index.en.html 34.9 KB
Newer Older
1

Y
Yi Wang 已提交
2 3 4 5 6 7 8
<html>
<head>
  <script type="text/x-mathjax-config">
  MathJax.Hub.Config({
    extensions: ["tex2jax.js", "TeX/AMSsymbols.js", "TeX/AMSmath.js"],
    jax: ["input/TeX", "output/HTML-CSS"],
    tex2jax: {
9 10
      inlineMath: [ ['$','$'] ],
      displayMath: [ ['$$','$$'] ],
Y
Yi Wang 已提交
11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45
      processEscapes: true
    },
    "HTML-CSS": { availableFonts: ["TeX"] }
  });
  </script>
  <script src="https://cdnjs.cloudflare.com/ajax/libs/mathjax/2.7.0/MathJax.js" async></script>
  <script type="text/javascript" src="../.tmpl/marked.js">
  </script>
  <link href="http://cdn.bootcss.com/highlight.js/9.9.0/styles/darcula.min.css" rel="stylesheet">
  <script src="http://cdn.bootcss.com/highlight.js/9.9.0/highlight.min.js"></script>
  <link href="http://cdn.bootcss.com/bootstrap/4.0.0-alpha.6/css/bootstrap.min.css" rel="stylesheet">
  <link href="https://cdn.jsdelivr.net/perfect-scrollbar/0.6.14/css/perfect-scrollbar.min.css" rel="stylesheet">
  <link href="../.tmpl/github-markdown.css" rel='stylesheet'>
</head>
<style type="text/css" >
.markdown-body {
    box-sizing: border-box;
    min-width: 200px;
    max-width: 980px;
    margin: 0 auto;
    padding: 45px;
}
</style>


<body>

<div id="context" class="container markdown-body">
</div>

<!-- This block will be replaced by each markdown file content. Please do not change lines below.-->
<div id="markdown" style='display:none'>
Image Classification
=======================

L
liaogang 已提交
46
The source code of this chapter is in [book/image_classification](https://github.com/PaddlePaddle/book/tree/develop/image_classification). For the first-time users, please refer to PaddlePaddle [Installation Tutorial](http://www.paddlepaddle.org/doc_cn/build_and_install/index.html) for installation instructions.
Y
Yi Wang 已提交
47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179

## Background

Comparing to words, images provide more vivid and easier to understand information with more artistic sense. They are important source for people to convey and exchange ideas. In this chapter, we focus on one of the essential problems in image recognition -- image classification.

Image classification distinguishes images of different categories based on their semantic meaning. It is a core problem in computer vision, and is also the foundation of other higher level computer vision tasks such as object detection, image segmentation, object tracking, action recognition, etc. Image classification has applications in many areas such as face recognition and intelligent video analysis in security systems, traffic scene recognition in transportation systems, content-based image retrieval and automatic photo indexing in web services, image classification in medicine, etc.

In image classification, we first encode the whole image using handcrafted or learned features, and then determine the object category by a classifier. Therefore, feature extraction plays an important role in image classification. Prior to deep learning, BoW(Bag of Words) model is the most popular method for object classification. BoW was introduced in NLP where a sentence is represented as a bag of words (words, phrases, or characters) extracted from training sentences. In the context of image classification, BoW model requires constructing a dictionary. The simplest BoW framework can be designed with three steps: **feature extraction**, **feature encoding**, and **classifier design**.

Deep learning approach to image classification works by supervised or unsupervised learning of hierarchical features automatically instead of crafting or selecting image features manually. Convolutional Neural Networks (CNNs) have made significant progress in image classification. They keep all image information by employing raw image pixels as input, extract low-level and high-level abstract features through convolution operations, and directly output the classification results from the model. This end-to-end learning fashion leads to good performance and wide applications.

In this chapter, we focus on introducing deep learning-based image classification methods, and on explaining how to train a CNN model using PaddlePaddle.

## Demonstration

Image classification includes general and fine-grained ones. Figure 1 demonstrates the results of general image classification -- the trained model can correctly recognize the main objects in the images.

<p align="center">
<img src="image/dog_cat.png "  width="350" ><br/>
Figure 1. General image classification
</p>


Figure 2 demonstrates the results of fine-grained image classification -- flower recognition, which requires correct recognition of flower categories.

<p align="center">
<img src="image/flowers.png" width="400" ><br/>
Figure 2. Fine-grained image classification
</p>


A good model should be able to recognize objects of different categories correctly, and meanwhile can correctly classify images taken from different points of view, under different illuminations, with object distortion or partial occlusion (we call these image disturbance). Figure 3 show some images with various disturbance. A good model should be able to classify these images correctly like humans.

