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Python: Deeper Insights into Machine Learning

You're reading from   Python: Deeper Insights into Machine Learning Deeper Insights into Machine Learning

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Product type Course
Published in Aug 2016
Publisher Packt
ISBN-13 9781787128576
Length 901 pages
Edition 1st Edition
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Authors (3):
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John Hearty John Hearty
Author Profile Icon John Hearty
John Hearty
Sebastian Raschka Sebastian Raschka
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Sebastian Raschka
David Julian David Julian
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David Julian
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Toc

Table of Contents (6) Chapters Close

Preface 1. Module 1 2. Module 2 FREE CHAPTER 3. Module 3 A. Biblography
Index

Chapter 2. Training Machine Learning Algorithms for Classification

In this chapter, we will make use of one of the first algorithmically described machine learning algorithms for classification, the perceptron and adaptive linear neurons. We will start by implementing a perceptron step by step in Python and training it to classify different flower species in the Iris dataset. This will help us to understand the concept of machine learning algorithms for classification and how they can be efficiently implemented in Python. Discussing the basics of optimization using adaptive linear neurons will then lay the groundwork for using more powerful classifiers via the scikit-learn machine-learning library in Chapter 3, A Tour of Machine Learning Classifiers Using Scikit-learn.

The topics that we will cover in this chapter are as follows:

  • Building an intuition for machine learning algorithms
  • Using pandas, NumPy, and matplotlib to read in, process, and visualize data
  • Implementing linear classification algorithms in Python

Artificial neurons – a brief glimpse into the early history of machine learning

Before we discuss the perceptron and related algorithms in more detail, let us take a brief tour through the early beginnings of machine learning. Trying to understand how the biological brain works to design artificial intelligence, Warren McCullock and Walter Pitts published the first concept of a simplified brain cell, the so-called McCullock-Pitts (MCP) neuron, in 1943 (W. S. McCulloch and W. Pitts. A Logical Calculus of the Ideas Immanent in Nervous Activity. The bulletin of mathematical biophysics, 5(4):115–133, 1943). Neurons are interconnected nerve cells in the brain that are involved in the processing and transmitting of chemical and electrical signals, which is illustrated in the following figure:

Artificial neurons – a brief glimpse into the early history of machine learning

McCullock and Pitts described such a nerve cell as a simple logic gate with binary outputs; multiple signals arrive at the dendrites, are then integrated into the cell body, and, if the accumulated signal exceeds a certain threshold, an output signal is generated that will be passed on by the axon.

Only a few years later, Frank Rosenblatt published the first concept of the perceptron learning rule based on the MCP neuron model (F. Rosenblatt, The Perceptron, a Perceiving and Recognizing Automaton. Cornell Aeronautical Laboratory, 1957). With his perceptron rule, Rosenblatt proposed an algorithm that would automatically learn the optimal weight coefficients that are then multiplied with the input features in order to make the decision of whether a neuron fires or not. In the context of supervised learning and classification, such an algorithm could then be used to predict if a sample belonged to one class or the other.

More formally, we can pose this problem as a binary classification task where we refer to our two classes as 1 (positive class) and -1 (negative class) for simplicity. We can then define an activation function Artificial neurons – a brief glimpse into the early history of machine learning that takes a linear combination of certain input values Artificial neurons – a brief glimpse into the early history of machine learning and a corresponding weight vector Artificial neurons – a brief glimpse into the early history of machine learning, where Artificial neurons – a brief glimpse into the early history of machine learning is the so-called net input (Artificial neurons – a brief glimpse into the early history of machine learning):

Artificial neurons – a brief glimpse into the early history of machine learning

Now, if the activation of a particular sample Artificial neurons – a brief glimpse into the early history of machine learning, that is, the output of Artificial neurons – a brief glimpse into the early history of machine learning, is greater than a defined threshold Artificial neurons – a brief glimpse into the early history of machine learning, we predict class 1 and class -1, otherwise, in the perceptron algorithm, the activation function Artificial neurons – a brief glimpse into the early history of machine learning is a simple unit step function, which is sometimes also called the Heaviside step function:

Artificial neurons – a brief glimpse into the early history of machine learning

For simplicity, we can bring the threshold Artificial neurons – a brief glimpse into the early history of machine learning to the left side of the equation and define a weight-zero as Artificial neurons – a brief glimpse into the early history of machine learning and Artificial neurons – a brief glimpse into the early history of machine learning, so that we write Artificial neurons – a brief glimpse into the early history of machine learning in a more compact form Artificial neurons – a brief glimpse into the early history of machine learning and Artificial neurons – a brief glimpse into the early history of machine learning.

Note

In the following sections, we will often make use of basic notations from linear algebra. For example, we will abbreviate the sum of the products of the values in Artificial neurons – a brief glimpse into the early history of machine learning and Artificial neurons – a brief glimpse into the early history of machine learning using a vector dot product, whereas superscript T stands for transpose, which is an operation that transforms a column vector into a row vector and vice versa:

Artificial neurons – a brief glimpse into the early history of machine learning

For example: Artificial neurons – a brief glimpse into the early history of machine learning.

Furthermore, the transpose operation can also be applied to a matrix to reflect it over its diagonal, for example:

Artificial neurons – a brief glimpse into the early history of machine learning

In this book, we will only use the very basic concepts from linear algebra. However, if you need a quick refresher, please take a look at Zico Kolter's excellent Linear Algebra Review and Reference, which is freely available at http://www.cs.cmu.edu/~zkolter/course/linalg/linalg_notes.pdf.

The following figure illustrates how the net input Artificial neurons – a brief glimpse into the early history of machine learning is squashed into a binary output (-1 or 1) by the activation function of the perceptron (left subfigure) and how it can be used to discriminate between two linearly separable classes (right subfigure):

Artificial neurons – a brief glimpse into the early history of machine learning

The whole idea behind the MCP neuron and Rosenblatt's thresholded perceptron model is to use a reductionist approach to mimic how a single neuron in the brain works: it either fires or it doesn't. Thus, Rosenblatt's initial perceptron rule is fairly simple and can be summarized by the following steps:

  1. Initialize the weights to 0 or small random numbers.
  2. For each training sample Artificial neurons – a brief glimpse into the early history of machine learning perform the following steps:
    1. Compute the output value Artificial neurons – a brief glimpse into the early history of machine learning.
    2. Update the weights.

Here, the output value is the class label predicted by the unit step function that we defined earlier, and the simultaneous update of each weight Artificial neurons – a brief glimpse into the early history of machine learning in the weight vector Artificial neurons – a brief glimpse into the early history of machine learning can be more formally written as:

Artificial neurons – a brief glimpse into the early history of machine learning

.

The value of Artificial neurons – a brief glimpse into the early history of machine learning, which is used to update the weight Artificial neurons – a brief glimpse into the early history of machine learning, is calculated by the perceptron learning rule:

Artificial neurons – a brief glimpse into the early history of machine learning

Where Artificial neurons – a brief glimpse into the early history of machine learning is the learning rate (a constant between 0.0 and 1.0), Artificial neurons – a brief glimpse into the early history of machine learning is the true class label of the Artificial neurons – a brief glimpse into the early history of machine learningth training sample, and Artificial neurons – a brief glimpse into the early history of machine learning is the predicted class label. It is important to note that all weights in the weight vector are being updated simultaneously, which means that we don't recompute the Artificial neurons – a brief glimpse into the early history of machine learning before all of the weights Artificial neurons – a brief glimpse into the early history of machine learning were updated. Concretely, for a 2D dataset, we would write the update as follows:

Artificial neurons – a brief glimpse into the early history of machine learning
Artificial neurons – a brief glimpse into the early history of machine learning
Artificial neurons – a brief glimpse into the early history of machine learning

Before we implement the perceptron rule in Python, let us make a simple thought experiment to illustrate how beautifully simple this learning rule really is. In the two scenarios where the perceptron predicts the class label correctly, the weights remain unchanged:

Artificial neurons – a brief glimpse into the early history of machine learning
Artificial neurons – a brief glimpse into the early history of machine learning

However, in the case of a wrong prediction, the weights are being pushed towards the direction of the positive or negative target class, respectively:

Artificial neurons – a brief glimpse into the early history of machine learning
Artificial neurons – a brief glimpse into the early history of machine learning

To get a better intuition for the multiplicative factor Artificial neurons – a brief glimpse into the early history of machine learning, let us go through another simple example, where:

Artificial neurons – a brief glimpse into the early history of machine learning

Let's assume that Artificial neurons – a brief glimpse into the early history of machine learning, and we misclassify this sample as -1. In this case, we would increase the corresponding weight by 1 so that the activation Artificial neurons – a brief glimpse into the early history of machine learning will be more positive the next time we encounter this sample and thus will be more likely to be above the threshold of the unit step function to classify the sample as +1:

Artificial neurons – a brief glimpse into the early history of machine learning

The weight update is proportional to the value of Artificial neurons – a brief glimpse into the early history of machine learning. For example, if we have another sample Artificial neurons – a brief glimpse into the early history of machine learning that is incorrectly classified as -1, we'd push the decision boundary by an even larger extend to classify this sample correctly the next time:

Artificial neurons – a brief glimpse into the early history of machine learning

It is important to note that the convergence of the perceptron is only guaranteed if the two classes are linearly separable and the learning rate is sufficiently small. If the two classes can't be separated by a linear decision boundary, we can set a maximum number of passes over the training dataset (epochs) and/or a threshold for the number of tolerated misclassifications—the perceptron would never stop updating the weights otherwise:

Artificial neurons – a brief glimpse into the early history of machine learning

Tip

Downloading the example code

You can download the example code files from your account at http://www.packtpub.com for all the Packt Publishing books you have purchased. If you purchased this book elsewhere, you can visit http://www.packtpub.com/support and register to have the files e-mailed directly to you.

