Generate pinknoise with same power as audio

Question

L il 25 Ago 2023

0
Link

Link diretto a questa domanda

https://it.mathworks.com/matlabcentral/answers/2013312-generate-pinknoise-with-same-power-as-audio

Risposto: Mathieu NOE il 28 Ago 2023

Risposta accettata: Mathieu NOE

I need to read an audio file and generate a pinknoise with the same power.

I tought using generatepinknoise(), but the built-in function does not accept a power specification.

Any ideas?

I was trying something based on https://stackoverflow.com/questions/17795675/making-pink-noise-1-f-using-list-of-frequencies, but it dosen't sound anything like pinknoise.

% Generate pinknoise with same power as sound

% get sound (2 channels)

[y,Fs] = audioread('S5.wav');

Y=fft(y);

A1 = abs(Y(:,1)); P1 = mean(A1.^2);

A2 = abs(Y(:,2)); P2 = mean(A2.^2);

N = length(Y); invfnorm = 1./[1:N]';

Anew1 = sqrt(P(:,1)*invfnorm/sum(invfnorm)); Anew2 = sqrt(P(:,2)*invfnorm/sum(invfnorm));

noise = ifft([Anew1 .* exp(1i*angle(Y(:,1))) Anew1 .* exp(1i*angle(Y(:,1))) ] ,'symmetric');

soundsc(noise,Fs)

0 Commenti
Mostra -2 commenti meno recentiNascondi -2 commenti meno recenti

Accedi per commentare.

Accedi per rispondere a questa domanda.

Answer 1

Mathieu NOE il 28 Ago 2023

0
Link

Link diretto a questa risposta

https://it.mathworks.com/matlabcentral/answers/2013312-generate-pinknoise-with-same-power-as-audio#answer_1295162

Apri in MATLAB Online

hello

this would be my suggestion . You don't need to do a fft to get the power of a signal (you can compute it directly in time domain too)

here I tested it on my own audio signal (piano.wav)

% Generate pinknoise with same power as sound
% get sound (2 channels)
[y,Fs] = audioread('S5.wav'); % your file 
% [y,Fs] = audioread('piano.wav'); % mine
[samples,channels] = size(y);
y_power = mean(y.^2,1); % power of signals
pn = mypinknoise(samples);
pn_power = mean(pn.^2); % yes it's 1 because normalized std as explained in the subfunction
% let's assume we want same pink noise power as audio channel of largest
% power
pow_factor = max(y_power)/pn_power;
% now the pink noise signal must be multiplied by the square root of the
% power factor
pn = pn*sqrt(pow_factor);
pn_power = mean(pn.^2); % double check ; now we have same noise power as the audio signal 
% concatenate signals for replay 
out = [y; pn(:)*ones(1,channels)];
soundsc(out,Fs);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function y = mypinknoise(N)
% function: y = pinknoise(N) 
% N - number of samples to be returned in a row vector
% y - a row vector of pink (flicker) noise samples
% The function generates a sequence of pink (flicker) noise samples. 
% In terms of power at a constant bandwidth, pink noise falls off at 3 dB/oct, i.e. 10 dB/dec. 
% difine the length of the vector and
% ensure that the M is even, this will simplify the processing
if rem(N, 2)
    M = N+1;
else
    M = N;
end
% generate white noise
x = randn(1, M);
% FFT
X = fft(x);
% prepare a vector with frequency indexes 
NumUniquePts = M/2 + 1;     % number of the unique fft points
n = 1:NumUniquePts;         % vector with frequency indexes 
% manipulate the left half of the spectrum so the PSD
% is proportional to the frequency by a factor of 1/f, 
% i.e. the amplitudes are proportional to 1/sqrt(f)
X = X(1:NumUniquePts);      
X = X./sqrt(n);
% prepare the right half of the spectrum - a conjugate copy of the left one,
% except the DC component and the Nyquist component - they are unique
% and reconstruct the whole spectrum
X = [X conj(X(end-1:-1:2))];
% IFFT
y = real(ifft(X));
% ensure that the length of y is N
y = y(1, 1:N);
% ensure unity standard deviation and zero mean value
y = y - mean(y);
y = y/std(y, 1);
end