<p align="center">
<img src="image/variations_en.png" width="550" ><br/>
Figure 3. Disturbed images [22]
</p>

## Model Overview

A large amount of research work in image classification is built upon public datasets such as [PASCAL VOC](http://host.robots.ox.ac.uk/pascal/VOC/), [ImageNet](http://image-net.org/). Many image classification algorithms are usually evaluated and compared on these datasets. PASCAL VOC is a computer vision competition started in 2005, and ImageNet is a dataset started in Large Scale Visual Recognition Challenge (ILSVRC) 2010. In this chapter, we introduce some image classification models from the submissions to these competitions.

Before 2012, traditional image classification methods can be achieved with the three steps described in the Background section. A complete model construction usually involves the following stages: low-level feature extraction, feature encoding, spatial constraint or feature clustering, classifier design, model ensemble.

  1). **Low-level feature extraction**: This is a step for extracting large amounts of local features according to fixed strides and scales. Popular local features include Scale-Invariant Feature Transform(SIFT)[1], Histogram of Oriented Gradient(HOG)[2], Local Binary Pattern(LBP)[3], etc. A common practice is to employ multiple feature descriptors in order to avoid missing too much information.
  2). **Feature encoding**: Low-level features contain large amount of redundancy and noise. In order to improve robustness of features, it is necessary to employ a feature transformation to encode low-level features, which is called feature encoding. Common feature encoding methods include vector quantization [4], sparse coding [5], locality-constrained linear coding [6], Fisher vector encoding [7], etc.
  3). **Spatial constraint**: Spatial constraint or feature clustering is usually adopted after feature encoding for extracting the maximum or average of each dimension in the spatial domain. Pyramid feature matching--a popular feature clustering method--divides an image uniformly into patches, and performs feature clustering in each patch.
  4). **Classification**: Upon the above steps, an image can be described by a vector of fixed dimension. Then a classifier can be used to classify the image into categories. Common classifiers include Support Vector Machine(SVM), random forest, etc. Kernel SVM is the most popular classifier, and has achieved very good performance in traditional image classification tasks.

This method has been used widely as image classification algorithm in PASCAL VOC [18]. NEC Labs(http://www.nec-labs.com/) won the championship by employing SIFT and LBP features, two non-linear encoders and SVM in ILSVRC 2010 [8].

The CNN model--AlexNet proposed by Alex Krizhevsky et al.[9], made a breakthrough in ILSVRC 2012. It outperformed traditional methods dramatically, and won the championship in ILSVRC 2012. This is also the first time that a deep learning method was used for large scale image classification. Since AlexNet, a series of  CNN models have been proposed and has advanced the state of the art steadily on Imagenet as shown in Figure 4. With deeper and more sophisticated architectures, Top-5 error rate is getting lower and lower, until to around 3.5%. The error rate of human raters on the same Imagenet dataset is 5.1%, which means that the image classification capability of a deep learning model surpasses human raters.

<p align="center">
<img src="image/ilsvrc.png" width="500" ><br/>
Figure 4. Top-5 error rates on ILSVRC image classification
</p>

### CNN

Traditional CNNs consist of convolutional and fully-connected layers, and employ softmax multi-category classifier and cross-entropy as loss function. Figure 5 shows a typical CNN. We first introduce the common parts of a CNN.

<p align="center">
<img src="image/lenet_en.png"><br/>
Figure 5. A CNN example [20]
</p>

- convolutional layer: It uses convolution operation to extract low-level and high-level features, and to discover local correlation and spatial invariance.

- pooling layer: It down-sample feature maps via extracting local max (max-pooling) or average (avg-pooling) of each patch in the feature map. Down-sampling, a common operator in image processing, can be used to filter out high frequency information.

- fully-connected layer: It fully connects neurons between two adjacent layers.

- non-linear activation: Convolutional and fully-connected layers are usually followed by some non-linear activation layers, such as Sigmoid, Tanh, Relu to enhance the expression capability. Relu is the most commonly used activation function in CNN.

- Dropout [10]: At each training stage, individual nodes are dropped out of the net with a certain probability in order to improve generalization and to avoid overfitting.

Due to parameter updating in each layer during training, it causes the change in the distributions of layer inputs, and requires careful tuning of hyper-parameters. In 2015, Sergey Ioffe and Christian Szegedy proposed a Batch Normalization (BN) algorithm [14], which normalizes the features of each batch in a layer, and enables relatively stable distribution in each layer. Not only does BN algorithm act as a regularizer, but also reduces the need for careful hyper-parameter design. Experiments demonstrate that BN algorithm accelerates the training convergence and has been widely used in later deeper models.

We will introduce the network architectures of VGG, GoogleNet and ResNets in the following sections.

### VGG

Oxford Visual Geometry Group (VGG) proposed VGG network in ILSVRC 2014 [11]. The model is deeper and wider than previous neural architectures. It comprises five main groups of convolution operations, with max-pooling layers between adjacent convolution groups. Each group contains a series of 3x3 convolutional layers, whose number of convolution kernels stays the same within the group and increases from 64 in the first group to 512 in the last one. The total number of learnable layers could be 11, 13, 16, or 19 depending on the number of convolutional layers in each group. Figure 6 illustrates a 16-layer VGG. The neural architecture of VGG is relatively simple, and has been adopted by many papers such as the first one that surpassed human-level performance on ImageNet [19].

