As mentioned by others, you are misinterpreting the frequency of the signal. Let me give an example to clear a few things:

```
Fs = 200; %# sampling rate
t = 0:1/Fs:1-1/Fs; %# time vector of 1 second
f = 6; %# frequency of signal
x = 0.44*sin(2*pi*f*t); %# sine wave
N = length(x); %# length of signal
nfft = N; %# n-point DFT, by default nfft=length(x)
%# (Note: it is faster if nfft is a power of 2)
X = abs(fft(x,nfft)).^2 / nfft; %# square of the magnitude of FFT
cutOff = ceil((nfft+1)/2); %# nyquist frequency
X = X(1:cutOff); %# FFT is symmetric, take first half
X(2:end -1) = 2 * X(2:end -1); %# compensate for the energy of the other half
fr = (0:cutOff-1)*Fs/nfft; %# frequency vector
subplot(211), plot(t, x)
title('Signal (Time Domain)')
xlabel('Time (sec)'), ylabel('Amplitude')
subplot(212), stem(fr, X)
title('Power Spectrum (Frequency Domain)')
xlabel('Frequency (Hz)'), ylabel('Power')
```

Now you can see that the peak in the FFT corresponds to the original frequency of the signal at 6Hz

```
[v idx] = max(X);
fr(idx)
ans =
6
```

We can even check that Parseval's theorem holds:

```
( sum(x.^2) - sum(X) )/nfft < 1e-6
```

### Option 2

Alternatively, we can use the signal processing toolbox functions:

```
%# estimate the power spectral density (PSD) using the periodogram
h = spectrum.periodogram;
hopts = psdopts(h);
set(hopts, 'Fs',Fs, 'NFFT',nfft, 'SpectrumType','onesided')
hpsd = psd(h, x, hopts);
figure, plot(hpsd)
Pxx = hpsd.Data;
fr = hpsd.Frequencies;
[v idx]= max(Pxx)
fr(idx)
avgpower(hpsd)
```

Note that this function uses a logarithmic scale: `plot(fr,10*log10(Pxx))`

instead of `plot(fr,Pxx)`

bitsleft down there). I think that you need to recalibrate the whole thing to a domain that will allowmuchlower frequency domains, like about 0.1 to 0.01hz. – RBarryYoung Jan 21 '10 at 22:19