线性解码器(Linear Decoder)
前面第一章提到稀疏自编码器(http://www.cnblogs.com/bzjia-blog/p/SparseAutoencoder.html)的三层网络结构,我们要满足最后一层的输出:a(3)≈a(1)(即输入值x)的近似重建。考虑到在最后一层的a(3)=f(z(3)),这里f一般用sigmoid函数或tanh函数等非线性函数,而将输出界定在一个范围内(比如sigmoid函数使结果在[0,1]中)。这对于有些数据组,例如MNIST手写数字库中其输入输出范围符合极佳,但并不是所有的情况都满足这个条件。例如,若采用PCA白化,输入将不再限制于[0,1],虽可通过缩放数据来确保其符合特定范围内,但显然,这不是最好的方式。
因此,这里提到的Linear Decoder就是通过在最后一层用激励函数:a(3) = z(3)(也即f(z)=z)来实现。这里要注意到,只是在最后一层用这个激励函数,其他隐层的激励函数仍然是sigmoid函数或者tanh函数,我们仅在输出层中使用线性激励机制。
这样一来,在求梯度的时候,公式:
就应该改成:
这个是显然的,因为f'(z)=1。其他层的都不需要改变。
练习:
这里讲义给出了一个练习,基本跟稀疏自编码一样,只有几处需要稍微改动一下。
linearDecoderExercise.m
%% CS294A/CS294W Linear Decoder Exercise % Instructions % ------------ % % This file contains code that helps you get started on the % linear decoder exericse. For this exercise, you will only need to modify % the code in sparseAutoencoderLinearCost.m. You will not need to modify % any code in this file. %%====================================================================== %% STEP 0: Initialization % Here we initialize some parameters used for the exercise. imageChannels = 3; % number of channels (rgb, so 3) patchDim = 8; % patch dimension numPatches = 100000; % number of patches visibleSize = patchDim * patchDim * imageChannels; % number of input units outputSize = visibleSize; % number of output units hiddenSize = 400; % number of hidden units sparsityParam = 0.035; % desired average activation of the hidden units. lambda = 3e-3; % weight decay parameter beta = 5; % weight of sparsity penalty term epsilon = 0.1; % epsilon for ZCA whitening %%====================================================================== %% STEP 1: Create and modify sparseAutoencoderLinearCost.m to use a linear decoder, % and check gradients % You should copy sparseAutoencoderCost.m from your earlier exercise % and rename it to sparseAutoencoderLinearCost.m. % Then you need to rename the function from sparseAutoencoderCost to % sparseAutoencoderLinearCost, and modify it so that the sparse autoencoder % uses a linear decoder instead. Once that is done, you should check % your gradients to verify that they are correct. % NOTE: Modify sparseAutoencoderCost first! % To speed up gradient checking, we will use a reduced network and some % dummy patches debugHiddenSize = 5; debugvisibleSize = 8; patches = rand([8 10]); theta = initializeParameters(debugHiddenSize, debugvisibleSize); [cost, grad] = sparseAutoencoderLinearCost(theta, debugvisibleSize, debugHiddenSize, ... lambda, sparsityParam, beta, ... patches); % Check gradients numGrad = computeNumericalGradient( @(x) sparseAutoencoderLinearCost(x, debugvisibleSize, debugHiddenSize, ... lambda, sparsityParam, beta, ... patches), theta); % Use this to visually compare the gradients side by side disp([numGrad grad]); diff = norm(numGrad-grad)/norm(numGrad+grad); % Should be small. In our implementation, these values are usually less than 1e-9. disp(diff); assert(diff < 1e-9, 'Difference too large. Check your gradient computation again'); % NOTE: Once your gradients check out, you should run step 0 again to % reinitialize the parameters %} %%====================================================================== %% STEP 2: Learn features on small patches % In this step, you will use your sparse autoencoder (which now uses a % linear decoder) to learn features on small patches sampled from related % images. %% STEP 2a: Load patches % In this step, we load 100k patches sampled from the STL10 dataset and % visualize them. Note that these patches have been scaled to [0,1] load stlSampledPatches.mat displayColorNetwork(patches(:, 1:100)); %% STEP 2b: Apply preprocessing % In this sub-step, we preprocess the sampled patches, in particular, % ZCA whitening them. % % In a later exercise on convolution and pooling, you will need to replicate % exactly the preprocessing steps you apply to these patches before % using the autoencoder to learn features on them. Hence, we will save the % ZCA whitening and mean image matrices together with the learned features % later on. % Subtract mean patch (hence zeroing the mean of the patches) meanPatch = mean(patches, 2); patches = bsxfun(@minus, patches, meanPatch); % Apply ZCA whitening sigma = patches * patches' / numPatches; [u, s, v] = svd(sigma); ZCAWhite = u * diag(1 ./ sqrt(diag(s) + epsilon)) * u'; patches = ZCAWhite * patches; displayColorNetwork(patches(:, 1:100)); %% STEP 2c: Learn features % You will now use your sparse autoencoder (with linear decoder) to learn % features on the preprocessed patches. This should take around 45 minutes. theta = initializeParameters(hiddenSize, visibleSize); % Use minFunc to minimize the function addpath minFunc/ options = struct; options.Method = 'lbfgs'; options.maxIter = 400; options.display = 'on'; [optTheta, cost] = minFunc( @(p) sparseAutoencoderLinearCost(p, ... visibleSize, hiddenSize, ... lambda, sparsityParam, ... beta, patches), ... theta, options); % Save the learned features and the preprocessing matrices for use in % the later exercise on convolution and pooling fprintf('Saving learned features and preprocessing matrices...\n'); save('STL10Features.mat', 'optTheta', 'ZCAWhite', 'meanPatch'); fprintf('Saved\n'); %% STEP 2d: Visualize learned features W = reshape(optTheta(1:visibleSize * hiddenSize), hiddenSize, visibleSize); b = optTheta(2*hiddenSize*visibleSize+1:2*hiddenSize*visibleSize+hiddenSize); displayColorNetwork( (W*ZCAWhite)');
sparseAutoencoderLinearCost.m
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function [cost,grad,features] = sparseAutoencoderLinearCost(theta, visibleSize, hiddenSize, ...
