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author | Arnaud Bergeron <abergeron@gmail.com> |
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date | Mon, 03 May 2010 13:55:03 -0400 |
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rev | line source |
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1 \documentclass[12pt,letterpaper]{article} |
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2 \usepackage[utf8]{inputenc} |
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3 \usepackage{graphicx} |
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4 \usepackage{times} |
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5 \usepackage{mlapa} |
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6 |
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7 \begin{document} |
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8 \title{Generating and Exploiting Perturbed Training Data for Deep Architectures} |
381 | 9 \author{The IFT6266 Gang} |
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10 \date{April 2010, Technical Report, Dept. IRO, U. Montreal} |
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11 |
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12 \maketitle |
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13 |
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14 \begin{abstract} |
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15 Recent theoretical and empirical work in statistical machine learning has |
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16 demonstrated the importance of learning algorithms for deep |
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17 architectures, i.e., function classes obtained by composing multiple |
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18 non-linear transformations. In the area of handwriting recognition, |
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19 deep learning algorithms |
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20 had been evaluated on rather small datasets with a few tens of thousands |
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21 of examples. Here we propose a powerful generator of variations |
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22 of examples for character images based on a pipeline of stochastic |
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23 transformations that include not only the usual affine transformations |
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24 but also the addition of slant, local elastic deformations, changes |
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25 in thickness, background images, color, contrast, occlusion, and |
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26 various types of pixel and spatially correlated noise. |
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27 We evaluate a deep learning algorithm (Stacked Denoising Autoencoders) |
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28 on the task of learning to classify digits and letters transformed |
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29 with this pipeline, using the hundreds of millions of generated examples |
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30 and testing on the full NIST test set. |
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31 We find that the SDA outperforms its |
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32 shallow counterpart, an ordinary Multi-Layer Perceptron, |
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33 and that it is better able to take advantage of the additional |
438 | 34 generated data, as well as better able to take advantage of |
35 training from more classes than those of interest in the end. | |
36 In fact, we find that the SDA reaches human performance as | |
37 estimated by the Amazon Mechanical Turk on the NIST test characters. | |
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38 \end{abstract} |
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39 |
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40 \section{Introduction} |
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41 |
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42 Deep Learning has emerged as a promising new area of research in |
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43 statistical machine learning (see~\emcite{Bengio-2009} for a review). |
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44 Learning algorithms for deep architectures are centered on the learning |
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45 of useful representations of data, which are better suited to the task at hand. |
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46 This is in great part inspired by observations of the mammalian visual cortex, |
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47 which consists of a chain of processing elements, each of which is associated with a |
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48 different representation. In fact, |
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49 it was found recently that the features learnt in deep architectures resemble |
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50 those observed in the first two of these stages (in areas V1 and V2 |
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51 of visual cortex)~\cite{HonglakL2008}. |
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52 Processing images typically involves transforming the raw pixel data into |
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53 new {\bf representations} that can be used for analysis or classification. |
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54 For example, a principal component analysis representation linearly projects |
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55 the input image into a lower-dimensional feature space. |
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56 Why learn a representation? Current practice in the computer vision |
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57 literature converts the raw pixels into a hand-crafted representation |
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58 (e.g.\ SIFT features~\cite{Lowe04}), but deep learning algorithms |
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59 tend to discover similar features in their first few |
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60 levels~\cite{HonglakL2008,ranzato-08,Koray-08,VincentPLarochelleH2008-very-small}. |
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61 Learning increases the |
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62 ease and practicality of developing representations that are at once |
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63 tailored to specific tasks, yet are able to borrow statistical strength |