<p align="center">
<img src="image/vgg16.png" width="750" ><br/>
Figure 6. Vgg16 model for ImageNet
</p>

### GoogleNet

GoogleNet [12] won the championship in ILSVRC 2014. Before introducing this model, lets get familiar with Network in Network(NIN) model [13] from which GoogleNet borrowed some ideas, and Inception blocks upon which GoogleNet is built.

NIN model has two main characteristics: 1) it replaces the single-layer convolutional network by Multi-Layer Perceptron Convolution or MLPconv. MLPconv, a tiny multi-layer convolutional network, enhances non-linearity by adding several 1x1 convolutional layers after linear ones. 2) In traditional CNNs, the last fewer layers are usually fully-connected with a large number of parameters. In contrast, NIN replaces all fully-connected layers with convolutional layers whose feature maps are of the same size as the category dimension, and followed by a global average pooling. This replacement of fully-connected layers significantly reduces the number of parameters.

Figure 7 depicts two Inception blocks. Figure 7(a) is the simplest design, the output of which is a concat of features from three convolutional layers and one pooling layer. The disadvantage of this design is that the pooling layer does not change the number of filters and leads to an increase of outputs. After going through several of such blocks, the number of outputs and parameters will become larger and larger, leading to higher computation complexity. To overcome this drawback, the Inception block in Figure 7(b) employs three 1x1 convolutional layers to reduce dimension or the number of channels, meanwhile improves non-linearity of the network.

<p align="center">
<img src="image/inception_en.png" width="800" ><br/>
Figure 7. Inception block
</p>

GoogleNet consists of multiple stacking Inception blocks followed by an avg-pooling layer as in NIN in place of by traditional fully connected layers. The difference between GoogleNet and NIN is that GoogleNet adds a fully connected layer after avg-pooling layer to output a vector of category size. Besides these two characteristics, the features from middle layers of a GoogleNet are also very discriminative. Therefore, GoogeleNet inserts two auxiliary classifiers in the model for enhancing gradient and regularization when doing backpropagating. The loss function of the whole network is the weighted sum of these three classifiers.

Figure 8 illustrates the neural architecture of a GoogleNet which consists of 22 layers: it starts with three regular convolutional layers followed by three groups of sub-networks-- the first group contains two Inception blocks, the second one five, and the third one two. It ends up with an average pooling and a fully-connected layer.

<p align="center">
<img src="image/googlenet.jpeg" ><br/>
Figure 8. GoogleNet[12]
</p>

The above model is the first version of GoogleNet or GoogelNet-v1. GoogleNet-v2 [14] introduces BN layer; GoogleNet-v3 [16] further splits some convolutional layers, which increases non-linearity and network depth; GoogelNet-v4 [17] leads to the design idea of ResNet which will be introduced in the next section. The evolution from v1 to v4 leverages the accuracy rate consistently. We will not go into details of the neural architectures of v2 to v4.

### ResNet

Residual Network(ResNet)[15] won the 2015 championships on three ImageNet competitions -- image classification, object localization and object detection. The authors of ResNet proposed a residual learning approach to easing the difficulty of training deeper networks -- with the network depth increasing, accuracy degrades. Based upon the design ideas of BN, small convolutional kernels, full convolutional network, ResNets reformulate the layers as residual blocks, with each block containing two branches, one directly connecting input to the output, the other performing two to three convolutions and calculating the residual function with reference to the layer inputs. And then the outputs of these two branches are added up.

Figure 9 illustrates the architecture of ResNet. The left is the basic building block consisting of two 3x3 convolutional layers of the same channels. The right one is a Bottleneck block. The bottleneck is a 1x1 convolutional layer used to reduce dimension from 256 to 64. The other 1x1 conolutional layer is used to increase dimension from 64 to 256. Therefore, the number of input and output channels of the middle 3x3 convolutional layer, which is 64, is relatively small.

<p align="center">
<img src="image/resnet_block.jpg" width="400"><br/>
Figure 9. Residual block
</p>

Figure 10 illustrates ResNets with 50, 101, 152 layers, respectively. All three networks use bottleneck blocks of different numbers of repetitions. ResNet converges very fast and can be trained with hundreds or thousands of layers.

<p align="center">
<img src="image/resnet.png"><br/>
Figure 10. ResNet model for ImageNet
</p>


L
liaogang 已提交
180
## Dataset
Y
Yi Wang 已提交
181 182 183

Commonly used public datasets for image classification are CIFAR(https://www.cs.toronto.edu/~kriz/cifar.html), ImageNet(http://image-net.org/), COCO(http://mscoco.org/), etc. Those used for fine-grained image classification are CUB-200-2011(http://www.vision.caltech.edu/visipedia/CUB-200-2011.html), Stanford Dog(http://vision.stanford.edu/aditya86/ImageNetDogs/), Oxford-flowers(http://www.robots.ox.ac.uk/~vgg/data/flowers/), etc. Among them, ImageNet are the largest and most research results are reported on ImageNet as mentioned in Model Overview section. Since 2010, the data of Imagenet has gone through some changes. The commonly used ImageNet-2012 dataset contains 1000 categories. There are 1,281,167 training images, ranging from 732 to 1200 images per category, and 50,000 validation images with 50 images per category in average.

