sustaining_gazes/matlab_version/face_validation/DeepLearnToolbox/README.md


DeepLearnToolbox
================

A Matlab toolbox for Deep Learning.

Deep Learning is a new subfield of machine learning that focuses on learning deep hierarchical models of data.
It is inspired by the human brain's apparent deep (layered, hierarchical) architecture.
A good overview of the theory of Deep Learning theory is
[Learning Deep Architectures for AI](http://www.iro.umontreal.ca/~bengioy/papers/ftml_book.pdf)

For a more informal introduction, see the following videos by Geoffrey Hinton and Andrew Ng.

* [The Next Generation of Neural Networks](http://www.youtube.com/watch?v=AyzOUbkUf3M) (Hinton, 2007)
* [Recent Developments in Deep Learning](http://www.youtube.com/watch?v=VdIURAu1-aU) (Hinton, 2010)
* [Unsupervised Feature Learning and Deep Learning](http://www.youtube.com/watch?v=ZmNOAtZIgIk) (Ng, 2011)

If you use this toolbox in your research please cite [Prediction as a candidate for learning deep hierarchical models of data](http://www2.imm.dtu.dk/pubdb/views/publication_details.php?id=6284)

```
@MASTERSTHESIS\{IMM2012-06284,
    author       = "R. B. Palm",
    title        = "Prediction as a candidate for learning deep hierarchical models of data",
    year         = "2012",
}
```

Contact: rasmusbergpalm at gmail dot com

Directories included in the toolbox
-----------------------------------

`NN/`   - A library for Feedforward Backpropagation Neural Networks

`CNN/`  - A library for Convolutional Neural Networks

`DBN/`  - A library for Deep Belief Networks

`SAE/`  - A library for Stacked Auto-Encoders

`CAE/` - A library for Convolutional Auto-Encoders

`util/` - Utility functions used by the libraries

`data/` - Data used by the examples

`tests/` - unit tests to verify toolbox is working

For references on each library check REFS.md

Setup
-----

1. Download.
2. addpath(genpath('DeepLearnToolbox'));

Known errors
------------------------------

`test_cnn_gradients_are_numerically_correct` fails on Octave because of a bug in Octave's convn implementation. See http://savannah.gnu.org/bugs/?39314

`test_example_CNN` fails in Octave for the same reason.
Example: Deep Belief Network
---------------------
```matlab

function test_example_DBN
load mnist_uint8;

train_x = double(train_x) / 255;
test_x  = double(test_x)  / 255;
train_y = double(train_y);
test_y  = double(test_y);

%%  ex1 train a 100 hidden unit RBM and visualize its weights
rand('state',0)
dbn.sizes = [100];
opts.numepochs =   1;
opts.batchsize = 100;
opts.momentum  =   0;
opts.alpha     =   1;
dbn = dbnsetup(dbn, train_x, opts);
dbn = dbntrain(dbn, train_x, opts);
figure; visualize(dbn.rbm{1}.W');   %  Visualize the RBM weights

%%  ex2 train a 100-100 hidden unit DBN and use its weights to initialize a NN
rand('state',0)
%train dbn
dbn.sizes = [100 100];
opts.numepochs =   1;
opts.batchsize = 100;
opts.momentum  =   0;
opts.alpha     =   1;
dbn = dbnsetup(dbn, train_x, opts);
dbn = dbntrain(dbn, train_x, opts);

%unfold dbn to nn
nn = dbnunfoldtonn(dbn, 10);
nn.activation_function = 'sigm';

%train nn
opts.numepochs =  1;
opts.batchsize = 100;
nn = nntrain(nn, train_x, train_y, opts);
[er, bad] = nntest(nn, test_x, test_y);

assert(er < 0.10, 'Too big error');

