টিএফপি সম্ভাব্য স্তর: বৈচিত্র্যপূর্ণ অটো এনকোডার

TensorFlow.org এ দেখুন Google Colab-এ চালান GitHub-এ উৎস দেখুন নোটবুক ডাউনলোড করুন

এই উদাহরণে আমরা TFP-এর "সম্ভাব্য স্তরগুলি" ব্যবহার করে একটি পরিবর্তনশীল অটোএনকোডারকে কীভাবে ফিট করা যায় তা দেখাই।

নির্ভরতা এবং পূর্বশর্ত

আমদানি

জিনিস দ্রুত করুন!

আমরা ডুব দেওয়ার আগে, আসুন নিশ্চিত করি যে আমরা এই ডেমোর জন্য একটি GPU ব্যবহার করছি৷

এটি করতে, "রানটাইম" -> "রানটাইম টাইপ পরিবর্তন করুন" -> "হার্ডওয়্যার অ্যাক্সিলারেটর" -> "GPU" নির্বাচন করুন।

নিচের স্নিপেটটি যাচাই করবে যে আমাদের কাছে একটি GPU অ্যাক্সেস আছে।

if tf.test.gpu_device_name() != '/device:GPU:0':
  print('WARNING: GPU device not found.')
else:
  print('SUCCESS: Found GPU: {}'.format(tf.test.gpu_device_name()))
SUCCESS: Found GPU: /device:GPU:0

ডেটাসেট লোড করুন

datasets, datasets_info = tfds.load(name='mnist',
                                    with_info=True,
                                    as_supervised=False)

def _preprocess(sample):
  image = tf.cast(sample['image'], tf.float32) / 255.  # Scale to unit interval.
  image = image < tf.random.uniform(tf.shape(image))   # Randomly binarize.
  return image, image

train_dataset = (datasets['train']
                 .map(_preprocess)
                 .batch(256)
                 .prefetch(tf.data.AUTOTUNE)
                 .shuffle(int(10e3)))
eval_dataset = (datasets['test']
                .map(_preprocess)
                .batch(256)
                .prefetch(tf.data.AUTOTUNE))

উল্লেখ্য আয় উপরে যে preprocess () image, image বদলে শুধু image কারণ Keras একটি (উদাহরণস্বরূপ, লেবেল) ইনপুট ফরম্যাট, অর্থাত সঙ্গে বৈষম্যমূলক মডেলের জন্য সেট আপ করা হয়েছে \(p\theta(y|x)\)। যেহেতু VAE লক্ষ্য এক্স নিজেই থেকে ইনপুট x (অর্থাত পুনরুদ্ধার হয় \(p_\theta(x|x)\)), ডাটা যুগল (উদাহরণস্বরূপ, উদাহরণস্বরূপ) হয়।

VAE কোড গলফ

মডেল নির্দিষ্ট করুন।

input_shape = datasets_info.features['image'].shape
encoded_size = 16
base_depth = 32
prior = tfd.Independent(tfd.Normal(loc=tf.zeros(encoded_size), scale=1),
                        reinterpreted_batch_ndims=1)
encoder = tfk.Sequential([
    tfkl.InputLayer(input_shape=input_shape),
    tfkl.Lambda(lambda x: tf.cast(x, tf.float32) - 0.5),
    tfkl.Conv2D(base_depth, 5, strides=1,
                padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2D(base_depth, 5, strides=2,
                padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2D(2 * base_depth, 5, strides=1,
                padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2D(2 * base_depth, 5, strides=2,
                padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2D(4 * encoded_size, 7, strides=1,
                padding='valid', activation=tf.nn.leaky_relu),
    tfkl.Flatten(),
    tfkl.Dense(tfpl.MultivariateNormalTriL.params_size(encoded_size),
               activation=None),
    tfpl.MultivariateNormalTriL(
        encoded_size,
        activity_regularizer=tfpl.KLDivergenceRegularizer(prior)),
])
WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/tensorflow/python/ops/linalg/linear_operator_lower_triangular.py:158: calling LinearOperator.__init__ (from tensorflow.python.ops.linalg.linear_operator) with graph_parents is deprecated and will be removed in a future version.
Instructions for updating:
Do not pass `graph_parents`.  They will  no longer be used.
WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/tensorflow/python/ops/linalg/linear_operator_lower_triangular.py:158: calling LinearOperator.__init__ (from tensorflow.python.ops.linalg.linear_operator) with graph_parents is deprecated and will be removed in a future version.
Instructions for updating:
Do not pass `graph_parents`.  They will  no longer be used.
decoder = tfk.Sequential([
    tfkl.InputLayer(input_shape=[encoded_size]),
    tfkl.Reshape([1, 1, encoded_size]),
    tfkl.Conv2DTranspose(2 * base_depth, 7, strides=1,
                         padding='valid', activation=tf.nn.leaky_relu),
    tfkl.Conv2DTranspose(2 * base_depth, 5, strides=1,
                         padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2DTranspose(2 * base_depth, 5, strides=2,
                         padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2DTranspose(base_depth, 5, strides=1,
                         padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2DTranspose(base_depth, 5, strides=2,
                         padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2DTranspose(base_depth, 5, strides=1,
                         padding='same', activation=tf.nn.leaky_relu),
    tfkl.Conv2D(filters=1, kernel_size=5, strides=1,
                padding='same', activation=None),
    tfkl.Flatten(),
    tfpl.IndependentBernoulli(input_shape, tfd.Bernoulli.logits),
])
vae = tfk.Model(inputs=encoder.inputs,
                outputs=decoder(encoder.outputs[0]))