L
liaogang 已提交
184
Since ImageNet is too large to be downloaded and trained efficiently, we use CIFAR-10 (https://www.cs.toronto.edu/~kriz/cifar.html) in this tutorial. The CIFAR-10 dataset consists of 60000 32x32 color images in 10 classes, with 6000 images per class. There are 50000 training images and 10000 test images. Figure 11 shows all the classes in CIFAR-10 as well as 10 images randomly sampled from each category.
Y
Yi Wang 已提交
185 186 187 188 189 190

<p align="center">
<img src="image/cifar.png" width="350"><br/>
Figure 11. CIFAR10 dataset[21]
</p>

L
liaogang 已提交
191
 `paddle.datasets` package encapsulates multiple public datasets, including `cifar`, `imdb`, `mnist`, `moivelens` and `wmt14`, etc. There's no need for us to manually download and preprocess CIFAR-10.
Y
Yi Wang 已提交
192

L
liaogang 已提交
193
After issuing a command `python train.py`, training will starting immediately. The details will be unpacked by the following sessions to see how it works.
Y
Yi Wang 已提交
194

L
liaogang 已提交
195
## Model Architecture
Y
Yi Wang 已提交
196

L
liaogang 已提交
197
### Initialize PaddlePaddle
Y
Yi Wang 已提交
198

L
liaogang 已提交
199
We must import and initialize PaddlePaddle (enable/disable GPU, set the number of trainers, etc).
Y
Yi Wang 已提交
200 201

```python
L
liaogang 已提交
202 203
import sys
import paddle.v2 as paddle
Y
Yi Wang 已提交
204

L
liaogang 已提交
205 206
# PaddlePaddle init
paddle.init(use_gpu=False, trainer_count=1)
Y
Yi Wang 已提交
207 208
```

L
liaogang 已提交
209
As alluded to in section [Model Overview](#model-overview), here we provide the implementations of both VGG and ResNet models.
Y
Yi Wang 已提交
210

L
liaogang 已提交
211
### VGG
Y
Yi Wang 已提交
212

L
liaogang 已提交
213
First, we use a VGG network. Since the image size and amount of CIFAR10 are relatively small comparing to ImageNet, we uses a small version of VGG network for CIFAR10. Convolution groups incorporate BN and dropout operations.
Y
Yi Wang 已提交
214 215 216

1. Define input data and its dimension

L
liaogang 已提交
217
        The input to the network is defined as `paddle.layer.data`, or image pixels in the context of image classification. The images in CIFAR10 are 32x32 color images of three channels. Therefore, the size of the input data is 3072 (3x32x32), and the number of categories is 10.
Y
Yi Wang 已提交
218

219 220 221
    ```python
    datadim = 3 * 32 * 32
    classdim = 10
L
liaogang 已提交
222 223
    image = paddle.layer.data(
        name="image", type=paddle.data_type.dense_vector(datadim))
224
    ```
Y
Yi Wang 已提交
225 226 227

2. Define VGG main module

228
    ```python
L
liaogang 已提交
229
    net = vgg_bn_drop(image)
230
    ```
L
liaogang 已提交
231
        The input to VGG main module is from the data layer. `vgg_bn_drop` defines a 16-layer VGG network, with each convolutional layer followed by BN and dropout layers. Here is the definition in detail:
Y
Yi Wang 已提交
232

233
    ```python
L
liaogang 已提交
234 235 236
    def vgg_bn_drop(input):
        def conv_block(ipt, num_filter, groups, dropouts, num_channels=None):
            return paddle.networks.img_conv_group(
237
                input=ipt,
L
liaogang 已提交
238
                num_channels=num_channels,
239 240 241 242
                pool_size=2,
                pool_stride=2,
                conv_num_filter=[num_filter] * groups,
                conv_filter_size=3,
L
liaogang 已提交
243
                conv_act=paddle.activation.Relu(),
244 245
                conv_with_batchnorm=True,
                conv_batchnorm_drop_rate=dropouts,
L
liaogang 已提交
246
                pool_type=paddle.pooling.Max())
247 248 249 250 251 252 253

        conv1 = conv_block(input, 64, 2, [0.3, 0], 3)
        conv2 = conv_block(conv1, 128, 2, [0.4, 0])
        conv3 = conv_block(conv2, 256, 3, [0.4, 0.4, 0])
        conv4 = conv_block(conv3, 512, 3, [0.4, 0.4, 0])
        conv5 = conv_block(conv4, 512, 3, [0.4, 0.4, 0])

