Image Classification

In this project, you'll classify images from the CIFAR-10 dataset. The dataset consists of airplanes, dogs, cats, and other objects. You'll preprocess the images, then train a convolutional neural network on all the samples. The images need to be normalized and the labels need to be one-hot encoded. You'll get to apply what you learned and build a convolutional, max pooling, dropout, and fully connected layers. At the end, you'll get to see your neural network's predictions on the sample images.

Get the Data

Run the following cell to download the CIFAR-10 dataset for python.



In [1]:

    
"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
from urllib.request import urlretrieve
from os.path import isfile, isdir
from tqdm import tqdm
import problem_unittests as tests
import tarfile

cifar10_dataset_folder_path = 'cifar-10-batches-py'

# Use Floyd's cifar-10 dataset if present
floyd_cifar10_location = '/input/cifar-10/python.tar.gz'
if isfile(floyd_cifar10_location):
    tar_gz_path = floyd_cifar10_location
else:
    tar_gz_path = 'cifar-10-python.tar.gz'

class DLProgress(tqdm):
    last_block = 0

    def hook(self, block_num=1, block_size=1, total_size=None):
        self.total = total_size
        self.update((block_num - self.last_block) * block_size)
        self.last_block = block_num

if not isfile(tar_gz_path):
    with DLProgress(unit='B', unit_scale=True, miniters=1, desc='CIFAR-10 Dataset') as pbar:
        urlretrieve(
            'https://www.cs.toronto.edu/~kriz/cifar-10-python.tar.gz',
            tar_gz_path,
            pbar.hook)

if not isdir(cifar10_dataset_folder_path):
    with tarfile.open(tar_gz_path) as tar:
        tar.extractall()
        tar.close()


tests.test_folder_path(cifar10_dataset_folder_path)









    



CIFAR-10 Dataset: 171MB [04:40, 607KB/s]                           






    



All files found!

Explore the Data

The dataset is broken into batches to prevent your machine from running out of memory. The CIFAR-10 dataset consists of 5 batches, named data_batch_1, data_batch_2, etc.. Each batch contains the labels and images that are one of the following:

airplane
automobile
bird
cat
deer
dog
frog
horse
ship
truck

Understanding a dataset is part of making predictions on the data. Play around with the code cell below by changing the batch_id and sample_id. The batch_id is the id for a batch (1-5). The sample_id is the id for a image and label pair in the batch.

Ask yourself "What are all possible labels?", "What is the range of values for the image data?", "Are the labels in order or random?". Answers to questions like these will help you preprocess the data and end up with better predictions.



In [2]:

    
%matplotlib inline
%config InlineBackend.figure_format = 'retina'

import helper
import numpy as np

# Explore the dataset
batch_id = 1
sample_id = 5
helper.display_stats(cifar10_dataset_folder_path, batch_id, sample_id)









    



Stats of batch 1:
Samples: 10000
Label Counts: {0: 1005, 1: 974, 2: 1032, 3: 1016, 4: 999, 5: 937, 6: 1030, 7: 1001, 8: 1025, 9: 981}
First 20 Labels: [6, 9, 9, 4, 1, 1, 2, 7, 8, 3, 4, 7, 7, 2, 9, 9, 9, 3, 2, 6]

Example of Image 5:
Image - Min Value: 0 Max Value: 252
Image - Shape: (32, 32, 3)
Label - Label Id: 1 Name: automobile

Implement Preprocess Functions

Normalize

In the cell below, implement the normalize function to take in image data, x, and return it as a normalized Numpy array. The values should be in the range of 0 to 1, inclusive. The return object should be the same shape as x.



In [3]:

    
def normalize(x):
    """
    Normalize a list of sample image data in the range of 0 to 1
    : x: List of image data.  The image shape is (32, 32, 3)
    : return: Numpy array of normalize data
    """
    # TODO: Implement Function
    return np.divide(x,255)


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_normalize(normalize)









    



Tests Passed

One-hot encode

Just like the previous code cell, you'll be implementing a function for preprocessing. This time, you'll implement the one_hot_encode function. The input, x, are a list of labels. Implement the function to return the list of labels as One-Hot encoded Numpy array. The possible values for labels are 0 to 9. The one-hot encoding function should return the same encoding for each value between each call to one_hot_encode. Make sure to save the map of encodings outside the function.