Now, before we jump into the implementation in the next section, let us summarize what we just learned in a simple figure that illustrates the general concept of the perceptron:

Artificial neurons – a brief glimpse into the early history of machine learning

The preceding figure illustrates how the perceptron receives the inputs of a sampleArtificial neurons – a brief glimpse into the early history of machine learning and combines them with the weights Artificial neurons – a brief glimpse into the early history of machine learning to compute the net input. The net input is then passed on to the activation function (here: the unit step function), which generates a binary output -1 or +1—the predicted class label of the sample. During the learning phase, this output is used to calculate the error of the prediction and update the weights.

Implementing a perceptron learning algorithm in Python

In the previous section, we learned how Rosenblatt's perceptron rule works; let us now go ahead and implement it in Python and apply it to the Iris dataset that we introduced in Chapter 1, Giving Computers the Ability to Learn from Data. We will take an objected-oriented approach to define the perceptron interface as a Python Class, which allows us to initialize new perceptron objects that can learn from data via a fit method, and make predictions via a separate predict method. As a convention, we add an underscore to attributes that are not being created upon the initialization of the object but by calling the object's other methods—for example, self.w_.

Note

If you are not yet familiar with Python's scientific libraries or need a refresher, please see the following resources:

NumPy: http://wiki.scipy.org/Tentative_NumPy_Tutorial

Pandas: http://pandas.pydata.org/pandas-docs/stable/tutorials.html

Matplotlib: http://matplotlib.org/users/beginner.html

Also, to better follow the code examples, I recommend you download the IPython notebooks from the Packt website. For a general introduction to IPython notebooks, please visit https://ipython.org/ipython-doc/3/notebook/index.html.

import numpy as np    
class Perceptron(object):
    """Perceptron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.

    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.

    """
    def __init__(self, eta=0.01, n_iter=10):
        self.eta = eta
        self.n_iter = n_iter

    def fit(self, X, y):
        """Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, where n_samples 
            is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

        """
        self.w_ = np.zeros(1 + X.shape[1])
        self.errors_ = []

        for _ in range(self.n_iter):
            errors = 0
            for xi, target in zip(X, y):
                update = self.eta * (target - self.predict(xi))
                self.w_[1:] += update * xi
                self.w_[0] += update
                errors += int(update != 0.0)
            self.errors_.append(errors)
        return self

    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.net_input(X) >= 0.0, 1, -1)

Using this perceptron implementation, we can now initialize new Perceptron objects with a given learning rate eta and n_iter, which is the number of epochs (passes over the training set). Via the fit method we initialize the weights in self.w_ to a zero-vector Implementing a perceptron learning algorithm in Python where Implementing a perceptron learning algorithm in Python stands for the number of dimensions (features) in the dataset where we add 1 for the zero-weight (that is, the threshold).

Note

NumPy indexing for one-dimensional arrays works similarly to Python lists using the square-bracket ([]) notation. For two-dimensional arrays, the first indexer refers to the row number, and the second indexer to the column number. For example, we would use X[2, 3] to select the third row and fourth column of a 2D array X.

After the weights have been initialized, the fit method loops over all individual samples in the training set and updates the weights according to the perceptron learning rule that we discussed in the previous section. The class labels are predicted by the predict method, which is also called in the fit method to predict the class label for the weight update, but predict can also be used to predict the class labels of new data after we have fitted our model. Furthermore, we also collect the number of misclassifications during each epoch in the list self.errors_ so that we can later analyze how well our perceptron performed during the training. The np.dot function that is used in the net_input method simply calculates the vector dot product Implementing a perceptron learning algorithm in Python.

Note

Instead of using NumPy to calculate the vector dot product between two arrays a and b via a.dot(b) or np.dot(a, b), we could also perform the calculation in pure Python via sum([j*j for i,j in zip(a, b)]. However, the advantage of using NumPy over classic Python for-loop structures is that its arithmetic operations are vectorized. Vectorization means that an elemental arithmetic operation is automatically applied to all elements in an array. By formulating our arithmetic operations as a sequence of instructions on an array rather than performing a set of operations for each element one at a time, we can make better use of our modern CPU architectures with Single Instruction, Multiple Data (SIMD) support. Furthermore, NumPy uses highly optimized linear algebra libraries, such as Basic Linear Algebra Subprograms (BLAS) and Linear Algebra Package (LAPACK) that have been written in C or Fortran. Lastly, NumPy also allows us to write our code in a more compact and intuitive way using the basics of linear algebra, such as vector and matrix dot products.

Training a perceptron model on the Iris dataset

To test our perceptron implementation, we will load the two flower classes Setosa and Versicolor from the Iris dataset. Although, the perceptron rule is not restricted to two dimensions, we will only consider the two features sepal length and petal length for visualization purposes. Also, we only chose the two flower classes Setosa and Versicolor for practical reasons. However, the perceptron algorithm can be extended to multi-class classification—for example, through the One-vs.-All technique.

Note

One-vs.-All (OvA), or sometimes also called One-vs.-Rest (OvR), is a technique, us to extend a binary classifier to multi-class problems. Using OvA, we can train one classifier per class, where the particular class is treated as the positive class and the samples from all other classes are considered as the negative class. If we were to classify a new data sample, we would use our Training a perceptron model on the Iris dataset classifiers, where Training a perceptron model on the Iris dataset is the number of class labels, and assign the class label with the highest confidence to the particular sample. In the case of the perceptron, we would use OvA to choose the class label that is associated with the largest absolute net input value.

First, we will use the pandas library to load the Iris dataset directly from the UCI Machine Learning Repository into a DataFrame object and print the last five lines via the tail method to check that the data was loaded correctly:

>>> import pandas as pd
>>> df = pd.read_csv('https://archive.ics.uci.edu/ml/'
...   'machine-learning-databases/iris/iris.data', header=None)
>>> df.tail()
Training a perceptron model on the Iris dataset

Next, we extract the first 100 class labels that correspond to the 50 Iris-Setosa and 50 Iris-Versicolor flowers, respectively, and convert the class labels into the two integer class labels 1 (Versicolor) and -1 (Setosa) that we assign to a vector y where the values method of a pandas DataFrame yields the corresponding NumPy representation. Similarly, we extract the first feature column (sepal length) and the third feature column (petal length) of those 100 training samples and assign them to a feature matrix X, which we can visualize via a two-dimensional scatter plot:

>>> import matplotlib.pyplot as plt
>>> import numpy as np

>>> y = df.iloc[0:100, 4].values
>>> y = np.where(y == 'Iris-setosa', -1, 1)
>>> X = df.iloc[0:100, [0, 2]].values
>>> plt.scatter(X[:50, 0], X[:50, 1],
...             color='red', marker='o', label='setosa')
>>> plt.scatter(X[50:100, 0], X[50:100, 1],
...             color='blue', marker='x', label='versicolor')
>>> plt.xlabel('petal length')
>>> plt.ylabel('sepal length')
>>> plt.legend(loc='upper left')
>>> plt.show()

After executing the preceding code example we should now see the following scatterplot:

Training a perceptron model on the Iris dataset

Now it's time to train our perceptron algorithm on the Iris data subset that we just extracted. Also, we will plot the misclassification error for each epoch to check if the algorithm converged and found a decision boundary that separates the two Iris flower classes:

>>> ppn = Perceptron(eta=0.1, n_iter=10)
>>> ppn.fit(X, y)
>>> plt.plot(range(1, len(ppn.errors_) + 1), ppn.errors_, 
...         marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Number of misclassifications')
>>> plt.show()

After executing the preceding code, we should see the plot of the misclassification errors versus the number of epochs, as shown next:

Training a perceptron model on the Iris dataset

As we can see in the preceding plot, our perceptron already converged after the sixth epoch and should now be able to classify the training samples perfectly. Let us implement a small convenience function to visualize the decision boundaries for 2D datasets:

from matplotlib.colors import ListedColormap

def plot_decision_regions(X, y, classifier, resolution=0.02):

    # setup marker generator and color map
    markers = ('s', 'x', 'o', '^', 'v')
    colors = ('red', 'blue', 'lightgreen', 'gray', 'cyan')
    cmap = ListedColormap(colors[:len(np.unique(y))])

    # plot the decision surface
    x1_min, x1_max = X[:, 0].min() - 1, X[:, 0].max() + 1
    x2_min, x2_max = X[:, 1].min() - 1, X[:, 1].max() + 1
    xx1, xx2 = np.meshgrid(np.arange(x1_min, x1_max, resolution),
                         np.arange(x2_min, x2_max, resolution))
    Z = classifier.predict(np.array([xx1.ravel(), xx2.ravel()]).T)
    Z = Z.reshape(xx1.shape)
    plt.contourf(xx1, xx2, Z, alpha=0.4, cmap=cmap)
    plt.xlim(xx1.min(), xx1.max())
    plt.ylim(xx2.min(), xx2.max())

    # plot class samples
    for idx, cl in enumerate(np.unique(y)):
        plt.scatter(x=X[y == cl, 0], y=X[y == cl, 1],
                    alpha=0.8, c=cmap(idx),
                    marker=markers[idx], label=cl)

First, we define a number of colors and markers and create a color map from the list of colors via ListedColormap. Then, we determine the minimum and maximum values for the two features and use those feature vectors to create a pair of grid arrays xx1 and xx2 via the NumPy meshgrid function. Since we trained our perceptron classifier on two feature dimensions, we need to flatten the grid arrays and create a matrix that has the same number of columns as the Iris training subset so that we can use the predict method to predict the class labels Z of the corresponding grid points. After reshaping the predicted class labels Z into a grid with the same dimensions as xx1 and xx2, we can now draw a contour plot via matplotlib's contourf function that maps the different decision regions to different colors for each predicted class in the grid array:

>>> plot_decision_regions(X, y, classifier=ppn)
>>> plt.xlabel('sepal length [cm]')
>>> plt.ylabel('petal length [cm]')
>>> plt.legend(loc='upper left')
>>> plt.show()

After executing the preceding code example, we should now see a plot of the decision regions, as shown in the following figure:

Training a perceptron model on the Iris dataset

As we can see in the preceding plot, the perceptron learned a decision boundary that was able to classify all flower samples in the Iris training subset perfectly.

