Microphone receives sound that has a specific frequency. I need to know frequency of sound from microphone. I using NAudio library on C#
closed as not a real question by Paolo Moretti, Sani Huttunen, CodeCaster, jonsca, lc. Oct 22 '12 at 9:42
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This is a matter of spectral analysis in the frequency domain. The discrete fourier transform (DFT) depicts the overall frequency content of a discrete (digital) signal - depicting amplitude vs frequency. This will give you a rather large spectrum/range (depending on your sample rate) from which you can determine which frequency or frequencies or more prominent than others.
I've never used NAudio, but there is an excellent C library you can use to calculate the DFT, called FFTW ("the fastest fourier transform in the west") =). You'll find information at: http://www.fftw.org/
If you know the specific frequency in question and only wish to determine its overall amplitude in the signal, than a DFT may not be the best way to go since there are other less cpu-intensive methods available.
Remember #1: A signal can never contain higher frequencies than those corresponding to half of your sample rate as determined by the Nyquist theorem. Hence, if you wish to be able to detect frequencies up to 20kHz, you must sample the sound with a sample rate of atleast 40kHz, preferably more.
Remember #2: The DFT requires the sample rate to be constant. If it isn't, you need to perform equidistant resampling of your signal (linear interpolation is sufficient) before your calculate the DFT.
I'm not too sure what you want to do, but the FT is a great tool to visualize the frequency content of your signal since the fourier transform will depict all frequencies in your signal - even the frequencies that you may not be interested in, so that you can decide what is "information" and what is "noise".
you start off with your audio signal, two arrays of equal length, one containing time samples and one containing amplitude samples, (every amplitude sample has a corresponding time sample in the other array). Lets assume your time array has the following few values 0, 0.001, 0.002, 0.003 ... From that you can conclude that your audio signal has been sampled at a sampling rate of 1/0.001 = 1000 Hz. The FFT needs you to specify the amplitude values and the sample rate (the sample rate is what is important, not the entire array of time values). The FFT will return a new array of amplitude values corresponding to the frequency values. Whats your frequency values? well, since you know your sampling rate to be 1000 Hz, and remembering the nyqvist theorem, your frequency values will be an array with values from 0 to 500 Hz with the same number of values as the array the FFT method returned. (The FFT method may also return the frequency values, depending on the method used).
Here is an example of how useful the FFT can be to visually find information from a signal. It's an example in MATLAB. http://www.mathworks.se/help/matlab/ref/fft.html Due to its definition, the FFT works faster if the number of values in the amplitude array is a power of 2, thats why they, in the example above, specify their FFT to return so many values.
HOW TO COME TO A CONCLUSION:
If you let your microphone record 3-4 audio signals, and you depict the frequency content of these four signals into four individual graphs, you will find that the amplitudes differ abit. This is because the four signals will not be identical in sound, and there is always noise inherent in any signal (from the surroundings and the hardware itself). Therefore, what you want to do is to take the average of two or more FFT signals to remove noise and get a more accurate represention of the frequency content. Depending on your application, this may not be possible if the sound you are capturing is noticably changing rapidly over time (for example speech, or music). Averaging is thus only useful if all the signals to be averaged are pretty much equal in sound (four seperate recordings of "the same thing"). Just to clarify, from four time-domain signals, you want to create four frequency domain signals (using a FFT method), and then calculate the average of the four frequency-domain signals into a single averaged frequency-domain signal. This will remove noise and give you a better representation.
AN ALTERNATIVE SOLUTION:
If you know that your signal is supposed to contain a certain number of dominant frequencies (not too many) and these are the only ones your are interesting in, then I would recommend that you use Pisarenko's harmonic decomposition (PHD) or Multiple signal classification (MUSIC, nice abbreviation!) to find these frequencies (and their corresponding amplitude values). This is less intensive computationally than the FFT. If you KNOW the signal contains 3 dominant frequencies, pisarenko will return the frequency values for these, but the FFT reveals much more information, allowing you come to more conclusions.
I'm not an expert on audio, but I think you should run the sampled audio through an FFT to get the frequencies of the sound.