Hint: Don't reinvent the wheel.



In [4]:

    
one_hot = np.eye(10, dtype=int) 

def one_hot_encode(x):
    """
    One hot encode a list of sample labels. Return a one-hot encoded vector for each label.
    : x: List of sample Labels
    : return: Numpy array of one-hot encoded labels
    """
    # TODO: Implement Function
    return one_hot[x]


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_one_hot_encode(one_hot_encode)









    



Tests Passed

Randomize Data

As you saw from exploring the data above, the order of the samples are randomized. It doesn't hurt to randomize it again, but you don't need to for this dataset.

Preprocess all the data and save it

Running the code cell below will preprocess all the CIFAR-10 data and save it to file. The code below also uses 10% of the training data for validation.



In [5]:

    
"""
DON'T MODIFY ANYTHING IN THIS CELL
"""
# Preprocess Training, Validation, and Testing Data
helper.preprocess_and_save_data(cifar10_dataset_folder_path, normalize, one_hot_encode)

Check Point

This is your first checkpoint. If you ever decide to come back to this notebook or have to restart the notebook, you can start from here. The preprocessed data has been saved to disk.



In [6]:

    
"""
DON'T MODIFY ANYTHING IN THIS CELL
"""
import pickle
import problem_unittests as tests
import helper

# Load the Preprocessed Validation data
valid_features, valid_labels = pickle.load(open('preprocess_validation.p', mode='rb'))

Build the network

For the neural network, you'll build each layer into a function. Most of the code you've seen has been outside of functions. To test your code more thoroughly, we require that you put each layer in a function. This allows us to give you better feedback and test for simple mistakes using our unittests before you submit your project.

Note: If you're finding it hard to dedicate enough time for this course each week, we've provided a small shortcut to this part of the project. In the next couple of problems, you'll have the option to use classes from the TensorFlow Layers or TensorFlow Layers (contrib) packages to build each layer, except the layers you build in the "Convolutional and Max Pooling Layer" section. TF Layers is similar to Keras's and TFLearn's abstraction to layers, so it's easy to pickup.

However, if you would like to get the most out of this course, try to solve all the problems without using anything from the TF Layers packages. You can still use classes from other packages that happen to have the same name as ones you find in TF Layers! For example, instead of using the TF Layers version of the conv2d class, tf.layers.conv2d, you would want to use the TF Neural Network version of conv2d, tf.nn.conv2d.

Let's begin!

Input

The neural network needs to read the image data, one-hot encoded labels, and dropout keep probability. Implement the following functions

Implement neural_net_image_input
- Return a TF Placeholder
- Set the shape using image_shape with batch size set to None.
- Name the TensorFlow placeholder "x" using the TensorFlow name parameter in the TF Placeholder.
Implement neural_net_label_input
- Return a TF Placeholder
- Set the shape using n_classes with batch size set to None.
- Name the TensorFlow placeholder "y" using the TensorFlow name parameter in the TF Placeholder.
Implement neural_net_keep_prob_input
- Return a TF Placeholder for dropout keep probability.
- Name the TensorFlow placeholder "keep_prob" using the TensorFlow name parameter in the TF Placeholder.

These names will be used at the end of the project to load your saved model.

Note: None for shapes in TensorFlow allow for a dynamic size.



In [7]:

    
import tensorflow as tf

def neural_net_image_input(image_shape):
    """
    Return a Tensor for a batch of image input
    : image_shape: Shape of the images
    : return: Tensor for image input.
    """
    # TODO: Implement Function
    return tf.placeholder(tf.float32, [None, image_shape[0], image_shape[1], image_shape[2]], name="x")


def neural_net_label_input(n_classes):
    """
    Return a Tensor for a batch of label input
    : n_classes: Number of classes
    : return: Tensor for label input.
    """
    # TODO: Implement Function
    return tf.placeholder(tf.int32, [None, n_classes], name="y")


def neural_net_keep_prob_input():
    """
    Return a Tensor for keep probability
    : return: Tensor for keep probability.
    """
    # TODO: Implement Function
    return tf.placeholder(tf.float32, name="keep_prob")


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tf.reset_default_graph()
tests.test_nn_image_inputs(neural_net_image_input)
tests.test_nn_label_inputs(neural_net_label_input)
tests.test_nn_keep_prob_inputs(neural_net_keep_prob_input)









    



Image Input Tests Passed.
Label Input Tests Passed.
Keep Prob Tests Passed.