Note

Although the perceptron classified the two Iris flower classes perfectly, convergence is one of the biggest problems of the perceptron. Frank Rosenblatt proved mathematically that the perceptron learning rule converges if the two classes can be separated by a linear hyperplane. However, if classes cannot be separated perfectly by such a linear decision boundary, the weights will never stop updating unless we set a maximum number of epochs.

Training a perceptron model on the Iris dataset

To test our perceptron implementation, we will load the two flower classes Setosa and Versicolor from the Iris dataset. Although, the perceptron rule is not restricted to two dimensions, we will only consider the two features sepal length and petal length for visualization purposes. Also, we only chose the two flower classes Setosa and Versicolor for practical reasons. However, the perceptron algorithm can be extended to multi-class classification—for example, through the One-vs.-All technique.

Note

One-vs.-All (OvA), or sometimes also called One-vs.-Rest (OvR), is a technique, us to extend a binary classifier to multi-class problems. Using OvA, we can train one classifier per class, where the particular class is treated as the positive class and the samples from all other classes are considered as the negative class. If we were to classify a new data sample, we would use our Training a perceptron model on the Iris dataset classifiers, where Training a perceptron model on the Iris dataset is the number of class labels, and assign the class label with the highest confidence to the particular sample. In the case of the perceptron, we would use OvA to choose the class label that is associated with the largest absolute net input value.

First, we will use the pandas library to load the Iris dataset directly from the UCI Machine Learning Repository into a DataFrame object and print the last five lines via the tail method to check that the data was loaded correctly:

>>> import pandas as pd
>>> df = pd.read_csv('https://archive.ics.uci.edu/ml/'
...   'machine-learning-databases/iris/iris.data', header=None)
>>> df.tail()
Training a perceptron model on the Iris dataset

Next, we extract the first 100 class labels that correspond to the 50 Iris-Setosa and 50 Iris-Versicolor flowers, respectively, and convert the class labels into the two integer class labels 1 (Versicolor) and -1 (Setosa) that we assign to a vector y where the values method of a pandas DataFrame yields the corresponding NumPy representation. Similarly, we extract the first feature column (sepal length) and the third feature column (petal length) of those 100 training samples and assign them to a feature matrix X, which we can visualize via a two-dimensional scatter plot:

>>> import matplotlib.pyplot as plt
>>> import numpy as np

>>> y = df.iloc[0:100, 4].values
>>> y = np.where(y == 'Iris-setosa', -1, 1)
>>> X = df.iloc[0:100, [0, 2]].values
>>> plt.scatter(X[:50, 0], X[:50, 1],
...             color='red', marker='o', label='setosa')
>>> plt.scatter(X[50:100, 0], X[50:100, 1],
...             color='blue', marker='x', label='versicolor')
>>> plt.xlabel('petal length')
>>> plt.ylabel('sepal length')
>>> plt.legend(loc='upper left')
>>> plt.show()

After executing the preceding code example we should now see the following scatterplot:

Training a perceptron model on the Iris dataset

Now it's time to train our perceptron algorithm on the Iris data subset that we just extracted. Also, we will plot the misclassification error for each epoch to check if the algorithm converged and found a decision boundary that separates the two Iris flower classes:

>>> ppn = Perceptron(eta=0.1, n_iter=10)
>>> ppn.fit(X, y)
>>> plt.plot(range(1, len(ppn.errors_) + 1), ppn.errors_, 
...         marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Number of misclassifications')
>>> plt.show()

After executing the preceding code, we should see the plot of the misclassification errors versus the number of epochs, as shown next:

Training a perceptron model on the Iris dataset

As we can see in the preceding plot, our perceptron already converged after the sixth epoch and should now be able to classify the training samples perfectly. Let us implement a small convenience function to visualize the decision boundaries for 2D datasets:

from matplotlib.colors import ListedColormap

def plot_decision_regions(X, y, classifier, resolution=0.02):

    # setup marker generator and color map
    markers = ('s', 'x', 'o', '^', 'v')
    colors = ('red', 'blue', 'lightgreen', 'gray', 'cyan')
    cmap = ListedColormap(colors[:len(np.unique(y))])

    # plot the decision surface
    x1_min, x1_max = X[:, 0].min() - 1, X[:, 0].max() + 1
    x2_min, x2_max = X[:, 1].min() - 1, X[:, 1].max() + 1
    xx1, xx2 = np.meshgrid(np.arange(x1_min, x1_max, resolution),
                         np.arange(x2_min, x2_max, resolution))
    Z = classifier.predict(np.array([xx1.ravel(), xx2.ravel()]).T)
    Z = Z.reshape(xx1.shape)
    plt.contourf(xx1, xx2, Z, alpha=0.4, cmap=cmap)
    plt.xlim(xx1.min(), xx1.max())
    plt.ylim(xx2.min(), xx2.max())

    # plot class samples
    for idx, cl in enumerate(np.unique(y)):
        plt.scatter(x=X[y == cl, 0], y=X[y == cl, 1],
                    alpha=0.8, c=cmap(idx),
                    marker=markers[idx], label=cl)

First, we define a number of colors and markers and create a color map from the list of colors via ListedColormap. Then, we determine the minimum and maximum values for the two features and use those feature vectors to create a pair of grid arrays xx1 and xx2 via the NumPy meshgrid function. Since we trained our perceptron classifier on two feature dimensions, we need to flatten the grid arrays and create a matrix that has the same number of columns as the Iris training subset so that we can use the predict method to predict the class labels Z of the corresponding grid points. After reshaping the predicted class labels Z into a grid with the same dimensions as xx1 and xx2, we can now draw a contour plot via matplotlib's contourf function that maps the different decision regions to different colors for each predicted class in the grid array:

>>> plot_decision_regions(X, y, classifier=ppn)
>>> plt.xlabel('sepal length [cm]')
>>> plt.ylabel('petal length [cm]')
>>> plt.legend(loc='upper left')
>>> plt.show()

After executing the preceding code example, we should now see a plot of the decision regions, as shown in the following figure:

Training a perceptron model on the Iris dataset

As we can see in the preceding plot, the perceptron learned a decision boundary that was able to classify all flower samples in the Iris training subset perfectly.

Note

Although the perceptron classified the two Iris flower classes perfectly, convergence is one of the biggest problems of the perceptron. Frank Rosenblatt proved mathematically that the perceptron learning rule converges if the two classes can be separated by a linear hyperplane. However, if classes cannot be separated perfectly by such a linear decision boundary, the weights will never stop updating unless we set a maximum number of epochs.

Adaptive linear neurons and the convergence of learning

In this section, we will take a look at another type of single-layer neural network: ADAptive LInear NEuron (Adaline). Adaline was published, only a few years after Frank Rosenblatt's perceptron algorithm, by Bernard Widrow and his doctoral student Tedd Hoff, and can be considered as an improvement on the latter (B. Widrow et al. Adaptive "Adaline" neuron using chemical "memistors". Number Technical Report 1553-2. Stanford Electron. Labs. Stanford, CA, October 1960). The Adaline algorithm is particularly interesting because it illustrates the key concept of defining and minimizing cost functions, which will lay the groundwork for understanding more advanced machine learning algorithms for classification, such as logistic regression and support vector machines, as well as regression models that we will discuss in future chapters.

The key difference between the Adaline rule (also known as the Widrow-Hoff rule) and Rosenblatt's perceptron is that the weights are updated based on a linear activation function rather than a unit step function like in the perceptron. In Adaline, this linear activation function Adaptive linear neurons and the convergence of learning is simply the identity function of the net input so that Adaptive linear neurons and the convergence of learning.

While the linear activation function is used for learning the weights, a quantizer, which is similar to the unit step function that we have seen before, can then be used to predict the class labels, as illustrated in the following figure:

Adaptive linear neurons and the convergence of learning

If we compare the preceding figure to the illustration of the perceptron algorithm that we saw earlier, the difference is that we know to use the continuous valued output from the linear activation function to compute the model error and update the weights, rather than the binary class labels.

Minimizing cost functions with gradient descent

One of the key ingredients of supervised machine learning algorithms is to define an objective function that is to be optimized during the learning process. This objective function is often a cost function that we want to minimize. In the case of Adaline, we can define the cost function Minimizing cost functions with gradient descent to learn the weights as the Sum of Squared Errors (SSE) between the calculated outcome and the true class label Minimizing cost functions with gradient descent.