lambda, sparsityParam, beta, data)
% -------------------- YOUR CODE HERE --------------------
% Instructions:
% Copy sparseAutoencoderCost in sparseAutoencoderCost.m from your
% earlier exercise onto
this
file, renaming the function to
% sparseAutoencoderLinearCost, and changing the autoencoder to use a
% linear decoder.
% visibleSize: the number of input units (probably 64)
% hiddenSize: the number of hidden units (probably 25)
% lambda: weight decay parameter
% sparsityParam: The desired average activation
for
the hidden units (denoted in the lecture
% notes by the greek alphabet rho, which looks like a lower-
case
"p"
).
% beta: weight of sparsity penalty term
% data: Our 64x10000 matrix containing the training data. So, data(:,i) is the i-th training example.
% The input theta is a vector (because minFunc expects the parameters to be a vector).
% We first convert theta to the (W1, W2, b1, b2) matrix/vector format, so that
this
% follows the notation convention of the lecture notes.
%将长向量转换成每一层的权值矩阵和偏置向量值
W1 = reshape(theta(1:hiddenSize*visibleSize), hiddenSize, visibleSize);
W2 = reshape(theta(hiddenSize*visibleSize+1:2*hiddenSize*visibleSize), visibleSize, hiddenSize);
b1 = theta(2*hiddenSize*visibleSize+1:2*hiddenSize*visibleSize+hiddenSize);
b2 = theta(2*hiddenSize*visibleSize+hiddenSize+1:end);
% Cost and gradient variables (your code needs to compute these values).
% Here, we initialize them to zeros.
cost = 0;
W1grad = zeros(size(W1));
W2grad = zeros(size(W2));
b1grad = zeros(size(b1));
b2grad = zeros(size(b2));
%% ---------- YOUR CODE HERE --------------------------------------
Jcost = 0;%直接误差
Jweight = 0;%权值惩罚
Jsparse = 0;%稀疏性惩罚
[n m] = size(data);%m为样本的个数,n为样本的特征数
%前向算法计算各神经网络节点的线性组合值和active值
z2 = W1*data+repmat(b1,1,m);%注意这里一定要将b1向量复制扩展成m列的矩阵
a2 = sigmoid(z2);
z3 = W2*a2+repmat(b2,1,m);
a3 = z3; %线性解码器************
% 计算预测产生的误差
Jcost = (0.5/m)*sum(sum((a3-data).^2));
%计算权值惩罚项
Jweight = (1/2)*(sum(sum(W1.^2))+sum(sum(W2.^2)));
%计算稀释性规则项
rho = (1/m).*sum(a2,2);%求出第一个隐含层的平均值向量
Jsparse = sum(sparsityParam.*
log
(sparsityParam./rho)+ ...
(1-sparsityParam).*
log
((1-sparsityParam)./(1-rho)));
%损失函数的总表达式
cost = Jcost+lambda*Jweight+beta*Jsparse;
%反向算法求出每个节点的误差值
d3 = -(data-a3); %线性解码器**************
sterm = beta*(-sparsityParam./rho+(1-sparsityParam)./(1-rho));%因为加入了稀疏规则项,所以
%计算偏导时需要引入该项
d2 = (W2'*d3+repmat(sterm,1,m)).*sigmoidInv(z2);
%计算W1grad
W1grad = W1grad+d2*data';
W1grad = (1/m)*W1grad+lambda*W1;
%计算W2grad
W2grad = W2grad+d3*a2';
W2grad = (1/m).*W2grad+lambda*W2;
%计算b1grad
b1grad = b1grad+sum(d2,2);
b1grad = (1/m)*b1grad;%注意b的偏导是一个向量,所以这里应该把每一行的值累加起来
%计算b2grad
b2grad = b2grad+sum(d3,2);
b2grad = (1/m)*b2grad;
%-------------------------------------------------------------------
% After computing the cost and gradient, we will convert the gradients back
% to a vector format (suitable
for
minFunc). Specifically, we will unroll
% your gradient matrices into a vector.
grad = [W1grad(:) ; W2grad(:) ; b1grad(:) ; b2grad(:)];
end
%-------------------------------------------------------------------
% Here's an implementation of the sigmoid function, which you may find useful
% in your computation of the costs and the gradients. This inputs a (row or
% column) vector (say (z1, z2, z3)) and returns (f(z1), f(z2), f(z3)).
function sigm = sigmoid(x)
sigm = 1 ./ (1 +
exp
(-x));
end
%sigmoid函数的逆函数
function sigmInv = sigmoidInv(x)
sigmInv = sigmoid(x).*(1-sigmoid(x));
end
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只是对稀疏自编码器的代码进行了两处稍微的改动。
结果:
学习到的特征也放在了STL10Features.mat里,将要在下一章的练习中用到。
PS:讲义地址:
http://deeplearning.stanford.edu/wiki/index.php/Linear_Decoders
http://deeplearning.stanford.edu/wiki/index.php/Exercise:Learning_color_features_with_Sparse_Autoencoders