```


Example: Stacked Auto-Encoders
---------------------
```matlab

function test_example_SAE
load mnist_uint8;

train_x = double(train_x)/255;
test_x  = double(test_x)/255;
train_y = double(train_y);
test_y  = double(test_y);

%%  ex1 train a 100 hidden unit SDAE and use it to initialize a FFNN
%  Setup and train a stacked denoising autoencoder (SDAE)
rand('state',0)
sae = saesetup([784 100]);
sae.ae{1}.activation_function       = 'sigm';
sae.ae{1}.learningRate              = 1;
sae.ae{1}.inputZeroMaskedFraction   = 0.5;
opts.numepochs =   1;
opts.batchsize = 100;
sae = saetrain(sae, train_x, opts);
visualize(sae.ae{1}.W{1}(:,2:end)')

% Use the SDAE to initialize a FFNN
nn = nnsetup([784 100 10]);
nn.activation_function              = 'sigm';
nn.learningRate                     = 1;
nn.W{1} = sae.ae{1}.W{1};

% Train the FFNN
opts.numepochs =   1;
opts.batchsize = 100;
nn = nntrain(nn, train_x, train_y, opts);
[er, bad] = nntest(nn, test_x, test_y);
assert(er < 0.16, 'Too big error');

```


Example: Convolutional Neural Nets
---------------------
```matlab

function test_example_CNN
load mnist_uint8;

train_x = double(reshape(train_x',28,28,60000))/255;
test_x = double(reshape(test_x',28,28,10000))/255;
train_y = double(train_y');
test_y = double(test_y');

%% ex1 Train a 6c-2s-12c-2s Convolutional neural network 
%will run 1 epoch in about 200 second and get around 11% error. 
%With 100 epochs you'll get around 1.2% error
rand('state',0)
cnn.layers = {
    struct('type', 'i') %input layer
    struct('type', 'c', 'outputmaps', 6, 'kernelsize', 5) %convolution layer
    struct('type', 's', 'scale', 2) %sub sampling layer
    struct('type', 'c', 'outputmaps', 12, 'kernelsize', 5) %convolution layer
    struct('type', 's', 'scale', 2) %subsampling layer
};
cnn = cnnsetup(cnn, train_x, train_y);

opts.alpha = 1;
opts.batchsize = 50;
opts.numepochs = 1;

cnn = cnntrain(cnn, train_x, train_y, opts);

[er, bad] = cnntest(cnn, test_x, test_y);

%plot mean squared error
figure; plot(cnn.rL);

assert(er<0.12, 'Too big error');

```


Example: Neural Networks
---------------------
```matlab

function test_example_NN
load mnist_uint8;

train_x = double(train_x) / 255;
test_x  = double(test_x)  / 255;
train_y = double(train_y);
test_y  = double(test_y);

% normalize
[train_x, mu, sigma] = zscore(train_x);
test_x = normalize(test_x, mu, sigma);

%% ex1 vanilla neural net
rand('state',0)
nn = nnsetup([784 100 10]);
opts.numepochs =  1;   %  Number of full sweeps through data
opts.batchsize = 100;  %  Take a mean gradient step over this many samples
[nn, L] = nntrain(nn, train_x, train_y, opts);

[er, bad] = nntest(nn, test_x, test_y);

assert(er < 0.08, 'Too big error');

%% ex2 neural net with L2 weight decay
rand('state',0)
nn = nnsetup([784 100 10]);

nn.weightPenaltyL2 = 1e-4;  %  L2 weight decay
opts.numepochs =  1;        %  Number of full sweeps through data
opts.batchsize = 100;       %  Take a mean gradient step over this many samples

nn = nntrain(nn, train_x, train_y, opts);

[er, bad] = nntest(nn, test_x, test_y);
assert(er < 0.1, 'Too big error');


%% ex3 neural net with dropout
rand('state',0)
nn = nnsetup([784 100 10]);

nn.dropoutFraction = 0.5;   %  Dropout fraction 
opts.numepochs =  1;        %  Number of full sweeps through data
opts.batchsize = 100;       %  Take a mean gradient step over this many samples

nn = nntrain(nn, train_x, train_y, opts);

[er, bad] = nntest(nn, test_x, test_y);
assert(er < 0.1, 'Too big error');

%% ex4 neural net with sigmoid activation function
rand('state',0)
nn = nnsetup([784 100 10]);

nn.activation_function = 'sigm';    %  Sigmoid activation function
nn.learningRate = 1;                %  Sigm require a lower learning rate
opts.numepochs =  1;                %  Number of full sweeps through data
opts.batchsize = 100;               %  Take a mean gradient step over this many samples

nn = nntrain(nn, train_x, train_y, opts);

[er, bad] = nntest(nn, test_x, test_y);
assert(er < 0.1, 'Too big error');

%% ex5 plotting functionality
rand('state',0)
nn = nnsetup([784 20 10]);
opts.numepochs         = 5;            %  Number of full sweeps through data
nn.output              = 'softmax';    %  use softmax output
opts.batchsize         = 1000;         %  Take a mean gradient step over this many samples
opts.plot              = 1;            %  enable plotting

nn = nntrain(nn, train_x, train_y, opts);

[er, bad] = nntest(nn, test_x, test_y);
assert(er < 0.1, 'Too big error');

%% ex6 neural net with sigmoid activation and plotting of validation and training error
% split training data into training and validation data
vx   = train_x(1:10000,:);
tx = train_x(10001:end,:);
vy   = train_y(1:10000,:);
ty = train_y(10001:end,:);

rand('state',0)
nn                      = nnsetup([784 20 10]);     
nn.output               = 'softmax';                   %  use softmax output
opts.numepochs          = 5;                           %  Number of full sweeps through data
opts.batchsize          = 1000;                        %  Take a mean gradient step over this many samples
opts.plot               = 1;                           %  enable plotting
nn = nntrain(nn, tx, ty, opts, vx, vy);                %  nntrain takes validation set as last two arguments (optionally)

[er, bad] = nntest(nn, test_x, test_y);
assert(er < 0.1, 'Too big error');

