MACHINE LEARNING | 7 mins read

Deep Learning Development with Google Colab

By Kant on 30 Mar 2021

What Is Google Colab?

Collaboratory, or “Colab” for short, is a product from Google Research. Colab allows anybody to write and execute arbitrary python code through the browser and is especially well-suited to machine learning, data analysis, and education.

How to run a code in Google Colab?

Just only 2 steps 

1. Sign in Google Colab (

Google colab home page

2. Create a new notebook

a. Select a new notebook option from the pop-up window shown in the above picture. However, you can create a new notebook by going to the file menu and select “New notebook”.

Create a new notebook

b. Using a GPU or TPU in Colab: By default, the GPU and TPU are disabled for the notebooks. Nevertheless, They can easily be turned on.

The steps to turn on the GPU are:

i. Click Runtime located on the menu bar.

ii. Select the Change Runtime type.

iii. Select GPU/TPU from the hardware accelerator.

c. Using a GPU or TPU in Colab: By default, the GPU and TPU are disabled for the notebooks. Nevertheless, They can easily be turned on.

Implement deep learning using Google colab

1. Get Google Colab Ready to Use

Since Colab is working on your Google Drive, we first need to specify the folder we’ll work. I created a folder named “app” on my Google Drive. Of course, you can use a different name or choose the default Colab Notebooks folder instead of the app folder.

2. Create a new notebook via Right-click > More > Collaboratory

3. Set up GPU as 2 steps from above

4. Mount Colab with your google drive 

a. On the left panel, click on a folder icon

b. Then, click on the folder icon with google drive sign

c. After mounted, drive directory will appear.

 5. Set up module for training image classification model

import itertools
                import os
                import matplotlib.pylab as plt
                import numpy as np
                import tensorflow as tf
                import tensorflow_hub as hub
                print("TF version:", tf.__version__)
                print("Hub version:", hub.__version__)
                print("GPU is", "available" if tf.test.is_gpu_available() else "NOT AVAILABLE")

6. Set up module for training image classification model

module_selection = ("mobilenet_v2_100_224", 224)
                handle_base, pixels = module_selection
                MODULE_HANDLE ="{}/feature_vector/4".format(handle_base)
                IMAGE_SIZE = (pixels, pixels)
                print("Using {} with input size {}".format(MODULE_HANDLE, IMAGE_SIZE))
                BATCH_SIZE = 32


7. Set up the Flowers dataset

data_dir = tf.keras.utils.get_file(
                datagen_kwargs = dict(rescale=1./255, validation_split=.20)
                dataflow_kwargs = dict(target_size=IMAGE_SIZE, batch_size=BATCH_SIZE,
                valid_datagen = tf.keras.preprocessing.image.ImageDataGenerator(
                valid_generator = valid_datagen.flow_from_directory(
                    data_dir, subset="validation", shuffle=False, **dataflow_kwargs)
                do_data_augmentation = False
                if do_data_augmentation:
                  train_datagen = tf.keras.preprocessing.image.ImageDataGenerator(
                      width_shift_range=0.2, height_shift_range=0.2,
                      shear_range=0.2, zoom_range=0.2,
                  train_datagen = valid_datagen
                train_generator = train_datagen.flow_from_directory(
                    data_dir, subset="training", shuffle=True, **dataflow_kwargs)


8. Define the model

do_fine_tuning = False
                print("Building model with", MODULE_HANDLE)
                model = tf.keras.Sequential([
                   # Explicitly define the input shape so the model can be properly
                   # loaded by the TFLiteConverter
                   tf.keras.layers.InputLayer(input_shape=IMAGE_SIZE + (3,)),
                   hub.KerasLayer(MODULE_HANDLE, trainable=do_fine_tuning),


9. Train the model

                  optimizer=tf.keras.optimizers.SGD(lr=0.005, momentum=0.9),
                  loss=tf.keras.losses.CategoricalCrossentropy(from_logits=True, label_smoothing=0.1),
                steps_per_epoch = train_generator.samples // train_generator.batch_size
                validation_steps = valid_generator.samples // valid_generator.batch_size
                hist =
                    epochs=5, steps_per_epoch=steps_per_epoch,


10. Try out the model on an image from the validation data:

def get_class_string_from_index(index):
                   for class_string, class_index in valid_generator.class_indices.items():
                      if class_index == index:
                         return class_string
                x, y = next(valid_generator)
                image = x[0, :, :, :]
                true_index = np.argmax(y[0])
                # Expand the validation image to (1, 224, 224, 3) before predicting the label
                prediction_scores = model.predict(np.expand_dims(image, axis=0))
                predicted_index = np.argmax(prediction_scores)
                print("True label: " + get_class_string_from_index(true_index))
                print("Predicted label: " + get_class_string_from_index(predicted_index))


Written By
Machine learning engineer at Sennalabs. Loves to learn new tech.
Machine learning engineer at Sennalabs. Loves to learn new tech.

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