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64 from other related tasks (e.g., modeling different kinds of objects). Finally, learning the |
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65 feature representation can lead to higher-level (more abstract, more |
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66 general) features that are more robust to unanticipated sources of |
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67 variance extant in real data. |
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68 |
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69 Whereas a deep architecture can in principle be more powerful than a shallow |
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70 one in terms of representation, depth appears to render the training problem |
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71 more difficult in terms of optimization and local minima. |
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72 It is also only recently that |
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73 successful algorithms were proposed to overcome some of these |
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74 difficulties. |
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75 |
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76 \section{Perturbation and Transformation of Character Images} |
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77 This section describes the different transformations we used to generate data, in their order. |
428 | 78 We can differentiate two important parts in the pipeline. The first one, from slant to pinch, performs transformations |
79 of the character. The second part, from blur to contrast, adds noise to the image. | |
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80 |
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81 \subsection{Adding Slant} |
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82 In order to mimic a slant effect, we simply shift each row of the image proportionnaly to its height: $shift = round(slant \times height)$. |
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83 We round the shift in order to have a discret displacement. We do not use a filter to smooth the result in order to save computing time |
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84 and also because latter transformations have similar effects. |
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85 |
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86 The $slant$ coefficient can be negative or positive with equal probability and its value is randomly sampled according to the complexity level. |
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87 In our case we take uniformly a number in the range $[0,complexity]$, so the maximum displacement for the lowest |
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88 or highest pixel line is of $round(complexity \times 32)$. |
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89 |
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90 |
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91 \subsection{Changing Thickness} |
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92 To change the thickness of the characters we used morpholigical operators: dilation and erosion~\cite{Haralick87,Serra82}. |
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93 |
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94 The basic idea of such transform is, for each pixel, to multiply in the element-wise manner its neighbourhood with a matrix called the structuring element. |
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95 Then for dilation we remplace the pixel value by the maximum of the result, or the minimum for erosion. |
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96 This will dilate or erode objects in the image and the strength of the transform only depends on the structuring element. |
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97 |
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98 We used ten different structural elements with increasing dimensions (the biggest is $5\times5$). |
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99 for each image, we radomly sample the operator type (dilation or erosion) with equal probability and one structural element |
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100 from a subset of the $n$ smallest structuring elements where $n$ is $round(10 \times complexity)$ for dilation and $round(6 \times complexity)$ for erosion. |
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101 A neutral element is always present in the set, if it is chosen the transformation is not applied. |
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102 Erosion allows only the six smallest structural elements because when the character is too thin it may erase it completly. |
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103 |
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104 \subsection{Affine Transformations} |
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105 We generate an affine transform matrix according to the complexity level, then we apply it directly to the image. |
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106 The matrix is of size $2 \times 3$, so we can represent it by six parameters $(a,b,c,d,e,f)$. |
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107 Formally, for each pixel $(x,y)$ of the output image, |
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108 we give the value of the pixel nearest to : $(ax+by+c,dx+ey+f)$, in the input image. |
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109 This allows to produce scaling, translation, rotation and shearing variances. |
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110 |
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111 The sampling of the parameters $(a,b,c,d,e,f)$ have been tuned by hand to forbid important rotations (not to confuse classes) but to give good variability of the transformation. For each image we sample uniformly the parameters in the following ranges: |
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112 $a$ and $d$ in $[1-3 \times complexity,1+3 \times complexity]$, $b$ and $e$ in $[-3 \times complexity,3 \times complexity]$ and $c$ and $f$ in $[-4 \times complexity, 4 \times complexity]$. |
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113 |
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114 |
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115 \subsection{Local Elastic Deformations} |
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116 This filter induces a "wiggly" effect in the image. The description here will be brief, as the algorithm follows precisely what is described in \cite{SimardSP03}. |