L
liaogang 已提交
254 255 256 257 258 259 260
        drop = paddle.layer.dropout(input=conv5, dropout_rate=0.5)
        fc1 = paddle.layer.fc(input=drop, size=512, act=paddle.activation.Linear())
        bn = paddle.layer.batch_norm(
            input=fc1,
            act=paddle.activation.Relu(),
            layer_attr=paddle.attr.Extra(drop_rate=0.5))
        fc2 = paddle.layer.fc(input=bn, size=512, act=paddle.activation.Linear())
261 262
        return fc2
    ```
Y
Yi Wang 已提交
263

L
liaogang 已提交
264
        2.1. First defines a convolution block or conv_block. The default convolution kernel is 3x3, and the default pooling size is 2x2 with stride 2. Dropout specifies the probability in dropout operation. Function `img_conv_group` is defined in `paddle.networks` consisting of a series of `Conv->BN->ReLu->Dropout` and a `Pooling`.
Y
Yi Wang 已提交
265 266 267 268 269 270 271 272 273 274 275


        2.2. Five groups of convolutions. The first two groups perform two convolutions, while the last three groups perform three convolutions. The dropout rate of the last convolution in each group is set to 0, which means there is no dropout for this layer.


        2.3. The last two layers are fully-connected layer of dimension 512.

3. Define Classifier

        The above VGG network extracts high-level features and maps them to a vector of the same size as the categories. Softmax function or classifier is then used for calculating the probability of the image belonging to each category.

276 277 278
    ```python
    out = fc_layer(input=net, size=class_num, act=SoftmaxActivation())
    ```
Y
Yi Wang 已提交
279 280 281

4. Define Loss Function and Outputs

L
liaogang 已提交
282
        In the context of supervised learning, labels of training images are defined in `paddle.layer.data`, too. During training, cross-entropy is used as loss function and as the output of the network; During testing, the outputs are the probabilities calculated in the classifier.
Y
Yi Wang 已提交
283

284
    ```python
L
liaogang 已提交
285 286 287
    lbl = paddle.layer.data(
        name="label", type=paddle.data_type.integer_value(classdim))
    cost = paddle.layer.classification_cost(input=out, label=lbl)
288
    ```
Y
Yi Wang 已提交
289 290 291 292 293 294

### ResNet

The first, third and forth steps of a ResNet are the same as a VGG. The second one is the main module.

```python
L
liaogang 已提交
295
net = resnet_cifar10(data, depth=32)
Y
Yi Wang 已提交
296 297 298 299 300
```

Here are some basic functions used in `resnet_cifar10`:

  - `conv_bn_layer` : convolutional layer followed by BN.
L
liaogang 已提交
301
  - `shortcut` : the shortcut branch in a residual block. There are two kinds of shortcuts: 1x1 convolution used when the number of channels between input and output is different; direct connection used otherwise.
Y
Yi Wang 已提交
302 303 304 305 306 307 308 309 310 311 312

  - `basicblock` : a basic residual module as shown in the left of Figure 9, consisting of two sequential 3x3 convolutions and one "shortcut" branch.
  - `bottleneck` : a bottleneck module as shown in the right of Figure 9, consisting of a two 1x1 convolutions with one 3x3 convolution in between branch and a "shortcut" branch.
  - `layer_warp` : a group of residual modules consisting of several stacking blocks. In each group, the sliding window size of the first residual block could be different from the rest of blocks, in order to reduce the size of feature maps along horizontal and vertical directions.

```python
def conv_bn_layer(input,
                  ch_out,
                  filter_size,
                  stride,
                  padding,
L
liaogang 已提交
313
                  active_type=paddle.activation.Relu(),
Y
Yi Wang 已提交
314
                  ch_in=None):
L
liaogang 已提交
315
    tmp = paddle.layer.img_conv(
Y
Yi Wang 已提交
316 317 318 319 320 321
        input=input,
        filter_size=filter_size,
        num_channels=ch_in,
        num_filters=ch_out,
        stride=stride,
        padding=padding,
L
liaogang 已提交
322
        act=paddle.activation.Linear(),
Y
Yi Wang 已提交
323
        bias_attr=False)
L
liaogang 已提交
324
    return paddle.layer.batch_norm(input=tmp, act=active_type)
Y
Yi Wang 已提交
325 326 327

def shortcut(ipt, n_in, n_out, stride):
    if n_in != n_out:
L
liaogang 已提交
328 329
        return conv_bn_layer(ipt, n_out, 1, stride, 0,
                             paddle.activation.Linear())
Y
Yi Wang 已提交
330 331 332 333
    else:
        return ipt

def basicblock(ipt, ch_out, stride):
L
liaogang 已提交
334
    ch_in = ch_out * 2
Y
Yi Wang 已提交
335
    tmp = conv_bn_layer(ipt, ch_out, 3, stride, 1)
L
liaogang 已提交
336
    tmp = conv_bn_layer(tmp, ch_out, 3, 1, 1, paddle.activation.Linear())
Y
Yi Wang 已提交
337
    short = shortcut(ipt, ch_in, ch_out, stride)
L
liaogang 已提交
338
    return paddle.layer.addto(input=[tmp, short], act=paddle.activation.Relu())
Y
Yi Wang 已提交
339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355

def layer_warp(block_func, ipt, features, count, stride):
    tmp = block_func(ipt, features, stride)
    for i in range(1, count):
        tmp = block_func(tmp, features, 1)
    return tmp
```

The following are the components of `resnet_cifar10`:

1. The lowest level is `conv_bn_layer`.
2. The middle level consists of three `layer_warp`, each of which uses the left residual block in Figure 9.
3. The last level is average pooling layer.