Convolution and Max Pooling Layer

Convolution layers have a lot of success with images. For this code cell, you should implement the function conv2d_maxpool to apply convolution then max pooling:

Create the weight and bias using conv_ksize, conv_num_outputs and the shape of x_tensor.
Apply a convolution to x_tensor using weight and conv_strides.
- We recommend you use same padding, but you're welcome to use any padding.
Add bias
Add a nonlinear activation to the convolution.
Apply Max Pooling using pool_ksize and pool_strides.
- We recommend you use same padding, but you're welcome to use any padding.

Note: You can't use TensorFlow Layers or TensorFlow Layers (contrib) for this layer, but you can still use TensorFlow's Neural Network package. You may still use the shortcut option for all the other layers.



In [8]:

    
def conv2d_maxpool(x_tensor, conv_num_outputs, conv_ksize, conv_strides, pool_ksize, pool_strides):
    """
    Apply convolution then max pooling to x_tensor
    :param x_tensor: TensorFlow Tensor
    :param conv_num_outputs: Number of outputs for the convolutional layer
    :param conv_ksize: kernal size 2-D Tuple for the convolutional layer
    :param conv_strides: Stride 2-D Tuple for convolution
    :param pool_ksize: kernal size 2-D Tuple for pool
    :param pool_strides: Stride 2-D Tuple for pool
    : return: A tensor that represents convolution and max pooling of x_tensor
    """
    #it does make difference if we don't specify the mean and stddev parameters.
    weights = tf.Variable(tf.truncated_normal(shape=(*conv_ksize, x_tensor.get_shape().as_list()[-1], conv_num_outputs), mean=0, stddev=0.1))
    bias = tf.Variable(tf.zeros(conv_num_outputs))
    #apply convolution
    conv_layer = tf.nn.conv2d(x_tensor, weights, strides = [1, *conv_strides ,1], padding = 'SAME')
    #add bias
    conv_layer = tf.nn.bias_add(conv_layer,bias)
    #apply activation function
    conv_layer = tf.nn.relu(conv_layer)
    #apply max pooling
    conv_layer = tf.nn.max_pool(conv_layer, ksize = [1, *pool_ksize, 1], strides = [1,*pool_strides, 1], padding='SAME')
    
    return conv_layer


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_con_pool(conv2d_maxpool)









    



Tests Passed

Flatten Layer

Implement the flatten function to change the dimension of x_tensor from a 4-D tensor to a 2-D tensor. The output should be the shape (Batch Size, Flattened Image Size). Shortcut option: you can use classes from the TensorFlow Layers or TensorFlow Layers (contrib) packages for this layer. For more of a challenge, only use other TensorFlow packages.



In [9]:

    
def flatten(x_tensor):
    """
    Flatten x_tensor to (Batch Size, Flattened Image Size)
    : x_tensor: A tensor of size (Batch Size, ...), where ... are the image dimensions.
    : return: A tensor of size (Batch Size, Flattened Image Size).
    """
    # TODO: Implement Function    
    xt_shape = x_tensor.get_shape().as_list()
    return tf.reshape(x_tensor, [-1,xt_shape[1]*xt_shape[2]*xt_shape[3]])


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_flatten(flatten)









    



Tests Passed

Fully-Connected Layer

Implement the fully_conn function to apply a fully connected layer to x_tensor with the shape (Batch Size, num_outputs). Shortcut option: you can use classes from the TensorFlow Layers or TensorFlow Layers (contrib) packages for this layer. For more of a challenge, only use other TensorFlow packages.