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117 |
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118 The general idea is to generate two "displacements" fields, for horizontal and vertical displacements of pixels. Each of these fields has the same size as the original image. |
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119 |
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120 When generating the transformed image, we'll loop over the x and y positions in the fields and select, as a value, the value of the pixel in the original image at the (relative) position given by the displacement fields for this x and y. If the position we'd retrieve is outside the borders of the image, we use a 0 value instead. |
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121 |
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122 To generate a pixel in either field, first a value between -1 and 1 is chosen from a uniform distribution. Then all the pixels, in both fields, is multiplied by a constant $\alpha$ which controls the intensity of the displacements (bigger $\alpha$ translates into larger wiggles). |
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123 |
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124 As a final step, each field is convoluted with a Gaussian 2D kernel of standard deviation $\sigma$. Visually, this results in a "blur" filter. This has the effect of making values next to each other in the displacement fields similar. In effect, this makes the wiggles more coherent, less noisy. |
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125 |
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126 As displacement fields were long to compute, 50 pairs of fields were generated per complexity in increments of 0.1 (50 pairs for 0.1, 50 pairs for 0.2, etc.), and afterwards, given a complexity, we selected randomly among the 50 corresponding pairs. |
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127 |
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128 $\sigma$ and $\alpha$ were linked to complexity through the formulas $\alpha = \sqrt[3]{complexity} \times 10.0$ and $\sigma = 10 - 7 \times \sqrt[3]{complexity}$. |
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131 \subsection{Pinch} |
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132 |
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133 This is another GIMP filter we used. The filter is in fact named "Whirl and pinch", but we don't use the "whirl" part (whirl is set to 0). As described in GIMP, a pinch is "similar to projecting the image onto an elastic surface and pressing or pulling on the center of the surface". |
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134 |
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135 Mathematically, for a square input image, think of drawing a circle of radius $r$ around a center point $C$. Any point (pixel) $P$ belonging to that disk (region inside circle) will have its value recalculated by taking the value of another "source" pixel in the original image. The position of that source pixel is found on the line thats goes through $C$ and $P$, but at some other distance $d_2$. Define $d_1$ to be the distance between $P$ and $C$. $d_2$ is given by $d_2 = sin(\frac{\pi{}d_1}{2r})^{-pinch} \times d_1$, where $pinch$ is a parameter to the filter. |
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136 |
417 | 137 If the region considered is not square then, before computing $d_2$, the smallest dimension (x or y) is stretched such that we may consider the region as if it was square. Then, after $d_2$ has been computed and corresponding components $d_2\_x$ and $d_2\_y$ have been found, the component corresponding to the stretched dimension is compressed back by an inverse ratio. |
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138 |
417 | 139 The actual value is given by bilinear interpolation considering the pixels around the (non-integer) source position thus found. |
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140 |
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141 The value for $pinch$ in our case was given by sampling from an uniform distribution over the range $[-complexity, 0.7 \times complexity]$. |
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142 |
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143 \subsection{Motion Blur} |
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144 |
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145 This is a GIMP filter we applied, a "linear motion blur" in GIMP terminology. The description will be brief as it is a well-known filter. |
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146 |
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147 This algorithm has two input parameters, $length$ and $angle$. The value of a pixel in the final image is the mean value of the $length$ first pixels found by moving in the $angle$ direction. An approximation of this idea is used, as we won't fall onto precise pixels by following that direction. This is done using the Bresenham line algorithm. |
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148 |
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149 The angle, in our case, is chosen from a uniform distribution over $[0,360]$ degrees. The length, though, depends on the complexity; it's sampled from a Gaussian distribution of mean 0 and standard deviation $\sigma = 3 \times complexity$. |
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150 |
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151 \subsection{Occlusion} |
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152 |
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153 This filter selects random parts of other (hereafter "occlusive") letter images and places them over the original letter (hereafter "occluded") image. To be more precise, having selected a subregion of the occlusive image and a desination position in the occluded image, to determine the final value for a given overlapping pixel, it selects whichever pixel is the lightest. As a reminder, the background value is 0, black, so the value nearest to 1 is selected. |
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154 |
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155 To select a subpart of the occlusive image, four numbers are generated. For compability with the code, we'll call them "haut", "bas", "gauche" and "droite" (respectively meaning top, bottom, left and right). Each of these numbers is selected according to a Gaussian distribution of mean $8 \times complexity$ and standard deviation $2$. This means the largest the complexity is, the biggest the occlusion will be. The absolute value is taken, as the numbers must be positive, and the maximum value is capped at 15. |