Note: besides the first convolutional layer and the last fully-connected layer, the total number of layers in three `layer_warp` should be dividable by 6, that is the depth of `resnet_cifar10` should satisfy $(depth - 2) % 6 == 0$.

```python
L
liaogang 已提交
356
def resnet_cifar10(ipt, depth=32):
Y
Yi Wang 已提交
357 358 359 360
    # depth should be one of 20, 32, 44, 56, 110, 1202
    assert (depth - 2) % 6 == 0
    n = (depth - 2) / 6
    nStages = {16, 64, 128}
L
liaogang 已提交
361 362
    conv1 = conv_bn_layer(
        ipt, ch_in=3, ch_out=16, filter_size=3, stride=1, padding=1)
Y
Yi Wang 已提交
363 364 365
    res1 = layer_warp(basicblock, conv1, 16, n, 1)
    res2 = layer_warp(basicblock, res1, 32, n, 2)
    res3 = layer_warp(basicblock, res2, 64, n, 2)
L
liaogang 已提交
366 367
    pool = paddle.layer.img_pool(
        input=res3, pool_size=8, stride=1, pool_type=paddle.pooling.Avg())
Y
Yi Wang 已提交
368 369 370 371 372
    return pool
```

## Model Training

L
liaogang 已提交
373
### Define Parameters
Y
Yi Wang 已提交
374

L
liaogang 已提交
375
First, we create the model parameters according to the previous model configuration `cost`.
Y
Yi Wang 已提交
376

L
liaogang 已提交
377 378 379
```python
# Create parameters
parameters = paddle.parameters.create(cost)
Y
Yi Wang 已提交
380 381
```

L
liaogang 已提交
382
### Create Trainer
Y
Yi Wang 已提交
383

L
liaogang 已提交
384 385
Before jumping into creating a training module, algorithm setting is also necessary.
Here we specified `Momentum` optimization algorithm via `paddle.optimizer`.
Y
Yi Wang 已提交
386

L
liaogang 已提交
387 388 389 390 391 392 393 394 395 396 397 398 399 400 401
```python
# Create optimizer
momentum_optimizer = paddle.optimizer.Momentum(
    momentum=0.9,
    regularization=paddle.optimizer.L2Regularization(rate=0.0002 * 128),
    learning_rate=0.1 / 128.0,
    learning_rate_decay_a=0.1,
    learning_rate_decay_b=50000 * 100,
    learning_rate_schedule='discexp',
    batch_size=128)

# Create trainer
trainer = paddle.trainer.SGD(cost=cost,
                             parameters=parameters,
                             update_equation=momentum_optimizer)
Y
Yi Wang 已提交
402 403
```

L
liaogang 已提交
404 405 406
The learning rate adjustment policy can be defined with variables `learning_rate_decay_a`($a$), `learning_rate_decay_b`($b$) and `learning_rate_schedule`. In this example, discrete exponential method is used for adjusting learning rate. The formula is as follows,
$$  lr = lr_{0} * a^ {\lfloor \frac{n}{ b}\rfloor} $$
where $n$ is the number of processed samples, $lr_{0}$ is the learning_rate.
Y
Yi Wang 已提交
407

L
liaogang 已提交
408
### Training
Y
Yi Wang 已提交
409

L
liaogang 已提交
410
`cifar.train10()` will yield records during each pass, after shuffling, a batch input is generated for training.
Y
Yi Wang 已提交
411

L
liaogang 已提交
412 413 414 415 416 417 418 419 420
```python
reader=paddle.reader.batch(
    paddle.reader.shuffle(
        paddle.dataset.cifar.train10(), buf_size=50000),
        batch_size=128)
```

`feeding` is devoted to specifying the correspondence between each yield record and `paddle.layer.data`. For instance,
 the first column of data generated by `cifar.train10()` corresponds to image layer's feature.
Y
Yi Wang 已提交
421

L
liaogang 已提交
422 423 424 425
```python
feeding={'image': 0,
         'label': 1}
```
Y
Yi Wang 已提交
426

L
liaogang 已提交
427
Callback function `event_handler` will be called during training when a pre-defined event happens.
Y
Yi Wang 已提交
428 429