```


[![Bitdeli Badge](https://d2weczhvl823v0.cloudfront.net/rasmusbergpalm/deeplearntoolbox/trend.png)](https://bitdeli.com/free "Bitdeli Badge")
Master commit of OpenFace. 2016-04-28 21:40:36 +02:00
			`DeepLearnToolbox`
			`================`

			`A Matlab toolbox for Deep Learning.`

			`Deep Learning is a new subfield of machine learning that focuses on learning deep hierarchical models of data.`
			`It is inspired by the human brain's apparent deep (layered, hierarchical) architecture.`
			`A good overview of the theory of Deep Learning theory is`
			`[Learning Deep Architectures for AI](http://www.iro.umontreal.ca/~bengioy/papers/ftml_book.pdf)`

			`For a more informal introduction, see the following videos by Geoffrey Hinton and Andrew Ng.`

			`* [The Next Generation of Neural Networks](http://www.youtube.com/watch?v=AyzOUbkUf3M) (Hinton, 2007)`
			`* [Recent Developments in Deep Learning](http://www.youtube.com/watch?v=VdIURAu1-aU) (Hinton, 2010)`
			`* [Unsupervised Feature Learning and Deep Learning](http://www.youtube.com/watch?v=ZmNOAtZIgIk) (Ng, 2011)`

			`If you use this toolbox in your research please cite [Prediction as a candidate for learning deep hierarchical models of data](http://www2.imm.dtu.dk/pubdb/views/publication_details.php?id=6284)`

			```
			`@MASTERSTHESIS\{IMM2012-06284,`
			`author = "R. B. Palm",`
			`title = "Prediction as a candidate for learning deep hierarchical models of data",`
			`year = "2012",`
			`}`
			```

			`Contact: rasmusbergpalm at gmail dot com`

			`Directories included in the toolbox`
			`-----------------------------------`

			`NN/` - A library for Feedforward Backpropagation Neural Networks

			`CNN/` - A library for Convolutional Neural Networks

			`DBN/` - A library for Deep Belief Networks

			`SAE/` - A library for Stacked Auto-Encoders

			`CAE/` - A library for Convolutional Auto-Encoders

			`util/` - Utility functions used by the libraries

			`data/` - Data used by the examples

			`tests/` - unit tests to verify toolbox is working

			`For references on each library check REFS.md`

			`Setup`
			`-----`

			`1. Download.`
			`2. addpath(genpath('DeepLearnToolbox'));`

			`Known errors`
			`------------------------------`

			`test_cnn_gradients_are_numerically_correct` fails on Octave because of a bug in Octave's convn implementation. See http://savannah.gnu.org/bugs/?39314