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156 |
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157 These four sizes collectively define a window centered on the middle pixel of the occlusive image. This is the part that will be extracted as the occlusion. |
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158 |
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159 The next step is to select a destination position in the occluded image. Vertical and horizontal displacements $y\_arrivee$ and $x\_arrivee$ are selected according to Gaussian distributions of mean 0 and of standard deviations of, respectively, 3 and 2. Then an horizontal placement mode, $endroit$ (meaning location), is selected to be of three values meaning left, middle or right. |
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160 |
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161 If $endroit$ is "middle", the occlusion will be horizontally centered around the horizontal middle of the occluded image, then shifted according to $x\_arrivee$. If $endroit$ is "left", it will be placed on the left of the occluded image, then displaced right according to $x\_arrivee$. The contrary happens if $endroit$ is $right$. |
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162 |
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163 In both the horizontal and vertical positionning, the maximum position in either direction is such that the selected occlusion won't go beyond the borders of the occluded image. |
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164 |
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165 This filter has a probability of not being applied, at all, of 60\%. |
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166 |
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167 |
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168 \subsection{Distorsion gauss} |
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169 |
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170 This filter simply adds, to each pixel of the image independently, a gaussian noise of mean $0$ and standard deviation $\frac{complexity}{10}$. |
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171 |
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172 It has has a probability of not being applied, at all, of 70\%. |
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173 |
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174 |
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175 \subsection{Background Images} |
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176 |
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177 This transformation adds a random background behind the letter. The background is chosen by first selecting, at random, an image from a set of images. Then we choose a 32x32 subregion of that image as the background image (by sampling x and y positions uniformly while making sure not to cross image borders). |
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178 |
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179 To combine the original letter image and the background image, contrast adjustments are made. We first get the maximal values (i.e. maximal intensity) for both the original image and the background image, $maximage$ and $maxbg$. We also have a parameter, $contrast$, given by sampling from a uniform distribution over $[complexity, 1]$. |
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180 |
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181 Once we have all these numbers, we first adjust the values for the background image. Each pixel value is multiplied by $\frac{max(maximage - contrast, 0)}{maxbg}$. Therefore the higher the contrast, the darkest the background will be. |
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182 |
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183 The final image is found by taking the brightest (i.e. value nearest to 1) pixel from either the background image or the corresponding pixel in the original image. |
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184 |
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185 \subsection{Salt and Pepper Noise} |
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186 |
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187 This filter adds noise to the image by randomly selecting a certain number of them and, for those selected pixels, assign a random value according to a uniform distribution over the $[0,1]$ ranges. This last distribution does not change according to complexity. Instead, the number of selected pixels does: the proportion of changed pixels corresponds to $complexity / 5$, which means, as a maximum, 20\% of the pixels will be randomized. On the lowest extreme, no pixel is changed. |
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188 |
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189 This filter also has a probability of not being applied, at all, of 75\%. |
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190 |
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191 \subsection{Spatially Gaussian Noise} |
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192 |
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193 The aim of this transformation is to filter, with a gaussian kernel, different regions of the image. In order to save computing time |
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194 we decided to convolve the whole image only once with a symmetric gaussian kernel of size and variance choosen uniformly in the ranges: |
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195 $[12,12 + 20 \times complexity]$ and $[2,2 + 6 \times complexity]$. The result is normalized between $0$ and $1$. |
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196 We also create a symmetric averaging window, of the kernel size, with maximum value at the center. |
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197 For each image we sample uniformly from $3$ to $3 + 10 \times complexity$ pixels that will be averaging centers |
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198 between the original image and the filtered one. |
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199 We initialize to zero a mask matrix of the image size. For each selected pixel we add to the mask the averaging window centered to it. |
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200 The final image is computed from the following element-wise operation: $\frac{image + filtered_image \times mask}{mask+1}$. |
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201 |
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202 This filter has a probability of not being applied, at all, of 75\%. |
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203 |