In [19]:

    
def fully_conn(x_tensor, num_outputs):
    """
    Apply a fully connected layer to x_tensor using weight and bias
    : x_tensor: A 2-D tensor where the first dimension is batch size.
    : num_outputs: The number of output that the new tensor should be.
    : return: A 2-D tensor where the second dimension is num_outputs.
    """
    # TODO: Implement Function
    #calculate weights and biases
    xt_shape = x_tensor.get_shape().as_list()
    weights = tf.Variable(tf.truncated_normal((xt_shape[1], num_outputs), mean=0, stddev=0.1))
    biases = tf.zeros(num_outputs)
    
    #apply weights
    layer = tf.matmul(x_tensor, weights)
    layer = tf.add(layer, biases)
    
    #apply nonlinear activation function
    layer = tf.nn.relu(layer)
    return layer

"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_fully_conn(fully_conn)









    



Tests Passed

Output Layer

Implement the output function to apply a fully connected layer to x_tensor with the shape (Batch Size, num_outputs). Shortcut option: you can use classes from the TensorFlow Layers or TensorFlow Layers (contrib) packages for this layer. For more of a challenge, only use other TensorFlow packages.

Note: Activation, softmax, or cross entropy should not be applied to this.



In [20]:

    
def output(x_tensor, num_outputs):
    """
    Apply a output layer to x_tensor using weight and bias
    : x_tensor: A 2-D tensor where the first dimension is batch size.
    : num_outputs: The number of output that the new tensor should be.
    : return: A 2-D tensor where the second dimension is num_outputs.
    """
    # TODO: Implement Function
    xt_shape = x_tensor.get_shape().as_list()
    weights = tf.Variable(tf.truncated_normal((xt_shape[1], num_outputs), mean=0, stddev=0.1))
    layer = tf.matmul(x_tensor, weights)
    return layer


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_output(output)









    



Tests Passed

Create Convolutional Model

Implement the function conv_net to create a convolutional neural network model. The function takes in a batch of images, x, and outputs logits. Use the layers you created above to create this model:

Apply 1, 2, or 3 Convolution and Max Pool layers
Apply a Flatten Layer
Apply 1, 2, or 3 Fully Connected Layers
Apply an Output Layer
Return the output
Apply TensorFlow's Dropout to one or more layers in the model using keep_prob.



In [21]:

    
def conv_net(x, keep_prob):
    """
    Create a convolutional neural network model
    : x: Placeholder tensor that holds image data.
    : keep_prob: Placeholder tensor that hold dropout keep probability.
    : return: Tensor that represents logits
    """
    # TODO: Apply 1, 2, or 3 Convolution and Max Pool layers
    #    Play around with different number of outputs, kernel size and stride
    # Function Definition from Above:
    #    conv2d_maxpool(x_tensor, conv_num_outputs, conv_ksize, conv_strides, pool_ksize, pool_strides) 
    x_shape = x.get_shape().as_list()
    
    #first convolution layer input
#     original_size = [32,32]
    conv_ksize = [5,5]
    conv_strides = [1,1]
    pool_ksize = [2,2]
    pool_strides = [2,2]                            
    conv1 = conv2d_maxpool(x, 32, conv_ksize, conv_strides, pool_ksize, pool_strides)

    #convolution layer input
    #1x1 convolution with 1x1 max polling :)
    conv4_ksize = [1,1]
    conv4_strides = [1,1]
    pool4_ksize = [1,1]
    pool4_strides = [1,1]
    conv4 = conv2d_maxpool(conv1, 32, conv4_ksize, conv4_strides, pool4_ksize, pool4_strides)
    
    # TODO: Apply a Flatten Layer
    # Function Definition from Above:
    flat = flatten(conv4)
    

    # TODO: Apply 1, 2, or 3 Fully Connected Layers
    #    Play around with different number of outputs
    # Function Definition from Above:
    fc1 = fully_conn(flat, 128)
    fc1 = tf.nn.dropout(fc1, keep_prob=keep_prob)
    fc2 = fully_conn(fc1, 64)
    fc2 = tf.nn.dropout(fc2, keep_prob=keep_prob)
    
    # TODO: Apply an Output Layer
    #    Set this to the number of classes
    # Function Definition from Above:
    out = output(fc2, 10)
    
    
    # TODO: return output
    return out


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""

##############################
## Build the Neural Network ##
##############################

