""" overfitting ~~~~~~~~~~~ Plot graphs to illustrate the problem of overfitting. """ # Standard library import json import random import sys # My library sys.path.append('../src/') import mnist_loader import network2 # Third-party libraries import matplotlib.pyplot as plt import numpy as np def main(filename, num_epochs, training_cost_xmin=200, test_accuracy_xmin=200, test_cost_xmin=0, training_accuracy_xmin=0, training_set_size=1000, lmbda=0.0): """``filename`` is the name of the file where the results will be stored. ``num_epochs`` is the number of epochs to train for. ``training_set_size`` is the number of images to train on. ``lmbda`` is the regularization parameter. The other parameters set the epochs at which to start plotting on the x axis. """ run_network(filename, num_epochs, training_set_size, lmbda) make_plots(filename, num_epochs, test_accuracy_xmin, training_cost_xmin, test_accuracy_xmin, training_accuracy_xmin, training_set_size) def run_network(filename, num_epochs, training_set_size=1000, lmbda=0.0): """Train the network for ``num_epochs`` on ``training_set_size`` images, and store the results in ``filename``. Those results can later be used by ``make_plots``. Note that the results are stored to disk in large part because it's convenient not to have to ``run_network`` each time we want to make a plot (it's slow). """ # Make results more easily reproducible random.seed(12345678) np.random.seed(12345678) training_data, validation_data, test_data = mnist_loader.load_data_wrapper() net = network2.Network([784, 30, 10], cost=network2.CrossEntropyCost()) net.large_weight_initializer() test_cost, test_accuracy, training_cost, training_accuracy \ = net.SGD(training_data[:training_set_size], num_epochs, 10, 0.5, evaluation_data=test_data, lmbda = lmbda, monitor_evaluation_cost=True, monitor_evaluation_accuracy=True, monitor_training_cost=True, monitor_training_accuracy=True) f = open(filename, "w") json.dump([test_cost, test_accuracy, training_cost, training_accuracy], f) f.close() def make_plots(filename, num_epochs, training_cost_xmin=200, test_accuracy_xmin=200, test_cost_xmin=0, training_accuracy_xmin=0, training_set_size=1000): """Load the results from ``filename``, and generate the corresponding plots. """ f = open(filename, "r") test_cost, test_accuracy, training_cost, training_accuracy \ = json.load(f) f.close() plot_training_cost(training_cost, num_epochs, training_cost_xmin) plot_test_accuracy(test_accuracy, num_epochs, test_accuracy_xmin) plot_test_cost(test_cost, num_epochs, test_cost_xmin) plot_training_accuracy(training_accuracy, num_epochs, training_accuracy_xmin, training_set_size) plot_overlay(test_accuracy, training_accuracy, num_epochs, min(test_accuracy_xmin, training_accuracy_xmin), training_set_size) def plot_training_cost(training_cost, num_epochs, training_cost_xmin): fig = plt.figure() ax = fig.add_subplot(111) ax.plot(np.arange(training_cost_xmin, num_epochs), training_cost[training_cost_xmin:num_epochs], color='#2A6EA6') ax.set_xlim([training_cost_xmin, num_epochs]) ax.grid(True) ax.set_xlabel('Epoch') ax.set_title('Cost on the training data') plt.show() def plot_test_accuracy(test_accuracy, num_epochs, test_accuracy_xmin): fig = plt.figure() ax = fig.add_subplot(111) ax.plot(np.arange(test_accuracy_xmin, num_epochs), [accuracy/100.0 for accuracy in test_accuracy[test_accuracy_xmin:num_epochs]], color='#2A6EA6') ax.set_xlim([test_accuracy_xmin, num_epochs]) ax.grid(True) ax.set_xlabel('Epoch') ax.set_title('Accuracy (%) on the test data') plt.show() def plot_test_cost(test_cost, num_epochs, test_cost_xmin): fig = plt.figure() ax = fig.add_subplot(111) ax.plot(np.arange(test_cost_xmin, num_epochs), test_cost[test_cost_xmin:num_epochs], color='#2A6EA6') ax.set_xlim([test_cost_xmin, num_epochs]) ax.grid(True) ax.set_xlabel('Epoch') ax.set_title('Cost on the test data') plt.show() def plot_training_accuracy(training_accuracy, num_epochs, training_accuracy_xmin, training_set_size): fig = plt.figure() ax = fig.add_subplot(111) ax.plot(np.arange(training_accuracy_xmin, num_epochs), [accuracy*100.0/training_set_size for accuracy in training_accuracy[training_accuracy_xmin:num_epochs]], color='#2A6EA6') ax.set_xlim([training_accuracy_xmin, num_epochs]) ax.grid(True) ax.set_xlabel('Epoch') ax.set_title('Accuracy (%) on the training data') plt.show() def plot_overlay(test_accuracy, training_accuracy, num_epochs, xmin, training_set_size): fig = plt.figure() ax = fig.add_subplot(111) ax.plot(np.arange(xmin, num_epochs), [accuracy/100.0 for accuracy in test_accuracy], color='#2A6EA6', label="Accuracy on the test data") ax.plot(np.arange(xmin, num_epochs), [accuracy*100.0/training_set_size for accuracy in training_accuracy], color='#FFA933', label="Accuracy on the training data") ax.grid(True) ax.set_xlim([xmin, num_epochs]) ax.set_xlabel('Epoch') ax.set_ylim([90, 100]) plt.legend(loc="lower right") plt.show() if __name__ == "__main__": filename = raw_input("Enter a file name: ") num_epochs = int(raw_input( "Enter the number of epochs to run for: ")) training_cost_xmin = int(raw_input( "training_cost_xmin (suggest 200): ")) test_accuracy_xmin = int(raw_input( "test_accuracy_xmin (suggest 200): ")) test_cost_xmin = int(raw_input( "test_cost_xmin (suggest 0): ")) training_accuracy_xmin = int(raw_input( "training_accuracy_xmin (suggest 0): ")) training_set_size = int(raw_input( "Training set size (suggest 1000): ")) lmbda = float(raw_input( "Enter the regularization parameter, lambda (suggest: 5.0): ")) main(filename, num_epochs, training_cost_xmin, test_accuracy_xmin, test_cost_xmin, training_accuracy_xmin, training_set_size, lmbda)