অনুমান করুন।

negloglik = lambda x, rv_x: -rv_x.log_prob(x)

vae.compile(optimizer=tf.optimizers.Adam(learning_rate=1e-3),
            loss=negloglik)

_ = vae.fit(train_dataset,
            epochs=15,
            validation_data=eval_dataset)
Epoch 1/15
235/235 [==============================] - 14s 61ms/step - loss: 206.5541 - val_loss: 163.1924
Epoch 2/15
235/235 [==============================] - 14s 59ms/step - loss: 151.1891 - val_loss: 143.6748
Epoch 3/15
235/235 [==============================] - 14s 58ms/step - loss: 141.3275 - val_loss: 137.9188
Epoch 4/15
235/235 [==============================] - 14s 58ms/step - loss: 136.7453 - val_loss: 133.2726
Epoch 5/15
235/235 [==============================] - 14s 58ms/step - loss: 132.3803 - val_loss: 131.8343
Epoch 6/15
235/235 [==============================] - 14s 58ms/step - loss: 129.2451 - val_loss: 127.1935
Epoch 7/15
235/235 [==============================] - 14s 59ms/step - loss: 126.0975 - val_loss: 123.6789
Epoch 8/15
235/235 [==============================] - 14s 58ms/step - loss: 124.0565 - val_loss: 122.5058
Epoch 9/15
235/235 [==============================] - 14s 58ms/step - loss: 122.9974 - val_loss: 121.9544
Epoch 10/15
235/235 [==============================] - 14s 58ms/step - loss: 121.7349 - val_loss: 120.8735
Epoch 11/15
235/235 [==============================] - 14s 58ms/step - loss: 121.0856 - val_loss: 120.1340
Epoch 12/15
235/235 [==============================] - 14s 58ms/step - loss: 120.2232 - val_loss: 121.3554
Epoch 13/15
235/235 [==============================] - 14s 58ms/step - loss: 119.8123 - val_loss: 119.2351
Epoch 14/15
235/235 [==============================] - 14s 58ms/step - loss: 119.2685 - val_loss: 118.2133
Epoch 15/15
235/235 [==============================] - 14s 59ms/step - loss: 118.8895 - val_loss: 119.4771

দেখ মা, না হাত টেনসর !

# We'll just examine ten random digits.
x = next(iter(eval_dataset))[0][:10]
xhat = vae(x)
assert isinstance(xhat, tfd.Distribution)

ইমেজ প্লট ইউটিল

print('Originals:')
display_imgs(x)

print('Decoded Random Samples:')
display_imgs(xhat.sample())

print('Decoded Modes:')
display_imgs(xhat.mode())

print('Decoded Means:')
display_imgs(xhat.mean())
Originals:

png

Decoded Random Samples:

png

Decoded Modes:

png

Decoded Means:

png

# Now, let's generate ten never-before-seen digits.
z = prior.sample(10)
xtilde = decoder(z)
assert isinstance(xtilde, tfd.Distribution)
print('Randomly Generated Samples:')
display_imgs(xtilde.sample())

print('Randomly Generated Modes:')
display_imgs(xtilde.mode())

print('Randomly Generated Means:')
display_imgs(xtilde.mean())
Randomly Generated Samples:

png

Randomly Generated Modes:

png

Randomly Generated Means:

png