# Remove previous weights, bias, inputs, etc..
tf.reset_default_graph()

# Inputs
x = neural_net_image_input((32, 32, 3))
y = neural_net_label_input(10)
keep_prob = neural_net_keep_prob_input()

# Model
logits = conv_net(x, keep_prob)

# Name logits Tensor, so that is can be loaded from disk after training
logits = tf.identity(logits, name='logits')

# Loss and Optimizer
cost = tf.reduce_mean(tf.nn.softmax_cross_entropy_with_logits(logits=logits, labels=y))
optimizer = tf.train.AdamOptimizer().minimize(cost)

# Accuracy
correct_pred = tf.equal(tf.argmax(logits, 1), tf.argmax(y, 1))
accuracy = tf.reduce_mean(tf.cast(correct_pred, tf.float32), name='accuracy')

tests.test_conv_net(conv_net)









    



Neural Network Built!

Train the Neural Network

Single Optimization

Implement the function train_neural_network to do a single optimization. The optimization should use optimizer to optimize in session with a feed_dict of the following:

x for image input
y for labels
keep_prob for keep probability for dropout

This function will be called for each batch, so tf.global_variables_initializer() has already been called.

Note: Nothing needs to be returned. This function is only optimizing the neural network.



In [22]:

    
def train_neural_network(session, optimizer, keep_probability, feature_batch, label_batch):
    """
    Optimize the session on a batch of images and labels
    : session: Current TensorFlow session
    : optimizer: TensorFlow optimizer function
    : keep_probability: keep probability
    : feature_batch: Batch of Numpy image data
    : label_batch: Batch of Numpy label data
    """
    # TODO: Implement Function
    session.run(optimizer, feed_dict={
                x: feature_batch,
                y: label_batch,
                keep_prob: keep_probability})


"""
DON'T MODIFY ANYTHING IN THIS CELL THAT IS BELOW THIS LINE
"""
tests.test_train_nn(train_neural_network)









    



Tests Passed

Show Stats

Implement the function print_stats to print loss and validation accuracy. Use the global variables valid_features and valid_labels to calculate validation accuracy. Use a keep probability of 1.0 to calculate the loss and validation accuracy.



In [23]:

    
def print_stats(session, feature_batch, label_batch, cost, accuracy):
    """
    Print information about loss and validation accuracy
    : session: Current TensorFlow session
    : feature_batch: Batch of Numpy image data
    : label_batch: Batch of Numpy label data
    : cost: TensorFlow cost function
    : accuracy: TensorFlow accuracy function
    """
    # TODO: Implement Function
    loss = session.run(cost, feed_dict = 
                   {x: feature_batch,y: label_batch, keep_prob: 1.0})
    acc = session.run(accuracy,feed_dict = 
                  {x: valid_features, y: valid_labels, keep_prob: 1.0})
    print('Loss at {}'.format(loss), 'Validation Accuracy at {}'.format(acc))

Hyperparameters

Tune the following parameters:

Set epochs to the number of iterations until the network stops learning or start overfitting
Set batch_size to the highest number that your machine has memory for. Most people set them to common sizes of memory:
- 64
- 128
- 256
- ...
Set keep_probability to the probability of keeping a node using dropout



In [24]:

    
# TODO: Tune Parameters
epochs = 10
batch_size = 128
keep_probability = 0.5

Train on a Single CIFAR-10 Batch

Instead of training the neural network on all the CIFAR-10 batches of data, let's use a single batch. This should save time while you iterate on the model to get a better accuracy. Once the final validation accuracy is 50% or greater, run the model on all the data in the next section.



In [25]:

    
"""
DON'T MODIFY ANYTHING IN THIS CELL
"""
print('Checking the Training on a Single Batch...')
with tf.Session() as sess:
    # Initializing the variables
    sess.run(tf.global_variables_initializer())
    
    # Training cycle
    for epoch in range(epochs):
        batch_i = 1
        for batch_features, batch_labels in helper.load_preprocess_training_batch(batch_i, batch_size):
            train_neural_network(sess, optimizer, keep_probability, batch_features, batch_labels)
        print('Epoch {:>2}, CIFAR-10 Batch {}:  '.format(epoch + 1, batch_i), end='')
        print_stats(sess, batch_features, batch_labels, cost, accuracy)









