How can I modify my code for reading .ogg datasets and apply LSTM classification ?

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Pooyan Mobtahej 2020 年 10 月 19 日

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https://jp.mathworks.com/matlabcentral/answers/619418-how-can-i-modify-my-code-for-reading-ogg-datasets-and-apply-lstm-classification

編集済み: Pooyan Mobtahej 2020 年 10 月 20 日

I need to read .ogg audio files (datasets) in Matlab, get its size for crreating array and and apply LSTM classification. I have 2 classes normal and anomalies. Could you give me a code to be able to read audio files and do classification? You can separate our data into three parts. For example, 80% of all normal and anomaly signals for training (2 classes), 10% for validation, and 10% for testing.

You can create sample sounds .ogg files for your code. And the code shall be able to read different audio datasets.

I have used the following code but you can suggest me proper modification:

normal = zeros(100,1000); %return matrix 
anomaly = zeros(100,1000); 
%assuming you have 100 audio files of 1000 samples each, for both normal and anomaly classes,
%you can use a loop to read the files and split the data for training / Validation / Testing.  
for i = 1:100 
    normal_name = strcat('normal_',num2str(i),'.ogg'); %preserves them in cell arrays
    anomoly_name = strcat('anomaly_',num2str(i),'.ogg'); 
    %files named for anomaly_0 to anomaly_100
    normal(i) = audioread(normal_name); 
    anomaly(i) = audioread(anomaly_name); 
end 
%The above arrays can be split for training/Validation/Testing data set 
%Normal=NNoice
%Anomaly=ANoice
%NNoise = 2*rand([100,1000]) - 1; %changed N
NLabels = repelem(categorical("normal"),100,1);
ANoise = filter(1,[1,-0.999],NNoise);
ANoise = ANoise./max(abs(ANoise),[],'all');
ALabels = repelem(categorical("anomaly"),100,1);
%pNoise = pinknoise([N,1000]);n%removed pink noices
%Labels = repelem(categorical("pink"),1000,1)
sound(NNoise(:,1),fs)
melSpectrogram(NNoise(:,1),fs)
title('Normal')
sound(ANoise(:,1),fs)
melSpectrogram(ANoise(:,1),fs)
title('Anomaly')
%sound(pNoise(:,1),fs)
%melSpectrogram(pNoise(:,1),fs)
%title('Pink Noise')
featuresTrain = extract(aFE,audioTrain);
[numHopsPerSequence,numFeatures,numSignals] = size(featuresTrain)
audioTrain = [NNoise(:,1:80),ANoise(:,1:80)];%change 
labelsTrain = [ALabels(1:80);NLabels(1:80)];
audioValidation = [NNoise(:,81:end),ANoise(:,81:end)]; %changed according 100 samples
labelsValidation = [NLabels(81:end);ALabels(81:end)];
aFE = audioFeatureExtractor("SampleRate",fs, ...
    "SpectralDescriptorInput","melSpectrum", ...
    "spectralCentroid",true, ...
    "spectralSlope",true);
featuresTrain = permute(featuresTrain,[2,1,3]);
featuresTrain = squeeze(num2cell(featuresTrain,[1,2]));
numSignals = numel(featuresTrain)
[numFeatures,numHopsPerSequence] = size(featuresTrain{1})
featuresValidation = extract(aFE,audioValidation);
featuresValidation = permute(featuresValidation,[2,1,3]);
featuresValidation = squeeze(num2cell(featuresValidation,[1,2]));
layers = [ ...
    sequenceInputLayer(numFeatures)
    lstmLayer(50,"OutputMode","last")
    fullyConnectedLayer(numel(unique(labelsTrain)))
    softmaxLayer
    classificationLayer];
options = trainingOptions("adam", ...
    "Shuffle","every-epoch", ...
    "ValidationData",{featuresValidation,labelsValidation}, ...
    "Plots","training-progress", ...
    "Verbose",false);
net = trainNetwork(featuresTrain,labelsTrain,layers,options);
NNoiseTest = 2*rand([100,1]) - 1;
classify(net,extract(aFE,NNoiseTest)')
ANoiseTest = filter(1,[1,-0.999],ANoiseTest);
ANoiseTest= ANoiseTest./max(abs(ANoiseTest),[],'all');
classify(net,extract(aFE,ANoiseTest)')
%pNoiseTest = pinknoise(N);
%classify(net,extract(aFE,pNoiseTest)')