The term Minimizing cost functions with gradient descent is just added for our convenience; it will make it easier to derive the gradient, as we will see in the following paragraphs. The main advantage of this continuous linear activation function is—in contrast to the unit step function—that the cost function becomes differentiable. Another nice property of this cost function is that it is convex; thus, we can use a simple, yet powerful, optimization algorithm called gradient descent to find the weights that minimize our cost function to classify the samples in the Iris dataset.

As illustrated in the following figure, we can describe the principle behind gradient descent as climbing down a hill until a local or global cost minimum is reached. In each iteration, we take a step away from the gradient where the step size is determined by the value of the learning rate as well as the slope of the gradient:

Minimizing cost functions with gradient descent

Using gradient descent, we can now update the weights by taking a step away from the gradient Minimizing cost functions with gradient descent of our cost function Minimizing cost functions with gradient descent:

Minimizing cost functions with gradient descent

Here, the weight change Minimizing cost functions with gradient descent is defined as the negative gradient multiplied by the learning rate Minimizing cost functions with gradient descent:

Minimizing cost functions with gradient descent

.

To compute the gradient of the cost function, we need to compute the partial derivative of the cost function with respect to each weight Minimizing cost functions with gradient descent Minimizing cost functions with gradient descent so that we can write the update of weight Minimizing cost functions with gradient descent as: Minimizing cost functions with gradient descent:

Since we update all weights simultaneously, our Adaline learning rule becomes Minimizing cost functions with gradient descent.

Note

For those who are familiar with calculus, the partial derivative of the SSE cost function with respect to the jth weight in can be obtained as follows:

Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent

Although the Adaline learning rule looks identical to the perceptron rule, the Minimizing cost functions with gradient descent with Minimizing cost functions with gradient descent = Minimizing cost functions with gradient descent is a real number and not an integer class label. Furthermore, the weight update is calculated based on all samples in the training set (instead of updating the weights incrementally after each sample), which is why this approach is also referred to as "batch" gradient descent.

Implementing an Adaptive Linear Neuron in Python

Since the perceptron rule and Adaline are very similar, we will take the perceptron implementation that we defined earlier and change the fit method so that the weights are updated by minimizing the cost function via gradient descent:

class AdalineGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.
    
    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.

    """
    def __init__(self, eta=0.01, n_iter=50):
        self.eta = eta
        self.n_iter = n_iter

    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, 
            where n_samples is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

        """
        self.w_ = np.zeros(1 + X.shape[1])
        self.cost_ = []

        for i in range(self.n_iter):
            output = self.net_input(X)
            errors = (y - output)
            self.w_[1:] += self.eta * X.T.dot(errors)
            self.w_[0] += self.eta * errors.sum()
            cost = (errors**2).sum() / 2.0
            self.cost_.append(cost)
        return self

    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

Instead of updating the weights after evaluating each individual training sample, as in the perceptron, we calculate the gradient based on the whole training dataset via self.eta * errors.sum() for the zero-weight and via self.eta * X.T.dot(errors) for the weights 1 to Implementing an Adaptive Linear Neuron in Python where X.T.dot(errors) is a matrix-vector multiplication between our feature matrix and the error vector. Similar to the previous perceptron implementation, we collect the cost values in a list self.cost_ to check if the algorithm converged after training.

Note

Performing a matrix-vector multiplication is similar to calculating a vector dot product where each row in the matrix is treated as a single row vector. This vectorized approach represents a more compact notation and results in a more efficient computation using NumPy. For example:

Implementing an Adaptive Linear Neuron in Python

.

In practice, it often requires some experimentation to find a good learning rate Implementing an Adaptive Linear Neuron in Python for optimal convergence. So, let's choose two different learning rates Implementing an Adaptive Linear Neuron in Python and Implementing an Adaptive Linear Neuron in Python to start with and plot the cost functions versus the number of epochs to see how well the Adaline implementation learns from the training data.

Note

The learning rate Implementing an Adaptive Linear Neuron in Python, as well as the number of epochs n_iter, are the so-called hyperparameters of the perceptron and Adaline learning algorithms. In Chapter 4, Building Good Training Sets—Data Preprocessing, we will take a look at different techniques to automatically find the values of different hyperparameters that yield optimal performance of the classification model.

Let us now plot the cost against the number of epochs for the two different learning rates:

>>> fig, ax = plt.subplots(nrows=1, ncols=2, figsize=(8, 4))
>>> ada1 = AdalineGD(n_iter=10, eta=0.01).fit(X, y)
>>> ax[0].plot(range(1, len(ada1.cost_) + 1),
...            np.log10(ada1.cost_), marker='o')
>>> ax[0].set_xlabel('Epochs')
>>> ax[0].set_ylabel('log(Sum-squared-error)')
>>> ax[0].set_title('Adaline - Learning rate 0.01')
>>> ada2 = AdalineGD(n_iter=10, eta=0.0001).fit(X, y)
>>> ax[1].plot(range(1, len(ada2.cost_) + 1),
...            ada2.cost_, marker='o')
>>> ax[1].set_xlabel('Epochs')
>>> ax[1].set_ylabel('Sum-squared-error')
>>> ax[1].set_title('Adaline - Learning rate 0.0001')
>>> plt.show()

As we can see in the resulting cost function plots next, we encountered two different types of problems. The left chart shows what could happen if we choose a learning rate that is too large—instead of minimizing the cost function, the error becomes larger in every epoch because we overshoot the global minimum:

Implementing an Adaptive Linear Neuron in Python

Although we can see that the cost decreases when we look at the right plot, the chosen learning rate Implementing an Adaptive Linear Neuron in Python is so small that the algorithm would require a very large number of epochs to converge. The following figure illustrates how we change the value of a particular weight parameter to minimize the cost function Implementing an Adaptive Linear Neuron in Python (left subfigure). The subfigure on the right illustrates what happens if we choose a learning rate that is too large, we overshoot the global minimum:

Implementing an Adaptive Linear Neuron in Python

Many machine learning algorithms that we will encounter throughout this book require some sort of feature scaling for optimal performance, which we will discuss in more detail in Chapter 3, A Tour of Machine Learning Classifiers Using Scikit-learn. Gradient descent is one of the many algorithms that benefit from feature scaling. Here, we will use a feature scaling method called standardization, which gives our data the property of a standard normal distribution. The mean of each feature is centered at value 0 and the feature column has a standard deviation of 1. For example, to standardize the Implementing an Adaptive Linear Neuron in Pythonth feature, we simply need to subtract the sample mean Implementing an Adaptive Linear Neuron in Python from every training sample and divide it by its standard deviation Implementing an Adaptive Linear Neuron in Python:

Implementing an Adaptive Linear Neuron in Python

Here Implementing an Adaptive Linear Neuron in Python is a vector consisting of the Implementing an Adaptive Linear Neuron in Pythonth feature values of all training samples Implementing an Adaptive Linear Neuron in Python.

Standardization can easily be achieved using the NumPy methods mean and std:

>>> X_std = np.copy(X)
>>> X_std[:,0] = (X[:,0] - X[:,0].mean()) / X[:,0].std()
>>> X_std[:,1] = (X[:,1] - X[:,1].mean()) / X[:,1].std()

After standardization, we will train the Adaline again and see that it now converges using a learning rate Implementing an Adaptive Linear Neuron in Python:

>>> ada = AdalineGD(n_iter=15, eta=0.01)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Sum-squared-error')
>>> plt.show()

After executing the preceding code, we should see a figure of the decision regions as well as a plot of the declining cost, as shown in the following figure:

Implementing an Adaptive Linear Neuron in Python

As we can see in the preceding plots, the Adaline now converges after training on the standardized features using a learning rate Implementing an Adaptive Linear Neuron in Python. However, note that the SSE remains non-zero even though all samples were classified correctly.

Large scale machine learning and stochastic gradient descent

In the previous section, we learned how to minimize a cost function by taking a step into the opposite direction of a gradient that is calculated from the whole training set; this is why this approach is sometimes also referred to as batch gradient descent. Now imagine we have a very large dataset with millions of data points, which is not uncommon in many machine learning applications. Running batch gradient descent can be computationally quite costly in such scenarios since we need to reevaluate the whole training dataset each time we take one step towards the global minimum.

A popular alternative to the batch gradient descent algorithm is stochastic gradient descent, sometimes also called iterative or on-line gradient descent. Instead of updating the weights based on the sum of the accumulated errors over all samples Large scale machine learning and stochastic gradient descent:

Large scale machine learning and stochastic gradient descent

We update the weights incrementally for each training sample:

Large scale machine learning and stochastic gradient descent

Although stochastic gradient descent can be considered as an approximation of gradient descent, it typically reaches convergence much faster because of the more frequent weight updates. Since each gradient is calculated based on a single training example, the error surface is noisier than in gradient descent, which can also have the advantage that stochastic gradient descent can escape shallow local minima more readily. To obtain accurate results via stochastic gradient descent, it is important to present it with data in a random order, which is why we want to shuffle the training set for every epoch to prevent cycles.