    



Checking the Training on a Single Batch...
Epoch  1, CIFAR-10 Batch 1:  Loss at 2.1034278869628906 Validation Accuracy at 0.2662000060081482
Epoch  2, CIFAR-10 Batch 1:  Loss at 1.984605073928833 Validation Accuracy at 0.3779999911785126
Epoch  3, CIFAR-10 Batch 1:  Loss at 1.8798420429229736 Validation Accuracy at 0.415800005197525
Epoch  4, CIFAR-10 Batch 1:  Loss at 1.7449359893798828 Validation Accuracy at 0.4426000118255615
Epoch  5, CIFAR-10 Batch 1:  Loss at 1.6100698709487915 Validation Accuracy at 0.4607999920845032
Epoch  6, CIFAR-10 Batch 1:  Loss at 1.5533056259155273 Validation Accuracy at 0.4564000070095062
Epoch  7, CIFAR-10 Batch 1:  Loss at 1.3873822689056396 Validation Accuracy at 0.4803999960422516
Epoch  8, CIFAR-10 Batch 1:  Loss at 1.3382835388183594 Validation Accuracy at 0.4896000027656555
Epoch  9, CIFAR-10 Batch 1:  Loss at 1.1789571046829224 Validation Accuracy at 0.5138000249862671
Epoch 10, CIFAR-10 Batch 1:  Loss at 1.0851598978042603 Validation Accuracy at 0.4880000054836273

Fully Train the Model

Now that you got a good accuracy with a single CIFAR-10 batch, try it with all five batches.



In [26]:

    
"""
DON'T MODIFY ANYTHING IN THIS CELL
"""
save_model_path = './image_classification'

print('Training...')
with tf.Session() as sess:
    # Initializing the variables
    sess.run(tf.global_variables_initializer())
    
    # Training cycle
    for epoch in range(epochs):
        # Loop over all batches
        n_batches = 5
        for batch_i in range(1, n_batches + 1):
            for batch_features, batch_labels in helper.load_preprocess_training_batch(batch_i, batch_size):
                train_neural_network(sess, optimizer, keep_probability, batch_features, batch_labels)
            print('Epoch {:>2}, CIFAR-10 Batch {}:  '.format(epoch + 1, batch_i), end='')
            print_stats(sess, batch_features, batch_labels, cost, accuracy)
            
    # Save Model
    saver = tf.train.Saver()
    save_path = saver.save(sess, save_model_path)









    