			`test_example_CNN` fails in Octave for the same reason.
			`Example: Deep Belief Network`
			`---------------------`
			```matlab

			`function test_example_DBN`
			`load mnist_uint8;`

			`train_x = double(train_x) / 255;`
			`test_x = double(test_x) / 255;`
			`train_y = double(train_y);`
			`test_y = double(test_y);`

			`%% ex1 train a 100 hidden unit RBM and visualize its weights`
			`rand('state',0)`
			`dbn.sizes = [100];`
			`opts.numepochs = 1;`
			`opts.batchsize = 100;`
			`opts.momentum = 0;`
			`opts.alpha = 1;`
			`dbn = dbnsetup(dbn, train_x, opts);`
			`dbn = dbntrain(dbn, train_x, opts);`
			`figure; visualize(dbn.rbm{1}.W'); % Visualize the RBM weights`

			`%% ex2 train a 100-100 hidden unit DBN and use its weights to initialize a NN`
			`rand('state',0)`
			`%train dbn`
			`dbn.sizes = [100 100];`
			`opts.numepochs = 1;`
			`opts.batchsize = 100;`
			`opts.momentum = 0;`
			`opts.alpha = 1;`
			`dbn = dbnsetup(dbn, train_x, opts);`
			`dbn = dbntrain(dbn, train_x, opts);`

			`%unfold dbn to nn`
			`nn = dbnunfoldtonn(dbn, 10);`
			`nn.activation_function = 'sigm';`

			`%train nn`
			`opts.numepochs = 1;`
			`opts.batchsize = 100;`
			`nn = nntrain(nn, train_x, train_y, opts);`
			`[er, bad] = nntest(nn, test_x, test_y);`

			`assert(er < 0.10, 'Too big error');`

			```


			`Example: Stacked Auto-Encoders`
			`---------------------`
			```matlab

			`function test_example_SAE`
			`load mnist_uint8;`

			`train_x = double(train_x)/255;`
			`test_x = double(test_x)/255;`
			`train_y = double(train_y);`
			`test_y = double(test_y);`

			`%% ex1 train a 100 hidden unit SDAE and use it to initialize a FFNN`
			`% Setup and train a stacked denoising autoencoder (SDAE)`
			`rand('state',0)`
			`sae = saesetup([784 100]);`
			`sae.ae{1}.activation_function = 'sigm';`
			`sae.ae{1}.learningRate = 1;`
			`sae.ae{1}.inputZeroMaskedFraction = 0.5;`
			`opts.numepochs = 1;`
			`opts.batchsize = 100;`
			`sae = saetrain(sae, train_x, opts);`
			`visualize(sae.ae{1}.W{1}(:,2:end)')`

			`% Use the SDAE to initialize a FFNN`
			`nn = nnsetup([784 100 10]);`
			`nn.activation_function = 'sigm';`
			`nn.learningRate = 1;`
			`nn.W{1} = sae.ae{1}.W{1};`

			`% Train the FFNN`
			`opts.numepochs = 1;`
			`opts.batchsize = 100;`
			`nn = nntrain(nn, train_x, train_y, opts);`
			`[er, bad] = nntest(nn, test_x, test_y);`
			`assert(er < 0.16, 'Too big error');`

			```


			`Example: Convolutional Neural Nets`
			`---------------------`
			```matlab

			`function test_example_CNN`
			`load mnist_uint8;`

			`train_x = double(reshape(train_x',28,28,60000))/255;`
			`test_x = double(reshape(test_x',28,28,10000))/255;`
			`train_y = double(train_y');`
			`test_y = double(test_y');`

			`%% ex1 Train a 6c-2s-12c-2s Convolutional neural network`
			`%will run 1 epoch in about 200 second and get around 11% error.`
			`%With 100 epochs you'll get around 1.2% error`
			`rand('state',0)`
			`cnn.layers = {`
			`struct('type', 'i') %input layer`
			`struct('type', 'c', 'outputmaps', 6, 'kernelsize', 5) %convolution layer`
			`struct('type', 's', 'scale', 2) %sub sampling layer`
			`struct('type', 'c', 'outputmaps', 12, 'kernelsize', 5) %convolution layer`
			`struct('type', 's', 'scale', 2) %subsampling layer`
			`};`
			`cnn = cnnsetup(cnn, train_x, train_y);`

			`opts.alpha = 1;`
			`opts.batchsize = 50;`
			`opts.numepochs = 1;`

			`cnn = cnntrain(cnn, train_x, train_y, opts);`

			`[er, bad] = cnntest(cnn, test_x, test_y);`

			`%plot mean squared error`
			`figure; plot(cnn.rL);`

			`assert(er<0.12, 'Too big error');`

			```