Note

In stochastic gradient descent implementations, the fixed learning rate Large scale machine learning and stochastic gradient descent is often replaced by an adaptive learning rate that decreases over time, for example, Large scale machine learning and stochastic gradient descent where Large scale machine learning and stochastic gradient descent and Large scale machine learning and stochastic gradient descent are constants. Note that stochastic gradient descent does not reach the global minimum but an area very close to it. By using an adaptive learning rate, we can achieve further annealing to a better global minimum

Another advantage of stochastic gradient descent is that we can use it for online learning. In online learning, our model is trained on-the-fly as new training data arrives. This is especially useful if we are accumulating large amounts of data—for example, customer data in typical web applications. Using online learning, the system can immediately adapt to changes and the training data can be discarded after updating the model if storage space in an issue.

Note

A compromise between batch gradient descent and stochastic gradient descent is the so-called mini-batch learning. Mini-batch learning can be understood as applying batch gradient descent to smaller subsets of the training data—for example, 50 samples at a time. The advantage over batch gradient descent is that convergence is reached faster via mini-batches because of the more frequent weight updates. Furthermore, mini-batch learning allows us to replace the for-loop over the training samples in Stochastic Gradient Descent (SGD) by vectorized operations, which can further improve the computational efficiency of our learning algorithm.

Since we already implemented the Adaline learning rule using gradient descent, we only need to make a few adjustments to modify the learning algorithm to update the weights via stochastic gradient descent. Inside the fit method, we will now update the weights after each training sample. Furthermore, we will implement an additional partial_fit method, which does not reinitialize the weights, for on-line learning. In order to check if our algorithm converged after training, we will calculate the cost as the average cost of the training samples in each epoch. Furthermore, we will add an option to shuffle the training data before each epoch to avoid cycles when we are optimizing the cost function; via the random_state parameter, we allow the specification of a random seed for consistency:

from numpy.random import seed

class AdalineSGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.

    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.
    shuffle : bool (default: True)
        Shuffles training data every epoch 
        if True to prevent cycles.
    random_state : int (default: None)
        Set random state for shuffling 
        and initializing the weights.
        
    """
    def __init__(self, eta=0.01, n_iter=10, 
               shuffle=True, random_state=None):
        self.eta = eta
        self.n_iter = n_iter
        self.w_initialized = False
        self.shuffle = shuffle
        if random_state:
            seed(random_state)
        
    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, where n_samples 
            is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

         """
        self._initialize_weights(X.shape[1])
        self.cost_ = []
        for i in range(self.n_iter):
            if self.shuffle:
                X, y = self._shuffle(X, y)
            cost = []
            for xi, target in zip(X, y):
                cost.append(self._update_weights(xi, target))
            avg_cost = sum(cost)/len(y)
            self.cost_.append(avg_cost)
        return self

    def partial_fit(self, X, y):
        """Fit training data without reinitializing the weights"""
        if not self.w_initialized:
            self._initialize_weights(X.shape[1])
        if y.ravel().shape[0] > 1:
            for xi, target in zip(X, y):
                self._update_weights(xi, target)
        else:
            self._update_weights(X, y)
        return self

    def _shuffle(self, X, y):
        """Shuffle training data"""
        r = np.random.permutation(len(y))
        return X[r], y[r]
    
    def _initialize_weights(self, m):
        """Initialize weights to zeros"""
        self.w_ = np.zeros(1 + m)
        self.w_initialized = True
        
    def _update_weights(self, xi, target):
        """Apply Adaline learning rule to update the weights"""
        output = self.net_input(xi)
        error = (target - output)
        self.w_[1:] += self.eta * xi.dot(error)
        self.w_[0] += self.eta * error
        cost = 0.5 * error**2
        return cost
    
    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

The _shuffle method that we are now using in the AdalineSGD classifier works as follows: via the permutation function in numpy.random, we generate a random sequence of unique numbers in the range 0 to 100. Those numbers can then be used as indices to shuffle our feature matrix and class label vector.

We can then use the fit method to train the AdalineSGD classifier and use our plot_decision_regions to plot our training results:

>>> ada = AdalineSGD(n_iter=15, eta=0.01, random_state=1)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Stochastic Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Average Cost')
>>> plt.show()

The two plots that we obtain from executing the preceding code example are shown in the following figure:

Large scale machine learning and stochastic gradient descent

As we can see, the average cost goes down pretty quickly, and the final decision boundary after 15 epochs looks similar to the batch gradient descent with Adaline. If we want to update our model—for example, in an on-line learning scenario with streaming data—we could simply call the partial_fit method on individual samples—for instance, ada.partial_fit(X_std[0, :], y[0]).

Minimizing cost functions with gradient descent

One of the key ingredients of supervised machine learning algorithms is to define an objective function that is to be optimized during the learning process. This objective function is often a cost function that we want to minimize. In the case of Adaline, we can define the cost function Minimizing cost functions with gradient descent to learn the weights as the Sum of Squared Errors (SSE) between the calculated outcome and the true class label Minimizing cost functions with gradient descent.

The term Minimizing cost functions with gradient descent is just added for our convenience; it will make it easier to derive the gradient, as we will see in the following paragraphs. The main advantage of this continuous linear activation function is—in contrast to the unit step function—that the cost function becomes differentiable. Another nice property of this cost function is that it is convex; thus, we can use a simple, yet powerful, optimization algorithm called gradient descent to find the weights that minimize our cost function to classify the samples in the Iris dataset.

As illustrated in the following figure, we can describe the principle behind gradient descent as climbing down a hill until a local or global cost minimum is reached. In each iteration, we take a step away from the gradient where the step size is determined by the value of the learning rate as well as the slope of the gradient:

Minimizing cost functions with gradient descent

Using gradient descent, we can now update the weights by taking a step away from the gradient Minimizing cost functions with gradient descent of our cost function Minimizing cost functions with gradient descent:

Minimizing cost functions with gradient descent

Here, the weight change Minimizing cost functions with gradient descent is defined as the negative gradient multiplied by the learning rate Minimizing cost functions with gradient descent:

Minimizing cost functions with gradient descent

.

To compute the gradient of the cost function, we need to compute the partial derivative of the cost function with respect to each weight Minimizing cost functions with gradient descent Minimizing cost functions with gradient descent so that we can write the update of weight Minimizing cost functions with gradient descent as: Minimizing cost functions with gradient descent:

Since we update all weights simultaneously, our Adaline learning rule becomes Minimizing cost functions with gradient descent.

Note

For those who are familiar with calculus, the partial derivative of the SSE cost function with respect to the jth weight in can be obtained as follows:

Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent
Minimizing cost functions with gradient descent

Although the Adaline learning rule looks identical to the perceptron rule, the Minimizing cost functions with gradient descent with Minimizing cost functions with gradient descent = Minimizing cost functions with gradient descent is a real number and not an integer class label. Furthermore, the weight update is calculated based on all samples in the training set (instead of updating the weights incrementally after each sample), which is why this approach is also referred to as "batch" gradient descent.

Implementing an Adaptive Linear Neuron in Python

Since the perceptron rule and Adaline are very similar, we will take the perceptron implementation that we defined earlier and change the fit method so that the weights are updated by minimizing the cost function via gradient descent:

class AdalineGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.
    
    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.

    """
    def __init__(self, eta=0.01, n_iter=50):
        self.eta = eta
        self.n_iter = n_iter

    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, 
            where n_samples is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

        """
        self.w_ = np.zeros(1 + X.shape[1])
        self.cost_ = []

        for i in range(self.n_iter):
            output = self.net_input(X)
            errors = (y - output)
            self.w_[1:] += self.eta * X.T.dot(errors)
            self.w_[0] += self.eta * errors.sum()
            cost = (errors**2).sum() / 2.0
            self.cost_.append(cost)
        return self

    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

Instead of updating the weights after evaluating each individual training sample, as in the perceptron, we calculate the gradient based on the whole training dataset via self.eta * errors.sum() for the zero-weight and via self.eta * X.T.dot(errors) for the weights 1 to Implementing an Adaptive Linear Neuron in Python where X.T.dot(errors) is a matrix-vector multiplication between our feature matrix and the error vector. Similar to the previous perceptron implementation, we collect the cost values in a list self.cost_ to check if the algorithm converged after training.

Note

Performing a matrix-vector multiplication is similar to calculating a vector dot product where each row in the matrix is treated as a single row vector. This vectorized approach represents a more compact notation and results in a more efficient computation using NumPy. For example:

Implementing an Adaptive Linear Neuron in Python

.

In practice, it often requires some experimentation to find a good learning rate Implementing an Adaptive Linear Neuron in Python for optimal convergence. So, let's choose two different learning rates Implementing an Adaptive Linear Neuron in Python and Implementing an Adaptive Linear Neuron in Python to start with and plot the cost functions versus the number of epochs to see how well the Adaline implementation learns from the training data.

Note

The learning rate Implementing an Adaptive Linear Neuron in Python, as well as the number of epochs n_iter, are the so-called hyperparameters of the perceptron and Adaline learning algorithms. In Chapter 4, Building Good Training Sets—Data Preprocessing, we will take a look at different techniques to automatically find the values of different hyperparameters that yield optimal performance of the classification model.