428 | 204 \subsection{"Ratures"} |
205 | |
206 The ratures ("scratches") filter places line-like white patches on the image. The lines are in fact heavily transformed images of the digit "1" (one), chosen at random among five thousands such start images of this digit. | |
207 | |
208 Once the image is selected, the transformation begins by finding the first $top$, $bottom$, $right$ and $left$ non-zero pixels in the image. It is then cropped to the region thus delimited, then this cropped version is expanded to 32x32 again. It is then rotated by a random angle having a Gaussian distribution of mean 90 and standard deviation $100 \times complexity$ (in degrees). The rotation is done with bicubic interpolation. | |
209 | |
210 The rotated image is then resized to 50x50, with anti-aliasing. In that image, we crop the image again by selecting a region delimited horizontally to $left$ to $left+32$ and vertically by $top$ to $top+32$. | |
211 | |
212 Once this is done, two passes of a greyscale morphological erosion filter are applied. Put briefly, this erosion filter reduces the width of the line by a certain $smoothing$ amount. For small complexities (< 0.5), $smoothing$ is 6, so the line is very small. For complexities ranging from 0.25 to 0.5, $smoothing$ is 5. It is 4 for complexities 0.5 to 0.75, and 3 for higher complexities. | |
213 | |
214 To compensate for border effects, the image is then cropped to 28x28 by removing two pixels everywhere on the borders, then expanded to 32x32 again. The pixel values are then linearly expanded such that the minimum value is 0 and the maximal one is 1. Then, 50\% of the time, the image is vertically flipped. | |
215 | |
216 This filter is only applied only 15\% of the time. When it is applied, 50\% of the time, only one patch image is generated and applied. In 30\% of cases, two patches are generated, and otherwise three patches are generated. The patch is applied by taking the maximal value on any given patch or the original image, for each of the 32x32 pixel locations. | |
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217 |
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218 \subsection{Color and Contrast Changes} |
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219 |
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220 This filter changes the constrast and may invert the image polarity (white on black to black on white). The contrast $C$ is defined here as the difference |
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221 between the maximum and the minimum pixel value of the image. A contrast value is sampled uniformly between $1$ and $1-0.85 \times complexity$ |
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222 (this insure a minimum constrast of $0.15$). We then simply normalize the image to the range $[\frac{1-C}{2},1-\frac{1-C}{2}]$. The polarity |
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223 is inverted with $0.5$ probability. |
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224 |
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225 |
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226 \begin{figure}[h] |
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227 \resizebox{.99\textwidth}{!}{\includegraphics{images/example_t.png}}\\ |
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228 \caption{Illustration of the pipeline of stochastic |
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229 transformations applied to the image of a lower-case t |
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230 (the upper left image). Each image in the pipeline (going from |
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231 left to right, first top line, then bottom line) shows the result |
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232 of applying one of the modules in the pipeline. The last image |
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233 (bottom right) is used as training example.} |
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234 \label{fig:pipeline} |
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235 \end{figure} |
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236 |
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237 \section{Learning Algorithms for Deep Architectures} |
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238 |
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239 Learning for deep network has long been a problem since well-known learning algorithms do not generalize well on deep architectures. |
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240 Using these training algorithms on deep network usually yields to a worse generalization than on shallow networks. |
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241 Recently, new initialization techniques have been discovered that enable better generalization overall. |
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242 |
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243 One of these initialization techniques is denoising auto-encoders. |
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244 The principle is that each layer starting from the bottom is trained to encode and decode their input and the encoding part is kept as initialization for the weights and bias of the network. |
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245 For more details see section \ref{SdA}. |
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246 |
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247 After initialization is done, standard training algorithms work. |
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248 In this case, since we have large data sets we use stochastic gradient descent. |
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249 This resemble minibatch training except that the batches are selected at random. |
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250 To speed up computation, we randomly pre-arranged examples in batches and used those for all training experiments. |
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251 |
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252 \section{Experimental Setup} |
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253 |
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254 \subsection{Training Datasets} |
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255 |
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256 \subsubsection{Data Sources} |
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257 |
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258 \begin{itemize} |
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259 \item {\bf NIST} |
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260 The NIST Special Database 19 (NIST19) is a very widely used dataset for training and testing OCR systems. |