Training...
Epoch  1, CIFAR-10 Batch 1:  Loss at 2.1722803115844727 Validation Accuracy at 0.2921999990940094
Epoch  1, CIFAR-10 Batch 2:  Loss at 1.900202751159668 Validation Accuracy at 0.35600000619888306
Epoch  1, CIFAR-10 Batch 3:  Loss at 1.5796239376068115 Validation Accuracy at 0.3882000148296356
Epoch  1, CIFAR-10 Batch 4:  Loss at 1.5937330722808838 Validation Accuracy at 0.41940000653266907
Epoch  1, CIFAR-10 Batch 5:  Loss at 1.6551700830459595 Validation Accuracy at 0.4341999888420105
Epoch  2, CIFAR-10 Batch 1:  Loss at 1.7551724910736084 Validation Accuracy at 0.4537999927997589
Epoch  2, CIFAR-10 Batch 2:  Loss at 1.4757696390151978 Validation Accuracy at 0.45339998602867126
Epoch  2, CIFAR-10 Batch 3:  Loss at 1.265783667564392 Validation Accuracy at 0.46779999136924744
Epoch  2, CIFAR-10 Batch 4:  Loss at 1.4730287790298462 Validation Accuracy at 0.49480000138282776
Epoch  2, CIFAR-10 Batch 5:  Loss at 1.4510926008224487 Validation Accuracy at 0.5008000135421753
Epoch  3, CIFAR-10 Batch 1:  Loss at 1.574515700340271 Validation Accuracy at 0.49959999322891235
Epoch  3, CIFAR-10 Batch 2:  Loss at 1.3555711507797241 Validation Accuracy at 0.5130000114440918
Epoch  3, CIFAR-10 Batch 3:  Loss at 1.1308870315551758 Validation Accuracy at 0.49559998512268066
Epoch  3, CIFAR-10 Batch 4:  Loss at 1.41506028175354 Validation Accuracy at 0.5095999836921692
Epoch  3, CIFAR-10 Batch 5:  Loss at 1.3787975311279297 Validation Accuracy at 0.5162000060081482
Epoch  4, CIFAR-10 Batch 1:  Loss at 1.3812506198883057 Validation Accuracy at 0.5109999775886536
Epoch  4, CIFAR-10 Batch 2:  Loss at 1.1360445022583008 Validation Accuracy at 0.5210000276565552
Epoch  4, CIFAR-10 Batch 3:  Loss at 1.0624386072158813 Validation Accuracy at 0.5090000033378601
Epoch  4, CIFAR-10 Batch 4:  Loss at 1.2736361026763916 Validation Accuracy at 0.5217999815940857
Epoch  4, CIFAR-10 Batch 5:  Loss at 1.2621545791625977 Validation Accuracy at 0.5271999835968018
Epoch  5, CIFAR-10 Batch 1:  Loss at 1.3399617671966553 Validation Accuracy at 0.5351999998092651
Epoch  5, CIFAR-10 Batch 2:  Loss at 1.019272804260254 Validation Accuracy at 0.5486000180244446
Epoch  5, CIFAR-10 Batch 3:  Loss at 0.9376908540725708 Validation Accuracy at 0.5404000282287598
Epoch  5, CIFAR-10 Batch 4:  Loss at 1.1272977590560913 Validation Accuracy at 0.546999990940094
Epoch  5, CIFAR-10 Batch 5:  Loss at 1.1280157566070557 Validation Accuracy at 0.5429999828338623
Epoch  6, CIFAR-10 Batch 1:  Loss at 1.180312991142273 Validation Accuracy at 0.5472000241279602
Epoch  6, CIFAR-10 Batch 2:  Loss at 0.9357051849365234 Validation Accuracy at 0.5618000030517578
Epoch  6, CIFAR-10 Batch 3:  Loss at 0.8897308111190796 Validation Accuracy at 0.5565999746322632
Epoch  6, CIFAR-10 Batch 4:  Loss at 1.0607421398162842 Validation Accuracy at 0.5598000288009644
Epoch  6, CIFAR-10 Batch 5:  Loss at 1.0174249410629272 Validation Accuracy at 0.5676000118255615
Epoch  7, CIFAR-10 Batch 1:  Loss at 1.112265944480896 Validation Accuracy at 0.5672000050544739
Epoch  7, CIFAR-10 Batch 2:  Loss at 0.8830011487007141 Validation Accuracy at 0.5752000212669373
Epoch  7, CIFAR-10 Batch 3:  Loss at 0.8073410987854004 Validation Accuracy at 0.5666000247001648
Epoch  7, CIFAR-10 Batch 4:  Loss at 1.0333398580551147 Validation Accuracy at 0.5687999725341797
Epoch  7, CIFAR-10 Batch 5:  Loss at 0.9369108080863953 Validation Accuracy at 0.5676000118255615
Epoch  8, CIFAR-10 Batch 1:  Loss at 1.0580998659133911 Validation Accuracy at 0.5740000009536743
Epoch  8, CIFAR-10 Batch 2:  Loss at 0.8647805452346802 Validation Accuracy at 0.5709999799728394
Epoch  8, CIFAR-10 Batch 3:  Loss at 0.7766159176826477 Validation Accuracy at 0.569599986076355
Epoch  8, CIFAR-10 Batch 4:  Loss at 0.9425522089004517 Validation Accuracy at 0.5831999778747559
Epoch  8, CIFAR-10 Batch 5:  Loss at 0.8822248578071594 Validation Accuracy at 0.5788000226020813
Epoch  9, CIFAR-10 Batch 1:  Loss at 0.9980655908584595 Validation Accuracy at 0.5687999725341797
Epoch  9, CIFAR-10 Batch 2:  Loss at 0.7557625770568848 Validation Accuracy at 0.5902000069618225
Epoch  9, CIFAR-10 Batch 3:  Loss at 0.7388275861740112 Validation Accuracy at 0.5848000049591064
Epoch  9, CIFAR-10 Batch 4:  Loss at 0.8485296368598938 Validation Accuracy at 0.5961999893188477
Epoch  9, CIFAR-10 Batch 5:  Loss at 0.847102165222168 Validation Accuracy at 0.5928000211715698
Epoch 10, CIFAR-10 Batch 1:  Loss at 0.8900960087776184 Validation Accuracy at 0.604200005531311
Epoch 10, CIFAR-10 Batch 2:  Loss at 0.7404141426086426 Validation Accuracy at 0.5781999826431274
Epoch 10, CIFAR-10 Batch 3:  Loss at 0.7057318687438965 Validation Accuracy at 0.5902000069618225
Epoch 10, CIFAR-10 Batch 4:  Loss at 0.7828270792961121 Validation Accuracy at 0.6014000177383423
Epoch 10, CIFAR-10 Batch 5:  Loss at 0.8034736514091492 Validation Accuracy at 0.5879999995231628