Let us now plot the cost against the number of epochs for the two different learning rates:

>>> fig, ax = plt.subplots(nrows=1, ncols=2, figsize=(8, 4))
>>> ada1 = AdalineGD(n_iter=10, eta=0.01).fit(X, y)
>>> ax[0].plot(range(1, len(ada1.cost_) + 1),
...            np.log10(ada1.cost_), marker='o')
>>> ax[0].set_xlabel('Epochs')
>>> ax[0].set_ylabel('log(Sum-squared-error)')
>>> ax[0].set_title('Adaline - Learning rate 0.01')
>>> ada2 = AdalineGD(n_iter=10, eta=0.0001).fit(X, y)
>>> ax[1].plot(range(1, len(ada2.cost_) + 1),
...            ada2.cost_, marker='o')
>>> ax[1].set_xlabel('Epochs')
>>> ax[1].set_ylabel('Sum-squared-error')
>>> ax[1].set_title('Adaline - Learning rate 0.0001')
>>> plt.show()

As we can see in the resulting cost function plots next, we encountered two different types of problems. The left chart shows what could happen if we choose a learning rate that is too large—instead of minimizing the cost function, the error becomes larger in every epoch because we overshoot the global minimum:

Implementing an Adaptive Linear Neuron in Python

Although we can see that the cost decreases when we look at the right plot, the chosen learning rate Implementing an Adaptive Linear Neuron in Python is so small that the algorithm would require a very large number of epochs to converge. The following figure illustrates how we change the value of a particular weight parameter to minimize the cost function Implementing an Adaptive Linear Neuron in Python (left subfigure). The subfigure on the right illustrates what happens if we choose a learning rate that is too large, we overshoot the global minimum:

Implementing an Adaptive Linear Neuron in Python

Many machine learning algorithms that we will encounter throughout this book require some sort of feature scaling for optimal performance, which we will discuss in more detail in Chapter 3, A Tour of Machine Learning Classifiers Using Scikit-learn. Gradient descent is one of the many algorithms that benefit from feature scaling. Here, we will use a feature scaling method called standardization, which gives our data the property of a standard normal distribution. The mean of each feature is centered at value 0 and the feature column has a standard deviation of 1. For example, to standardize the Implementing an Adaptive Linear Neuron in Pythonth feature, we simply need to subtract the sample mean Implementing an Adaptive Linear Neuron in Python from every training sample and divide it by its standard deviation Implementing an Adaptive Linear Neuron in Python:

Implementing an Adaptive Linear Neuron in Python

Here Implementing an Adaptive Linear Neuron in Python is a vector consisting of the Implementing an Adaptive Linear Neuron in Pythonth feature values of all training samples Implementing an Adaptive Linear Neuron in Python.

Standardization can easily be achieved using the NumPy methods mean and std:

>>> X_std = np.copy(X)
>>> X_std[:,0] = (X[:,0] - X[:,0].mean()) / X[:,0].std()
>>> X_std[:,1] = (X[:,1] - X[:,1].mean()) / X[:,1].std()

After standardization, we will train the Adaline again and see that it now converges using a learning rate Implementing an Adaptive Linear Neuron in Python:

>>> ada = AdalineGD(n_iter=15, eta=0.01)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Sum-squared-error')
>>> plt.show()

After executing the preceding code, we should see a figure of the decision regions as well as a plot of the declining cost, as shown in the following figure:

Implementing an Adaptive Linear Neuron in Python

As we can see in the preceding plots, the Adaline now converges after training on the standardized features using a learning rate Implementing an Adaptive Linear Neuron in Python. However, note that the SSE remains non-zero even though all samples were classified correctly.

Large scale machine learning and stochastic gradient descent

In the previous section, we learned how to minimize a cost function by taking a step into the opposite direction of a gradient that is calculated from the whole training set; this is why this approach is sometimes also referred to as batch gradient descent. Now imagine we have a very large dataset with millions of data points, which is not uncommon in many machine learning applications. Running batch gradient descent can be computationally quite costly in such scenarios since we need to reevaluate the whole training dataset each time we take one step towards the global minimum.

A popular alternative to the batch gradient descent algorithm is stochastic gradient descent, sometimes also called iterative or on-line gradient descent. Instead of updating the weights based on the sum of the accumulated errors over all samples Large scale machine learning and stochastic gradient descent:

Large scale machine learning and stochastic gradient descent

We update the weights incrementally for each training sample:

Large scale machine learning and stochastic gradient descent

Although stochastic gradient descent can be considered as an approximation of gradient descent, it typically reaches convergence much faster because of the more frequent weight updates. Since each gradient is calculated based on a single training example, the error surface is noisier than in gradient descent, which can also have the advantage that stochastic gradient descent can escape shallow local minima more readily. To obtain accurate results via stochastic gradient descent, it is important to present it with data in a random order, which is why we want to shuffle the training set for every epoch to prevent cycles.

Note

In stochastic gradient descent implementations, the fixed learning rate Large scale machine learning and stochastic gradient descent is often replaced by an adaptive learning rate that decreases over time, for example, Large scale machine learning and stochastic gradient descent where Large scale machine learning and stochastic gradient descent and Large scale machine learning and stochastic gradient descent are constants. Note that stochastic gradient descent does not reach the global minimum but an area very close to it. By using an adaptive learning rate, we can achieve further annealing to a better global minimum

Another advantage of stochastic gradient descent is that we can use it for online learning. In online learning, our model is trained on-the-fly as new training data arrives. This is especially useful if we are accumulating large amounts of data—for example, customer data in typical web applications. Using online learning, the system can immediately adapt to changes and the training data can be discarded after updating the model if storage space in an issue.

Note

A compromise between batch gradient descent and stochastic gradient descent is the so-called mini-batch learning. Mini-batch learning can be understood as applying batch gradient descent to smaller subsets of the training data—for example, 50 samples at a time. The advantage over batch gradient descent is that convergence is reached faster via mini-batches because of the more frequent weight updates. Furthermore, mini-batch learning allows us to replace the for-loop over the training samples in Stochastic Gradient Descent (SGD) by vectorized operations, which can further improve the computational efficiency of our learning algorithm.

Since we already implemented the Adaline learning rule using gradient descent, we only need to make a few adjustments to modify the learning algorithm to update the weights via stochastic gradient descent. Inside the fit method, we will now update the weights after each training sample. Furthermore, we will implement an additional partial_fit method, which does not reinitialize the weights, for on-line learning. In order to check if our algorithm converged after training, we will calculate the cost as the average cost of the training samples in each epoch. Furthermore, we will add an option to shuffle the training data before each epoch to avoid cycles when we are optimizing the cost function; via the random_state parameter, we allow the specification of a random seed for consistency:

from numpy.random import seed

class AdalineSGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.

    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.
    shuffle : bool (default: True)
        Shuffles training data every epoch 
        if True to prevent cycles.
    random_state : int (default: None)
        Set random state for shuffling 
        and initializing the weights.
        
    """
    def __init__(self, eta=0.01, n_iter=10, 
               shuffle=True, random_state=None):
        self.eta = eta
        self.n_iter = n_iter
        self.w_initialized = False
        self.shuffle = shuffle
        if random_state:
            seed(random_state)
        
    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, where n_samples 
            is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

         """
        self._initialize_weights(X.shape[1])
        self.cost_ = []
        for i in range(self.n_iter):
            if self.shuffle:
                X, y = self._shuffle(X, y)
            cost = []
            for xi, target in zip(X, y):
                cost.append(self._update_weights(xi, target))
            avg_cost = sum(cost)/len(y)
            self.cost_.append(avg_cost)
        return self

    def partial_fit(self, X, y):
        """Fit training data without reinitializing the weights"""
        if not self.w_initialized:
            self._initialize_weights(X.shape[1])
        if y.ravel().shape[0] > 1:
            for xi, target in zip(X, y):
                self._update_weights(xi, target)
        else:
            self._update_weights(X, y)
        return self

    def _shuffle(self, X, y):
        """Shuffle training data"""
        r = np.random.permutation(len(y))
        return X[r], y[r]
    
    def _initialize_weights(self, m):
        """Initialize weights to zeros"""
        self.w_ = np.zeros(1 + m)
        self.w_initialized = True
        
    def _update_weights(self, xi, target):
        """Apply Adaline learning rule to update the weights"""
        output = self.net_input(xi)
        error = (target - output)
        self.w_[1:] += self.eta * xi.dot(error)
        self.w_[0] += self.eta * error
        cost = 0.5 * error**2
        return cost
    
    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

The _shuffle method that we are now using in the AdalineSGD classifier works as follows: via the permutation function in numpy.random, we generate a random sequence of unique numbers in the range 0 to 100. Those numbers can then be used as indices to shuffle our feature matrix and class label vector.

We can then use the fit method to train the AdalineSGD classifier and use our plot_decision_regions to plot our training results:

>>> ada = AdalineSGD(n_iter=15, eta=0.01, random_state=1)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Stochastic Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Average Cost')
>>> plt.show()

The two plots that we obtain from executing the preceding code example are shown in the following figure:

Large scale machine learning and stochastic gradient descent

As we can see, the average cost goes down pretty quickly, and the final decision boundary after 15 epochs looks similar to the batch gradient descent with Adaline. If we want to update our model—for example, in an on-line learning scenario with streaming data—we could simply call the partial_fit method on individual samples—for instance, ada.partial_fit(X_std[0, :], y[0]).

Implementing an Adaptive Linear Neuron in Python

Since the perceptron rule and Adaline are very similar, we will take the perceptron implementation that we defined earlier and change the fit method so that the weights are updated by minimizing the cost function via gradient descent:

class AdalineGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.
    
    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.