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261 The dataset is composed with over 800 000 digits and characters (upper and lower cases), with hand checked classifications, |
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262 extracted from handwritten sample forms of 3600 writers. The characters are labelled by one of the 62 classes |
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263 corresponding to "0"-"9","A"-"Z" and "a"-"z". The dataset contains 8 series of different complexity. |
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264 The fourth series, $hsf_4$, experimentally recognized to be the most difficult one for classification task is recommended |
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265 by NIST as testing set and is used in our work for that purpose. |
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266 The performances reported by previous work on that dataset mostly use only the digits. |
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267 Here we use the whole classes both in the training and testing phase. |
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268 |
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269 |
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270 \item {\bf Fonts} |
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271 \item {\bf Captchas} |
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272 The Captcha data source is an adaptation of the \emph{pycaptcha} library (a python based captcha generator library) for |
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273 generating characters of the same format as the NIST dataset. The core of this data source is composed with a random character |
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274 generator and various kinds of tranformations similar to those described in the previous sections. |
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275 In order to increase the variability of the data generated, different fonts are used for generating the characters. |
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276 Transformations (slant, distorsions, rotation, translation) are applied to each randomly generated character with a complexity |
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277 depending on the value of the complexity parameter provided by the user of the data source. Two levels of complexity are |
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278 allowed and can be controlled via an easy to use facade class. |
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279 \item {\bf OCR data} |
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280 \end{itemize} |
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281 |
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282 \subsubsection{Data Sets} |
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283 \begin{itemize} |
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284 \item {\bf NIST} |
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285 \item {\bf P07} |
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286 The dataset P07 is sampled with our transformation pipeline with a complexity parameter of $0.7$. |
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287 For each new exemple to generate, we choose one source with the following probability: $0.1$ for the fonts, |
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288 $0.25$ for the captchas, $0.25$ for OCR data and $0.4$ for NIST. We apply all the transformations in their order |
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289 and for each of them we sample uniformly a complexity in the range $[0,0.7]$. |
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290 \item {\bf NISTP} {\em ne pas utiliser PNIST mais NISTP, pour rester politically correct...} |
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291 NISTP is equivalent to P07 except that we only apply transformations from slant to pinch. Therefore, the character is transformed |
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292 but no additionnal noise is added to the image, this gives images closer to the NIST dataset. |
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293 \end{itemize} |
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294 |
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295 \subsection{Models and their Hyperparameters} |
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296 |
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297 \subsubsection{Multi-Layer Perceptrons (MLP)} |
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298 |
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299 An MLP is a family of functions that are described by stacking layers of of a function similar to |
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300 $$g(x) = \tanh(b+Wx)$$ |
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301 The input, $x$, is a $d$-dimension vector. |
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302 The output, $g(x)$, is a $m$-dimension vector. |
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303 The parameter $W$ is a $m\times d$ matrix and is called the weight matrix. |
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304 The parameter $b$ is a $m$-vector and is called the bias vector. |
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305 The non-linearity (here $\tanh$) is applied element-wise to the output vector. |
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306 Usually the input is referred to a input layer and similarly for the output. |
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307 You can of course chain several such functions to obtain a more complex one. |
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308 Here is a common example |
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309 $$f(x) = c + V\tanh(b+Wx)$$ |
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310 In this case the intermediate layer corresponding to $\tanh(b+Wx)$ is called a hidden layer. |
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311 Here the output layer does not have the same non-linearity as the hidden layer. |
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312 This is a common case where some specialized non-linearity is applied to the output layer only depending on the task at hand. |
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313 |
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314 If you put 3 or more hidden layers in such a network you obtain what is called a deep MLP. |
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315 The parameters to adapt are the weight matrix and the bias vector for each layer. |
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316 |