Checkpoint

The model has been saved to disk.

Test Model

Test your model against the test dataset. This will be your final accuracy. You should have an accuracy greater than 50%. If you don't, keep tweaking the model architecture and parameters.



In [27]:

    
"""
DON'T MODIFY ANYTHING IN THIS CELL
"""
%matplotlib inline
%config InlineBackend.figure_format = 'retina'

import tensorflow as tf
import pickle
import helper
import random

# Set batch size if not already set
try:
    if batch_size:
        pass
except NameError:
    batch_size = 64

save_model_path = './image_classification'
n_samples = 4
top_n_predictions = 3

def test_model():
    """
    Test the saved model against the test dataset
    """

    test_features, test_labels = pickle.load(open('preprocess_training.p', mode='rb'))
    loaded_graph = tf.Graph()

    with tf.Session(graph=loaded_graph) as sess:
        # Load model
        loader = tf.train.import_meta_graph(save_model_path + '.meta')
        loader.restore(sess, save_model_path)

        # Get Tensors from loaded model
        loaded_x = loaded_graph.get_tensor_by_name('x:0')
        loaded_y = loaded_graph.get_tensor_by_name('y:0')
        loaded_keep_prob = loaded_graph.get_tensor_by_name('keep_prob:0')
        loaded_logits = loaded_graph.get_tensor_by_name('logits:0')
        loaded_acc = loaded_graph.get_tensor_by_name('accuracy:0')
        
        # Get accuracy in batches for memory limitations
        test_batch_acc_total = 0
        test_batch_count = 0
        
        for train_feature_batch, train_label_batch in helper.batch_features_labels(test_features, test_labels, batch_size):
            test_batch_acc_total += sess.run(
                loaded_acc,
                feed_dict={loaded_x: train_feature_batch, loaded_y: train_label_batch, loaded_keep_prob: 1.0})
            test_batch_count += 1

        print('Testing Accuracy: {}\n'.format(test_batch_acc_total/test_batch_count))

        # Print Random Samples
        random_test_features, random_test_labels = tuple(zip(*random.sample(list(zip(test_features, test_labels)), n_samples)))
        random_test_predictions = sess.run(
            tf.nn.top_k(tf.nn.softmax(loaded_logits), top_n_predictions),
            feed_dict={loaded_x: random_test_features, loaded_y: random_test_labels, loaded_keep_prob: 1.0})
        helper.display_image_predictions(random_test_features, random_test_labels, random_test_predictions)


test_model()









    



Testing Accuracy: 0.5945411392405063

Why 50-80% Accuracy?

You might be wondering why you can't get an accuracy any higher. First things first, 50% isn't bad for a simple CNN. Pure guessing would get you 10% accuracy. However, you might notice people are getting scores well above 80%. That's because we haven't taught you all there is to know about neural networks. We still need to cover a few more techniques.

Submitting This Project

When submitting this project, make sure to run all the cells before saving the notebook. Save the notebook file as "dlnd_image_classification.ipynb" and save it as a HTML file under "File" -> "Download as". Include the "helper.py" and "problem_unittests.py" files in your submission.



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