    """
    def __init__(self, eta=0.01, n_iter=50):
        self.eta = eta
        self.n_iter = n_iter

    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, 
            where n_samples is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

        """
        self.w_ = np.zeros(1 + X.shape[1])
        self.cost_ = []

        for i in range(self.n_iter):
            output = self.net_input(X)
            errors = (y - output)
            self.w_[1:] += self.eta * X.T.dot(errors)
            self.w_[0] += self.eta * errors.sum()
            cost = (errors**2).sum() / 2.0
            self.cost_.append(cost)
        return self

    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

Instead of updating the weights after evaluating each individual training sample, as in the perceptron, we calculate the gradient based on the whole training dataset via self.eta * errors.sum() for the zero-weight and via self.eta * X.T.dot(errors) for the weights 1 to Implementing an Adaptive Linear Neuron in Python where X.T.dot(errors) is a matrix-vector multiplication between our feature matrix and the error vector. Similar to the previous perceptron implementation, we collect the cost values in a list self.cost_ to check if the algorithm converged after training.

Note

Performing a matrix-vector multiplication is similar to calculating a vector dot product where each row in the matrix is treated as a single row vector. This vectorized approach represents a more compact notation and results in a more efficient computation using NumPy. For example:

Implementing an Adaptive Linear Neuron in Python

.

In practice, it often requires some experimentation to find a good learning rate Implementing an Adaptive Linear Neuron in Python for optimal convergence. So, let's choose two different learning rates Implementing an Adaptive Linear Neuron in Python and Implementing an Adaptive Linear Neuron in Python to start with and plot the cost functions versus the number of epochs to see how well the Adaline implementation learns from the training data.

Note

The learning rate Implementing an Adaptive Linear Neuron in Python, as well as the number of epochs n_iter, are the so-called hyperparameters of the perceptron and Adaline learning algorithms. In Chapter 4, Building Good Training Sets—Data Preprocessing, we will take a look at different techniques to automatically find the values of different hyperparameters that yield optimal performance of the classification model.

Let us now plot the cost against the number of epochs for the two different learning rates:

>>> fig, ax = plt.subplots(nrows=1, ncols=2, figsize=(8, 4))
>>> ada1 = AdalineGD(n_iter=10, eta=0.01).fit(X, y)
>>> ax[0].plot(range(1, len(ada1.cost_) + 1),
...            np.log10(ada1.cost_), marker='o')
>>> ax[0].set_xlabel('Epochs')
>>> ax[0].set_ylabel('log(Sum-squared-error)')
>>> ax[0].set_title('Adaline - Learning rate 0.01')
>>> ada2 = AdalineGD(n_iter=10, eta=0.0001).fit(X, y)
>>> ax[1].plot(range(1, len(ada2.cost_) + 1),
...            ada2.cost_, marker='o')
>>> ax[1].set_xlabel('Epochs')
>>> ax[1].set_ylabel('Sum-squared-error')
>>> ax[1].set_title('Adaline - Learning rate 0.0001')
>>> plt.show()

As we can see in the resulting cost function plots next, we encountered two different types of problems. The left chart shows what could happen if we choose a learning rate that is too large—instead of minimizing the cost function, the error becomes larger in every epoch because we overshoot the global minimum:

Implementing an Adaptive Linear Neuron in Python

Although we can see that the cost decreases when we look at the right plot, the chosen learning rate Implementing an Adaptive Linear Neuron in Python is so small that the algorithm would require a very large number of epochs to converge. The following figure illustrates how we change the value of a particular weight parameter to minimize the cost function Implementing an Adaptive Linear Neuron in Python (left subfigure). The subfigure on the right illustrates what happens if we choose a learning rate that is too large, we overshoot the global minimum:

Implementing an Adaptive Linear Neuron in Python

Many machine learning algorithms that we will encounter throughout this book require some sort of feature scaling for optimal performance, which we will discuss in more detail in Chapter 3, A Tour of Machine Learning Classifiers Using Scikit-learn. Gradient descent is one of the many algorithms that benefit from feature scaling. Here, we will use a feature scaling method called standardization, which gives our data the property of a standard normal distribution. The mean of each feature is centered at value 0 and the feature column has a standard deviation of 1. For example, to standardize the Implementing an Adaptive Linear Neuron in Pythonth feature, we simply need to subtract the sample mean Implementing an Adaptive Linear Neuron in Python from every training sample and divide it by its standard deviation Implementing an Adaptive Linear Neuron in Python:

Implementing an Adaptive Linear Neuron in Python

Here Implementing an Adaptive Linear Neuron in Python is a vector consisting of the Implementing an Adaptive Linear Neuron in Pythonth feature values of all training samples Implementing an Adaptive Linear Neuron in Python.

Standardization can easily be achieved using the NumPy methods mean and std:

>>> X_std = np.copy(X)
>>> X_std[:,0] = (X[:,0] - X[:,0].mean()) / X[:,0].std()
>>> X_std[:,1] = (X[:,1] - X[:,1].mean()) / X[:,1].std()

After standardization, we will train the Adaline again and see that it now converges using a learning rate Implementing an Adaptive Linear Neuron in Python:

>>> ada = AdalineGD(n_iter=15, eta=0.01)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Sum-squared-error')
>>> plt.show()

After executing the preceding code, we should see a figure of the decision regions as well as a plot of the declining cost, as shown in the following figure:

Implementing an Adaptive Linear Neuron in Python

As we can see in the preceding plots, the Adaline now converges after training on the standardized features using a learning rate Implementing an Adaptive Linear Neuron in Python. However, note that the SSE remains non-zero even though all samples were classified correctly.

Large scale machine learning and stochastic gradient descent

In the previous section, we learned how to minimize a cost function by taking a step into the opposite direction of a gradient that is calculated from the whole training set; this is why this approach is sometimes also referred to as batch gradient descent. Now imagine we have a very large dataset with millions of data points, which is not uncommon in many machine learning applications. Running batch gradient descent can be computationally quite costly in such scenarios since we need to reevaluate the whole training dataset each time we take one step towards the global minimum.

A popular alternative to the batch gradient descent algorithm is stochastic gradient descent, sometimes also called iterative or on-line gradient descent. Instead of updating the weights based on the sum of the accumulated errors over all samples Large scale machine learning and stochastic gradient descent:

Large scale machine learning and stochastic gradient descent

We update the weights incrementally for each training sample:

Large scale machine learning and stochastic gradient descent

Although stochastic gradient descent can be considered as an approximation of gradient descent, it typically reaches convergence much faster because of the more frequent weight updates. Since each gradient is calculated based on a single training example, the error surface is noisier than in gradient descent, which can also have the advantage that stochastic gradient descent can escape shallow local minima more readily. To obtain accurate results via stochastic gradient descent, it is important to present it with data in a random order, which is why we want to shuffle the training set for every epoch to prevent cycles.

Note

In stochastic gradient descent implementations, the fixed learning rate Large scale machine learning and stochastic gradient descent is often replaced by an adaptive learning rate that decreases over time, for example, Large scale machine learning and stochastic gradient descent where Large scale machine learning and stochastic gradient descent and Large scale machine learning and stochastic gradient descent are constants. Note that stochastic gradient descent does not reach the global minimum but an area very close to it. By using an adaptive learning rate, we can achieve further annealing to a better global minimum

Another advantage of stochastic gradient descent is that we can use it for online learning. In online learning, our model is trained on-the-fly as new training data arrives. This is especially useful if we are accumulating large amounts of data—for example, customer data in typical web applications. Using online learning, the system can immediately adapt to changes and the training data can be discarded after updating the model if storage space in an issue.

Note

A compromise between batch gradient descent and stochastic gradient descent is the so-called mini-batch learning. Mini-batch learning can be understood as applying batch gradient descent to smaller subsets of the training data—for example, 50 samples at a time. The advantage over batch gradient descent is that convergence is reached faster via mini-batches because of the more frequent weight updates. Furthermore, mini-batch learning allows us to replace the for-loop over the training samples in Stochastic Gradient Descent (SGD) by vectorized operations, which can further improve the computational efficiency of our learning algorithm.

Since we already implemented the Adaline learning rule using gradient descent, we only need to make a few adjustments to modify the learning algorithm to update the weights via stochastic gradient descent. Inside the fit method, we will now update the weights after each training sample. Furthermore, we will implement an additional partial_fit method, which does not reinitialize the weights, for on-line learning. In order to check if our algorithm converged after training, we will calculate the cost as the average cost of the training samples in each epoch. Furthermore, we will add an option to shuffle the training data before each epoch to avoid cycles when we are optimizing the cost function; via the random_state parameter, we allow the specification of a random seed for consistency:

from numpy.random import seed

class AdalineSGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.

    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.
    shuffle : bool (default: True)
        Shuffles training data every epoch 
        if True to prevent cycles.
    random_state : int (default: None)
        Set random state for shuffling 
        and initializing the weights.
        