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317 \subsubsection{Stacked Denoising Auto-Encoders (SDAE)} |
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318 \label{SdA} |
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319 |
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320 Auto-encoders are essentially a way to initialize the weights of the network to enable better generalization. |
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321 This is essentially unsupervised training where the layer is made to reconstruct its input through and encoding and decoding phase. |
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322 Denoising auto-encoders are a variant where the input is corrupted with random noise but the target is the uncorrupted input. |
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323 The principle behind these initialization methods is that the network will learn the inherent relation between portions of the data and be able to represent them thus helping with whatever task we want to perform. |
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324 |
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325 An auto-encoder unit is formed of two MLP layers with the bottom one called the encoding layer and the top one the decoding layer. |
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326 Usually the top and bottom weight matrices are the transpose of each other and are fixed this way. |
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327 The network is trained as such and, when sufficiently trained, the MLP layer is initialized with the parameters of the encoding layer. |
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328 The other parameters are discarded. |
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329 |
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330 The stacked version is an adaptation to deep MLPs where you initialize each layer with a denoising auto-encoder starting from the bottom. |
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331 During the initialization, which is usually called pre-training, the bottom layer is treated as if it were an isolated auto-encoder. |
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332 The second and following layers receive the same treatment except that they take as input the encoded version of the data that has gone through the layers before it. |
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333 For additional details see \cite{vincent:icml08}. |
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334 |
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335 \section{Experimental Results} |
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336 |
438 | 337 \subsection{SDA vs MLP vs Humans} |
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338 |
438 | 339 We compare here the best MLP (according to validation set error) that we found against |
340 the best SDA (again according to validation set error), along with a precise estimate | |
341 of human performance obtained via Amazon's Mechanical Turk (AMT) | |
342 service\footnote{http://mturk.com}. AMT users are paid small amounts | |
343 of money to perform tasks for which human intelligence is required. | |
344 Mechanical Turk has been used extensively in natural language | |
345 processing \cite{SnowEtAl2008} and vision | |
346 \cite{SorokinAndForsyth2008,whitehill09}. AMT users where presented | |
347 with 10 character images and asked to type 10 corresponding ascii | |
348 characters. Hence they were forced to make a hard choice among the | |
349 62 character classes. Three users classified each image, allowing | |
350 to estimate inter-human variability (shown as +/- in parenthesis below). | |
351 | |
352 \begin{table} | |
353 \caption{Overall comparison of error rates on 62 character classes (10 digits + | |
354 26 lower + 26 upper), except for last columns -- digits only, between deep architecture with pre-training | |
355 (SDA=Stacked Denoising Autoencoder) and ordinary shallow architecture | |
356 (MLP=Multi-Layer Perceptron). } | |
357 \label{tab:sda-vs-mlp-vs-humans} | |
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358 \begin{center} |
438 | 359 \begin{tabular}{|l|r|r|r|r|} \hline |
360 & NIST test & NISTP test & P07 test & NIST test digits \\ \hline | |
361 Humans& & & & \\ \hline | |
362 SDA & & & &\\ \hline | |
363 MLP & & & & \\ \hline | |
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364 \end{tabular} |
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365 \end{center} |
438 | 366 \end{table} |
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367 |
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368 \subsection{Perturbed Training Data More Helpful for SDAE} |
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369 |
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370 \subsection{Training with More Classes than Necessary} |
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371 |
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372 As previously seen, the SDA is better able to benefit from the transformations applied to the data than the MLP. We are now training SDAs and MLPs on single classes from NIST (respectively digits, lower case characters and upper case characters), to compare the test results with those from models trained on the entire NIST database (per-class test error, with an a priori on the desired class). The goal is to find out if training the model with more classes than necessary reduces the test error on a single class, as opposed to training it only with the desired class. We use a single hidden layer MLP with 1000 hidden units, and a SDA with 3 hidden layers (1000 hidden units per layer), pre-trained and fine-tuned on NIST. |
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373 |
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374 Our results show that the MLP only benefits from a full NIST training on digits, and the test error is only 5\% smaller than a digits-specialized MLP. On the other hand, the SDA always gives better results when it is trained with the entire NIST database, compared to its specialized counterparts (with upper case character, the test errors is 12\% smaller, 27\% smaller on digits, and 15\% smaller on lower case characters). |
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375 |
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376 \section{Conclusions} |
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377 |
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378 \bibliography{strings,ml,aigaion,specials} |
379
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379 \bibliographystyle{mlapa} |
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380 |
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381 \end{document} |