This commit is contained in:
Arthur Lu 2021-12-10 18:19:53 -08:00
commit f4e1a0e4de
2 changed files with 15 additions and 56 deletions

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@ -10,41 +10,20 @@ function output_x = AnuragDampenTarget(x, Fs,LOW, MID, HIGH)
% Detailed explanation goes here % Detailed explanation goes here
TARGET = MID; TARGET = MID;
AreaPercentage = 0.15; AreaPercentage = 0.15;
[dim,len] = size(x); %get length of the input len = length(x); %get length of the input
F = Fs * ((-len/2) : ((len/2) - 1)) / len; F = Fs * ((-len/2) : ((len/2) - 1)) / len;
lenf = length(F); lenf = length(F);
Mod_Freq = ifft(fft(x)); %Fourier Transform of the input signal Mod_Freq = fftshift(fft(x)); %Fourier Transform of the input signal
output = zeros([1,lenf]); % zero array of size Mod_freq output = zeros([1,lenf]); % zero array of size Mod_freq
if(dim == 2) %check for dual channel audio
F = [F;F];
output = [output;output];
end
%set the bounds %set the bounds
lowerBound = (1-AreaPercentage) * TARGET; lowerBound = (1-AreaPercentage) * TARGET;
upperBound = (1+AreaPercentage) * TARGET; upperBound = (1+AreaPercentage) * TARGET;
%% Dampen the target frequencies and maintain the others %% Dampen the target frequencies and maintain the others
if(dim == 2) %iterate through both channels if track is dual channel for n = 1:lenf
for n = 1:lenf if ((lowerBound < abs(F(n))) && abs(F(n)) < upperBound)
if ((lowerBound < abs(F(1,n))) && abs(F(1,n)) < upperBound) output(n) = 0.5;
output(1,n) = 1; else
else output(n) = 1;
output(1,n) = 0.5;
end
end
for n = 1:lenf
if ((lowerBound < abs(F(2,n))) && abs(F(2,n)) < upperBound)
output(2,n) = 1;
else
output(2,n) = .5;
end
end
else %iterate onnly once for monochannel
for n = 1:lenf
if ((lowerBound < abs(F(n))) && abs(F(n)) < upperBound)
output(n) = 1;
else
output(n) = .5;
end
end end
end end
%%Filter the original signal and transform %%Filter the original signal and transform

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@ -10,41 +10,21 @@ function output_x = AnuragEnchanceTarget(x, Fs,LOW, MID, HIGH)
% Detailed explanation goes here % Detailed explanation goes here
TARGET = MID; TARGET = MID;
AreaPercentage = 0.15; AreaPercentage = 0.15;
[dim,len] = size(x); %get length of the input len = length(x); %get length of the input
F = Fs * ((-len/2) : ((len/2) - 1)) / len; F = Fs * ((-len/2) : ((len/2) - 1)) / len;
lenf = length(F); lenf = length(F);
Mod_Freq = ifft(fft(x)); %Fourier Transform of the input signal Mod_Freq = fftshift(fft(x)); %Fourier Transform of the input signal
output = zeros([1,lenf]); % zero array of size Mod_freq output = zeros([1,lenf]); % zero array of size Mod_freq
if(dim == 2) %check for dual channel audio
F = [F;F];
output = [output;output];
end
%set the bounds %set the bounds
lowerBound = (1-AreaPercentage) * TARGET; lowerBound = (1-AreaPercentage) * TARGET;
upperBound = (1+AreaPercentage) * TARGET; upperBound = (1+AreaPercentage) * TARGET;
%% Amplify the target frequencies and dampen the others %% Amplify the target frequencies and dampen the others
if(dim == 2) %iterate through both channels if track is dual channel for n = 1:lenf
for n = 1:lenf if ((lowerBound < abs(F(n))) && abs(F(n)) < upperBound)
if ((lowerBound < abs(F(1,n))) && abs(F(1,n)) < upperBound) output(n) = 2;
output(1,n) = 2; else
else output(n) = 0.75;
output(1,n) = 0.75;
end
end
for n = 1:lenf
if ((lowerBound < abs(F(2,n))) && abs(F(2,n)) < upperBound)
output(2,n) = 2;
else
output(2,n) = 0.75;
end
end
else %iterate onnly once for monochannel
for n = 1:lenf
if ((lowerBound < abs(F(n))) && abs(F(n)) < upperBound)
output(n) = 2;
else
output(n) = 0.75;
end
end end
end end
%%Filter the original signal and transform %%Filter the original signal and transform