    """
    def __init__(self, eta=0.01, n_iter=10, 
               shuffle=True, random_state=None):
        self.eta = eta
        self.n_iter = n_iter
        self.w_initialized = False
        self.shuffle = shuffle
        if random_state:
            seed(random_state)
        
    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, where n_samples 
            is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

         """
        self._initialize_weights(X.shape[1])
        self.cost_ = []
        for i in range(self.n_iter):
            if self.shuffle:
                X, y = self._shuffle(X, y)
            cost = []
            for xi, target in zip(X, y):
                cost.append(self._update_weights(xi, target))
            avg_cost = sum(cost)/len(y)
            self.cost_.append(avg_cost)
        return self

    def partial_fit(self, X, y):
        """Fit training data without reinitializing the weights"""
        if not self.w_initialized:
            self._initialize_weights(X.shape[1])
        if y.ravel().shape[0] > 1:
            for xi, target in zip(X, y):
                self._update_weights(xi, target)
        else:
            self._update_weights(X, y)
        return self

    def _shuffle(self, X, y):
        """Shuffle training data"""
        r = np.random.permutation(len(y))
        return X[r], y[r]
    
    def _initialize_weights(self, m):
        """Initialize weights to zeros"""
        self.w_ = np.zeros(1 + m)
        self.w_initialized = True
        
    def _update_weights(self, xi, target):
        """Apply Adaline learning rule to update the weights"""
        output = self.net_input(xi)
        error = (target - output)
        self.w_[1:] += self.eta * xi.dot(error)
        self.w_[0] += self.eta * error
        cost = 0.5 * error**2
        return cost
    
    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

The _shuffle method that we are now using in the AdalineSGD classifier works as follows: via the permutation function in numpy.random, we generate a random sequence of unique numbers in the range 0 to 100. Those numbers can then be used as indices to shuffle our feature matrix and class label vector.

We can then use the fit method to train the AdalineSGD classifier and use our plot_decision_regions to plot our training results:

>>> ada = AdalineSGD(n_iter=15, eta=0.01, random_state=1)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Stochastic Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Average Cost')
>>> plt.show()

The two plots that we obtain from executing the preceding code example are shown in the following figure:

Large scale machine learning and stochastic gradient descent

As we can see, the average cost goes down pretty quickly, and the final decision boundary after 15 epochs looks similar to the batch gradient descent with Adaline. If we want to update our model—for example, in an on-line learning scenario with streaming data—we could simply call the partial_fit method on individual samples—for instance, ada.partial_fit(X_std[0, :], y[0]).

Large scale machine learning and stochastic gradient descent

In the previous section, we learned how to minimize a cost function by taking a step into the opposite direction of a gradient that is calculated from the whole training set; this is why this approach is sometimes also referred to as batch gradient descent. Now imagine we have a very large dataset with millions of data points, which is not uncommon in many machine learning applications. Running batch gradient descent can be computationally quite costly in such scenarios since we need to reevaluate the whole training dataset each time we take one step towards the global minimum.

A popular alternative to the batch gradient descent algorithm is stochastic gradient descent, sometimes also called iterative or on-line gradient descent. Instead of updating the weights based on the sum of the accumulated errors over all samples Large scale machine learning and stochastic gradient descent:

Large scale machine learning and stochastic gradient descent

We update the weights incrementally for each training sample:

Large scale machine learning and stochastic gradient descent

Although stochastic gradient descent can be considered as an approximation of gradient descent, it typically reaches convergence much faster because of the more frequent weight updates. Since each gradient is calculated based on a single training example, the error surface is noisier than in gradient descent, which can also have the advantage that stochastic gradient descent can escape shallow local minima more readily. To obtain accurate results via stochastic gradient descent, it is important to present it with data in a random order, which is why we want to shuffle the training set for every epoch to prevent cycles.

Note

In stochastic gradient descent implementations, the fixed learning rate Large scale machine learning and stochastic gradient descent is often replaced by an adaptive learning rate that decreases over time, for example, Large scale machine learning and stochastic gradient descent where Large scale machine learning and stochastic gradient descent and Large scale machine learning and stochastic gradient descent are constants. Note that stochastic gradient descent does not reach the global minimum but an area very close to it. By using an adaptive learning rate, we can achieve further annealing to a better global minimum

Another advantage of stochastic gradient descent is that we can use it for online learning. In online learning, our model is trained on-the-fly as new training data arrives. This is especially useful if we are accumulating large amounts of data—for example, customer data in typical web applications. Using online learning, the system can immediately adapt to changes and the training data can be discarded after updating the model if storage space in an issue.

Note

A compromise between batch gradient descent and stochastic gradient descent is the so-called mini-batch learning. Mini-batch learning can be understood as applying batch gradient descent to smaller subsets of the training data—for example, 50 samples at a time. The advantage over batch gradient descent is that convergence is reached faster via mini-batches because of the more frequent weight updates. Furthermore, mini-batch learning allows us to replace the for-loop over the training samples in Stochastic Gradient Descent (SGD) by vectorized operations, which can further improve the computational efficiency of our learning algorithm.

Since we already implemented the Adaline learning rule using gradient descent, we only need to make a few adjustments to modify the learning algorithm to update the weights via stochastic gradient descent. Inside the fit method, we will now update the weights after each training sample. Furthermore, we will implement an additional partial_fit method, which does not reinitialize the weights, for on-line learning. In order to check if our algorithm converged after training, we will calculate the cost as the average cost of the training samples in each epoch. Furthermore, we will add an option to shuffle the training data before each epoch to avoid cycles when we are optimizing the cost function; via the random_state parameter, we allow the specification of a random seed for consistency:

from numpy.random import seed

class AdalineSGD(object):
    """ADAptive LInear NEuron classifier.

    Parameters
    ------------
    eta : float
        Learning rate (between 0.0 and 1.0)
    n_iter : int
        Passes over the training dataset.

    Attributes
    -----------
    w_ : 1d-array
        Weights after fitting.
    errors_ : list
        Number of misclassifications in every epoch.
    shuffle : bool (default: True)
        Shuffles training data every epoch 
        if True to prevent cycles.
    random_state : int (default: None)
        Set random state for shuffling 
        and initializing the weights.
        
    """
    def __init__(self, eta=0.01, n_iter=10, 
               shuffle=True, random_state=None):
        self.eta = eta
        self.n_iter = n_iter
        self.w_initialized = False
        self.shuffle = shuffle
        if random_state:
            seed(random_state)
        
    def fit(self, X, y):
        """ Fit training data.

        Parameters
        ----------
        X : {array-like}, shape = [n_samples, n_features]
            Training vectors, where n_samples 
            is the number of samples and
            n_features is the number of features.
        y : array-like, shape = [n_samples]
            Target values.

        Returns
        -------
        self : object

         """
        self._initialize_weights(X.shape[1])
        self.cost_ = []
        for i in range(self.n_iter):
            if self.shuffle:
                X, y = self._shuffle(X, y)
            cost = []
            for xi, target in zip(X, y):
                cost.append(self._update_weights(xi, target))
            avg_cost = sum(cost)/len(y)
            self.cost_.append(avg_cost)
        return self

    def partial_fit(self, X, y):
        """Fit training data without reinitializing the weights"""
        if not self.w_initialized:
            self._initialize_weights(X.shape[1])
        if y.ravel().shape[0] > 1:
            for xi, target in zip(X, y):
                self._update_weights(xi, target)
        else:
            self._update_weights(X, y)
        return self

    def _shuffle(self, X, y):
        """Shuffle training data"""
        r = np.random.permutation(len(y))
        return X[r], y[r]
    
    def _initialize_weights(self, m):
        """Initialize weights to zeros"""
        self.w_ = np.zeros(1 + m)
        self.w_initialized = True
        
    def _update_weights(self, xi, target):
        """Apply Adaline learning rule to update the weights"""
        output = self.net_input(xi)
        error = (target - output)
        self.w_[1:] += self.eta * xi.dot(error)
        self.w_[0] += self.eta * error
        cost = 0.5 * error**2
        return cost
    
    def net_input(self, X):
        """Calculate net input"""
        return np.dot(X, self.w_[1:]) + self.w_[0]

    def activation(self, X):
        """Compute linear activation"""
        return self.net_input(X)

    def predict(self, X):
        """Return class label after unit step"""
        return np.where(self.activation(X) >= 0.0, 1, -1)

The _shuffle method that we are now using in the AdalineSGD classifier works as follows: via the permutation function in numpy.random, we generate a random sequence of unique numbers in the range 0 to 100. Those numbers can then be used as indices to shuffle our feature matrix and class label vector.

We can then use the fit method to train the AdalineSGD classifier and use our plot_decision_regions to plot our training results:

>>> ada = AdalineSGD(n_iter=15, eta=0.01, random_state=1)
>>> ada.fit(X_std, y)
>>> plot_decision_regions(X_std, y, classifier=ada)
>>> plt.title('Adaline - Stochastic Gradient Descent')
>>> plt.xlabel('sepal length [standardized]')
>>> plt.ylabel('petal length [standardized]')
>>> plt.legend(loc='upper left')
>>> plt.show()
>>> plt.plot(range(1, len(ada.cost_) + 1), ada.cost_, marker='o')
>>> plt.xlabel('Epochs')
>>> plt.ylabel('Average Cost')
>>> plt.show()

The two plots that we obtain from executing the preceding code example are shown in the following figure:

Large scale machine learning and stochastic gradient descent

As we can see, the average cost goes down pretty quickly, and the final decision boundary after 15 epochs looks similar to the batch gradient descent with Adaline. If we want to update our model—for example, in an on-line learning scenario with streaming data—we could simply call the partial_fit method on individual samples—for instance, ada.partial_fit(X_std[0, :], y[0]).

Summary

In this chapter, we gained a good understanding of the basic concepts of linear classifiers for supervised learning. After we implemented a perceptron, we saw how we can train adaptive linear neurons efficiently via a vectorized implementation of gradient descent and on-line learning via stochastic gradient descent. Now that we have seen how to implement simple classifiers in Python, we are ready to move on to the next chapter where we will use the Python scikit-learn machine learning library to get access to more advanced and powerful off-the-shelf machine learning classifiers that are commonly used in academia as well as in industry.

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