant plus some random glitches. Say, like
where N[n] is the "glitch" noise you want to get rid of. If the glitches are onesample long, you can remove them using a median filter which has to be bigger than the glitch length. On both sides of the glitch. Glitches of length 1, mean you will have enough with a median of 3 samples of length.
The median is computed so: Take the samples of x you want to filter (x[n1],x[n],x[n+1]), sort them, and your output is the middle one. Now that the noise signal is away, get rid of the constant signal. I understand the buffer is of a limited and known length, so you can just compute the mean of the whole buffer. Substract it. Now you have your single sinus signal. You can now compute the fundamental frequency by counting zero crossings. Count the amount of samples above 0 in which the former sample was below 0. The period is the total amount of samples of your buffer divided by this, and the frequency is the oposite (1/x) of the period. 


Although I would go with the majority and say that it seems like what you want is an fft solution (fft algorithm is pretty quick), if fft is not the answer for whatever reason you may want to try fitting a sine curve to the data using a fitting program and reading off the fitted frequency. Using Fityk, you can load the data, and fit to Fityk can be used from a gui, from a commandline for scripting and has a C++ API so could be included in your programs directly. 


I googled for "basic fft". Visual Basic FFT Your question screams FFT, but be careful, using FFT without understanding even a little bit about DSP can lead results that you don't understand or don't know where they come from. 


get the Frequency Analyzer at http://www.relisoft.com/Freeware/index.htm and run it and look at the code. 