L
liaogang 已提交
430 431 432 433 434 435 436 437 438 439 440 441 442 443 444 445 446
```python
# event handler to track training and testing process
def event_handler(event):
    if isinstance(event, paddle.event.EndIteration):
        if event.batch_id % 100 == 0:
            print "\nPass %d, Batch %d, Cost %f, %s" % (
                event.pass_id, event.batch_id, event.cost, event.metrics)
        else:
            sys.stdout.write('.')
            sys.stdout.flush()
    if isinstance(event, paddle.event.EndPass):
        result = trainer.test(
            reader=paddle.reader.batch(
                paddle.dataset.cifar.test10(), batch_size=128),
            reader_dict={'image': 0,
                         'label': 1})
        print "\nTest with Pass %d, %s" % (event.pass_id, result.metrics)
Y
Yi Wang 已提交
447 448
```

L
liaogang 已提交
449
Finally, we can invoke `trainer.train` to start training:
Y
Yi Wang 已提交
450

L
liaogang 已提交
451 452 453 454 455 456
```python
trainer.train(
    reader=reader,
    num_passes=200,
    event_handler=event_handler,
    feeding=feeding)
Y
Yi Wang 已提交
457 458
```

L
liaogang 已提交
459
Here is an example log after training for one pass. The average error rates are 0.6875 on the training set and 0.8852 on the validation set.
Y
Yi Wang 已提交
460

L
liaogang 已提交
461 462 463 464 465 466 467 468 469 470
```text
Pass 0, Batch 0, Cost 2.473182, {'classification_error_evaluator': 0.9140625}
...................................................................................................
Pass 0, Batch 100, Cost 1.913076, {'classification_error_evaluator': 0.78125}
...................................................................................................
Pass 0, Batch 200, Cost 1.783041, {'classification_error_evaluator': 0.7421875}
...................................................................................................
Pass 0, Batch 300, Cost 1.668833, {'classification_error_evaluator': 0.6875}
..........................................................................................
Test with Pass 0, {'classification_error_evaluator': 0.885200023651123}
Y
Yi Wang 已提交
471 472
```

L
liaogang 已提交
473
Figure 12 shows the curve of training error rate, which indicates it converges at Pass 200 with error rate 8.54%.
Y
Yi Wang 已提交
474
<p align="center">
L
liaogang 已提交
475 476
<img src="image/plot_en.png" width="400" ><br/>
Figure 12. The error rate of VGG model on CIFAR10
Y
Yi Wang 已提交
477 478
</p>

L
liaogang 已提交
479 480 481

After training is done, the model from each pass is saved in `output/pass-%05d`. For example, the model of Pass 300 is saved in `output/pass-00299`.

Y
Yi Wang 已提交
482 483 484 485 486 487 488 489 490 491 492 493 494 495 496 497 498 499 500 501 502 503 504 505 506 507 508 509 510 511 512 513 514 515 516 517 518 519 520 521 522 523 524 525 526 527 528 529 530 531 532 533 534
## Conclusion

Traditional image classification methods involve multiple stages of processing and the framework is very complicated. In contrast, CNN models can be trained end-to-end with significant increase of classification accuracy. In this chapter, we introduce three models -- VGG, GoogleNet, ResNet, provide PaddlePaddle config files for training VGG and ResNet on CIFAR10, and explain how to perform prediction and feature extraction using PaddlePaddle API. For other datasets such as ImageNet, the procedure for config and training are the same and you are welcome to give it a try.


## Reference

[1] D. G. Lowe, [Distinctive image features from scale-invariant keypoints](http://www.cs.ubc.ca/~lowe/papers/ijcv04.pdf). IJCV, 60(2):91-110, 2004.

[2] N. Dalal, B. Triggs, [Histograms of Oriented Gradients for Human Detection](http://vision.stanford.edu/teaching/cs231b_spring1213/papers/CVPR05_DalalTriggs.pdf), Proc. IEEE Conf. Computer Vision and Pattern Recognition, 2005.

[3] Ahonen, T., Hadid, A., and Pietikinen, M. (2006). [Face description with local binary patterns: Application to face recognition](http://ieeexplore.ieee.org/document/1717463/). PAMI, 28.

[4] J. Sivic, A. Zisserman, [Video Google: A Text Retrieval Approach to Object Matching in Videos](http://www.robots.ox.ac.uk/~vgg/publications/papers/sivic03.pdf), Proc. Ninth Int'l Conf. Computer Vision, pp. 1470-1478, 2003.

[5] B. Olshausen, D. Field, [Sparse Coding with an Overcomplete Basis Set: A Strategy Employed by V1?](http://redwood.psych.cornell.edu/papers/olshausen_field_1997.pdf), Vision Research, vol. 37, pp. 3311-3325, 1997.

[6] Wang, J., Yang, J., Yu, K., Lv, F., Huang, T., and Gong, Y. (2010). [Locality-constrained Linear Coding for image classification](http://ieeexplore.ieee.org/abstract/document/5540018/). In CVPR.