			`Example: Neural Networks`
			`---------------------`
			```matlab

			`function test_example_NN`
			`load mnist_uint8;`

			`train_x = double(train_x) / 255;`
			`test_x = double(test_x) / 255;`
			`train_y = double(train_y);`
			`test_y = double(test_y);`

			`% normalize`
			`[train_x, mu, sigma] = zscore(train_x);`
			`test_x = normalize(test_x, mu, sigma);`

			`%% ex1 vanilla neural net`
			`rand('state',0)`
			`nn = nnsetup([784 100 10]);`
			`opts.numepochs = 1; % Number of full sweeps through data`
			`opts.batchsize = 100; % Take a mean gradient step over this many samples`
			`[nn, L] = nntrain(nn, train_x, train_y, opts);`

			`[er, bad] = nntest(nn, test_x, test_y);`

			`assert(er < 0.08, 'Too big error');`

			`%% ex2 neural net with L2 weight decay`
			`rand('state',0)`
			`nn = nnsetup([784 100 10]);`

			`nn.weightPenaltyL2 = 1e-4; % L2 weight decay`
			`opts.numepochs = 1; % Number of full sweeps through data`
			`opts.batchsize = 100; % Take a mean gradient step over this many samples`

			`nn = nntrain(nn, train_x, train_y, opts);`

			`[er, bad] = nntest(nn, test_x, test_y);`
			`assert(er < 0.1, 'Too big error');`


			`%% ex3 neural net with dropout`
			`rand('state',0)`
			`nn = nnsetup([784 100 10]);`

			`nn.dropoutFraction = 0.5; % Dropout fraction`
			`opts.numepochs = 1; % Number of full sweeps through data`
			`opts.batchsize = 100; % Take a mean gradient step over this many samples`

			`nn = nntrain(nn, train_x, train_y, opts);`

			`[er, bad] = nntest(nn, test_x, test_y);`
			`assert(er < 0.1, 'Too big error');`

			`%% ex4 neural net with sigmoid activation function`
			`rand('state',0)`
			`nn = nnsetup([784 100 10]);`

			`nn.activation_function = 'sigm'; % Sigmoid activation function`
			`nn.learningRate = 1; % Sigm require a lower learning rate`
			`opts.numepochs = 1; % Number of full sweeps through data`
			`opts.batchsize = 100; % Take a mean gradient step over this many samples`

			`nn = nntrain(nn, train_x, train_y, opts);`

			`[er, bad] = nntest(nn, test_x, test_y);`
			`assert(er < 0.1, 'Too big error');`

			`%% ex5 plotting functionality`
			`rand('state',0)`
			`nn = nnsetup([784 20 10]);`
			`opts.numepochs = 5; % Number of full sweeps through data`
			`nn.output = 'softmax'; % use softmax output`
			`opts.batchsize = 1000; % Take a mean gradient step over this many samples`
			`opts.plot = 1; % enable plotting`

			`nn = nntrain(nn, train_x, train_y, opts);`

			`[er, bad] = nntest(nn, test_x, test_y);`
			`assert(er < 0.1, 'Too big error');`

			`%% ex6 neural net with sigmoid activation and plotting of validation and training error`
			`% split training data into training and validation data`
			`vx = train_x(1:10000,:);`
			`tx = train_x(10001:end,:);`
			`vy = train_y(1:10000,:);`
			`ty = train_y(10001:end,:);`

			`rand('state',0)`
			`nn = nnsetup([784 20 10]);`
			`nn.output = 'softmax'; % use softmax output`
			`opts.numepochs = 5; % Number of full sweeps through data`
			`opts.batchsize = 1000; % Take a mean gradient step over this many samples`
			`opts.plot = 1; % enable plotting`
			`nn = nntrain(nn, tx, ty, opts, vx, vy); % nntrain takes validation set as last two arguments (optionally)`

			`[er, bad] = nntest(nn, test_x, test_y);`
			`assert(er < 0.1, 'Too big error');`

			```




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