Closed github-learning-lab[bot] closed 4 years ago
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That's right! Remember that TensorFlow is a more general tool for working with tensors. Therefore, it is not only used for Neural Networks.
We will be executing all of our Python code using the command line interface and a Python interpretor. This provides us with a degree of immediate responsiveness and the ability to see all messages passed during operations instead of just fail or pass state messages.
To import packaged into a specific Python environment, you need only use the 'import' command.
python
Python 3.6.7 (v3.6.7:6ec5cf24b7, Oct 20 2018, 13:35:33) [MSC v.1900 64 bit (AMD64)] on win32
Type "help", "copyright", "credits" or "license" for more information.
>>> import numpy
>>>
We are also able to give packages nicknames, really useful so we don't have to type out matplotlib or tensorflow thousands of times. We assign these nicknames by "importing as".
>>> import matplotlib.pyplot as plt
>>>
And finally, we import Tensorflow and its Keras interface. Note that we can always call Keras as a Tensorflow object (i.e. tf.keras.command() ), but that takes too much typing. To save us time, we will import Keras from Tensorflow.
>>> import tensorflow as tf
>>> from tensorflow import keras
>>>
All of our prerequisite packages are now installed!
Leave a comment after you have imported the libraries above for the next step.
done
Now we are ready to roll! First, we must admit that it takes a lot of data to train a NN, and 70,000 examples is an anemic dataset. So instead of doing a more traditional 70/20/10 or 80/10/10 percent split between training/validating/testing, we will do a simple 6:1 ratio of training:testing (note that this is not best practices, but when there is limited data it may be your only recourse).
We first load in the dataset from the Keras package:
>>> fashion_mnist = keras.datasets.fashion_mnist
>>> (train_images, train_labels), (test_images, test_labels) = fashion_mnist.load_data()
Downloading data from https://storage.googleapis.com/tensorflow/tf-keras-datasets/train-labels-idx1-ubyte.gz
32768/29515 [=================================] - 0s 1us/step
Downloading data from https://storage.googleapis.com/tensorflow/tf-keras-datasets/train-images-idx3-ubyte.gz
26427392/26421880 [==============================] - 2s 0us/step
Downloading data from https://storage.googleapis.com/tensorflow/tf-keras-datasets/t10k-labels-idx1-ubyte.gz
8192/5148 [===============================================] - 0s 0us/step
Downloading data from https://storage.googleapis.com/tensorflow/tf-keras-datasets/t10k-images-idx3-ubyte.gz
4423680/4422102 [==============================] - 0s 0us/step
>>>
The first line merely assigns the name fashion_mnist to a particular dataset located within Keras' dataset library. The second line defines four arrays containing the training and testing data, cleaved again into separate structures for images and labels, and then loads all of that data into our standup of Python. The training data arrays will be used to --you guessed it-- train the model, and the testing arrays will allow us to evaluate the performance of our model.
It's always nice to be able to show that we've actually done something; ever since kindergarten there has been no better way than with a picture! You'll note that we pip installed and imported MatPlotLib, a library for plots and graphs. Here we'll use it to visualize an example of the Fashion MNIST dataset.
>>> plt.figure()
<Figure size 640x480 with 0 Axes>
>>> plt.imshow(train_images[0])
<matplotlib.image.AxesImage object at 0x00000133F2152518>
>>> plt.colorbar()
<matplotlib.colorbar.Colorbar object at 0x00000133F2184A90>
>>> plt.grid(False)
>>> plt.show()
The first command basically generates a figure object that will be manipulated by commands 2 through 4. Command 2 specifies what it is that we shall be plotting: the first element from the train_images array. NOTE: Recall that python is an inclusive counting language, meaning that it numbers/indexes things starting from zero, not one! And the final command, "show()", tells Python to generate this figure in an external (from CMD) window.
Your window should contain a plot that looks similar to Figure 3. Also, be aware that after plt.show(), Python will not return you to a command line until the newly generated window (containing our super nice picture) is closed. Upon closing the window, you will be able to continue entering Python commands.
Figure 3 The graphical output of the above code snip. Note that this is a pixelated ankle boot image in greyscale that has been false-colored.
When you have generated a graph of a boot image, close this issue
What a fine looking boot! 👢
In the new issue you will write a program that will classify this boot as a boot!
Pip Installing Packages
To complete this project we will need a few packages; these are add-ons available to Python but not included in the base install. Very luckily, we installed the latest Python 3, which includes the Pip Installation module of Python. Pip is a fast and easy way to install packages and their dependencies. As we are doing an NN-based project, we will need to use TensorFlow. For those who only recognize TensorFlow by its association with NNs, it may be shocking to learn that TensorFlow is a more general tool for the manipulation of mathematical entities called tensors. NNs are just a single use of tenor mechanics, and therefore TensorFlow.
As tensors and TensorFlow can be fairly complex to manage, there exists another package named Keras that acts as a high-level API (Application Programming Interface), allowing users to easily generation, define and manipulate the structures within TensorFlow.
Finally, as we wish to visualize aspects of our dataset and generate some informational plots, we will want Python's Mathematical Plotting Library, MatPlotLib. Additionally, MatPlotLib facilitates the generation of graphical plots in new windows, even when executed from the Command Line. And finally, to handle numerical computations and array-based operations we will import Numpy.
Starting from the c-prompt (where we left off above), you will need to tell the easy Python package manager (a program that helps you install, uninstall, update and upgrade ancillary features to a larger application) that we want to install Numpy, MatPlotLib, and Tensorflow.
If you encounter a permissions error, you may need to add
--user
to the end of each install. For examplepip install Numpy --user
.After each of these actions, pip will display that it is downloading and installing the package. If you have an existing (but not up-to-date) version, pip will first uninstall the old version before installing the new. If you have previously installed the current version of any package, pip will inform you that the 'requirement already exists'.
Now we can test if Python has installed our Tensorflow correctly (this being the testier of the three packages), by returning to the Python Environment and printing the version of our Tensorflow:
We can see that I have Tensorflow version 1.14.0 installed! Unless you have specified an earlier version (and dialing in the version that you need for any particular existing project can be a hassle with Tensorflow) you will have automatically installed the newest stable release, which at the time of this writing was version 2.0.0. And yes, I have intentionally had to enter and exit the Python environment from the CMD several times. This is called Reinforcement Learning; you've been subjected to the human equivalent of another machine learning technique you will learn about later.
Leave a comment with the letter (A, B, C, or D) that is false about TensorFlow
A. TensorFlow can be installed using pip B. TensorFlow is only used for Neural Networks C. TensorFlow is used to manipulate tensors D. The Keras package can make using TensorFlow more easy