# How do I create band-limited (100-640 Hz) white Gaussian noise?

I would like to create 500 ms of band-limited (100-640 Hz) white Gaussian noise with a (relatively) flat frequency spectrum. The noise should be normally distributed with mean = ~0 and 99.7% of values between ± 2 (i.e. standard deviation = 2/3). My sample rate is 1280 Hz; thus, a new amplitude is generated for each frame.

``````duration  = 500e-3;
rate      = 1280;
amplitude = 2;

npoints   = duration * rate;
noise     = (amplitude/3)* randn( 1, npoints );
% Gaus distributed white noise; mean = ~0; 99.7% of amplitudes between ± 2.
time      = (0:npoints-1) / rate
``````

Could somebody please show me how to filter the signal for the desired result (i.e. 100-640 Hz)? In addition, I was hoping somebody could also show me how to generate a graph to illustrate that the frequency spectrum is indeed flat.

I intend on importing the waveform to Signal (CED) to output as a form of transcranial electrical stimulation.

• I think you can take Fourier tranform of the noise using `fft`, reject the parts (substiture zero for the power) you don't want and take inverse fft using `ifft` of the resulting power spectrum. That should theoretically give you the desired signal. And if you take the `fft` of the resulting signal you should see that power is zero for the rejected frequencies. – Some Guy Jan 25 '17 at 19:40

The following is Matlab implementation of the method alluded to by "Some Guy" in a comment to your question.

``````% In frequency domain, white noise has constant amplitude but uniformly
% distributed random phase. We generate this here. Only half of the
% samples are generated here, the rest are computed later using the complex
% conjugate symmetry property of the FFT (of real signals).
X         = [1; exp(i*2*pi*rand(npoints/2-1,1)); 1]; % X(1) and X(NFFT/2) must be real

% Identify the locations of frequency bins. These will be used to zero out
% the elements of X that are not in the desired band
freqbins  = (0:npoints/2)'/npoints*rate;

% Zero out the frequency components outside the desired band
X(find((freqbins < 100) | (freqbins > 640))) = 0;

% Use the complex conjugate symmetry property of the FFT (for real signals) to
% generate the other half of the frequency-domain signal
X         = [X; conj(flipud(X(2:end-1)))];

% IFFT to convert to time-domain
noise     = real(ifft(X));

% Normalize such that 99.7% of the times signal lies between ±2
noise     = 2*noise/prctile(noise, 99.7);
``````

Statistical analysis of around a million samples generated using this method results in the following spectrum and distribution:

Firstly, the spectrum (using Welch method) is, as expected, flat in the band of interest:

Also, the distribution, estimated using histogram of the signal, matches the Gaussian PDF quite well.

• Thank you! Could you possibly share the code to generate the first figure? I.e. the spectrum? – Hans Jan 26 '17 at 12:19
• @Hans: I used a different function, but you could use the built-in `pwelch` function. Run `figure; pwelch(noise,kaiser(512, 15),256,1024,rate,'power');` The y-axis would be in dB scale, but the information should be pretty much identical. – aksadv Jan 26 '17 at 22:23