[7] Perronnin, F., Sánchez, J., & Mensink, T. (2010). [Improving the fisher kernel for large-scale image classification](http://dl.acm.org/citation.cfm?id=1888101). In ECCV (4).

[8] Lin, Y., Lv, F., Cao, L., Zhu, S., Yang, M., Cour, T., Yu, K., and Huang, T. (2011). [Large-scale image clas- sification: Fast feature extraction and SVM training](http://ieeexplore.ieee.org/document/5995477/). In CVPR.

[9] Krizhevsky, A., Sutskever, I., and Hinton, G. (2012). [ImageNet classification with deep convolutional neu- ral networks](http://www.cs.toronto.edu/~kriz/imagenet_classification_with_deep_convolutional.pdf). In NIPS.

[10] G.E. Hinton, N. Srivastava, A. Krizhevsky, I. Sutskever, and R.R. Salakhutdinov. [Improving neural networks by preventing co-adaptation of feature detectors](https://arxiv.org/abs/1207.0580). arXiv preprint arXiv:1207.0580, 2012.

[11] K. Chatfield, K. Simonyan, A. Vedaldi, A. Zisserman. [Return of the Devil in the Details: Delving Deep into Convolutional Nets](https://arxiv.org/abs/1405.3531). BMVC, 2014。

[12] Szegedy, C., Liu, W., Jia, Y., Sermanet, P., Reed, S., Anguelov, D., Erhan, D., Vanhoucke, V., Rabinovich, A., [Going deeper with convolutions](https://arxiv.org/abs/1409.4842). In: CVPR. (2015)

[13] Lin, M., Chen, Q., and Yan, S. [Network in network](https://arxiv.org/abs/1312.4400). In Proc. ICLR, 2014.

[14] S. Ioffe and C. Szegedy. [Batch normalization: Accelerating deep network training by reducing internal covariate shift](https://arxiv.org/abs/1502.03167). In ICML, 2015.

[15] K. He, X. Zhang, S. Ren, J. Sun. [Deep Residual Learning for Image Recognition](https://arxiv.org/abs/1512.03385). CVPR 2016.

[16] Szegedy, C., Vanhoucke, V., Ioffe, S., Shlens, J., Wojna, Z. [Rethinking the incep-tion architecture for computer vision](https://arxiv.org/abs/1512.00567). In: CVPR. (2016).

[17] Szegedy, C., Ioffe, S., Vanhoucke, V. [Inception-v4, inception-resnet and the impact of residual connections on learning](https://arxiv.org/abs/1602.07261). arXiv:1602.07261 (2016).

[18] Everingham, M., Eslami, S. M. A., Van Gool, L., Williams, C. K. I., Winn, J. and Zisserman, A. [The Pascal Visual Object Classes Challenge: A Retrospective]((http://link.springer.com/article/10.1007/s11263-014-0733-5)). International Journal of Computer Vision, 111(1), 98-136, 2015.

[19] He, K., Zhang, X., Ren, S., and Sun, J. [Delving Deep into Rectifiers: Surpassing Human-Level Performance on ImageNet Classification](https://arxiv.org/abs/1502.01852). ArXiv e-prints, February 2015.

[20] http://deeplearning.net/tutorial/lenet.html

[21] https://www.cs.toronto.edu/~kriz/cifar.html

[22] http://cs231n.github.io/classification/

<br/>
<a rel="license" href="http://creativecommons.org/licenses/by-nc-sa/4.0/"><img alt="知识共享许可协议" style="border-width:0" src="https://i.creativecommons.org/l/by-nc-sa/4.0/88x31.png" /></a><br /><span xmlns:dct="http://purl.org/dc/terms/" href="http://purl.org/dc/dcmitype/Text" property="dct:title" rel="dct:type">本教程</span><a xmlns:cc="http://creativecommons.org/ns#" href="http://book.paddlepaddle.org" property="cc:attributionName" rel="cc:attributionURL">PaddlePaddle</a> 创作,采用 <a rel="license" href="http://creativecommons.org/licenses/by-nc-sa/4.0/">知识共享 署名-非商业性使用-相同方式共享 4.0 国际 许可协议</a>进行许可。
535

Y
Yi Wang 已提交
536 537 538 539 540 541 542 543 544 545 546 547 548 549 550 551 552 553
</div>
<!-- You can change the lines below now. -->

<script type="text/javascript">
marked.setOptions({
  renderer: new marked.Renderer(),
  gfm: true,
  breaks: false,
  smartypants: true,
  highlight: function(code, lang) {
    code = code.replace(/&amp;/g, "&")
    code = code.replace(/&gt;/g, ">")
    code = code.replace(/&lt;/g, "<")
    code = code.replace(/&nbsp;/g, " ")
    return hljs.highlightAuto(code, [lang]).value;
  }
});
document.getElementById("context").innerHTML = marked(
554
        document.getElementById("markdown").innerHTML)
Y
Yi Wang 已提交
555 556
</script>
</body>