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176 lines
5.5 KiB
Matlab
176 lines
5.5 KiB
Matlab
%% Machine Learning Online Class
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% Exercise 7 | Principle Component Analysis and K-Means Clustering
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%
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% Instructions
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% ------------
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%
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% This file contains code that helps you get started on the
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% exercise. You will need to complete the following functions:
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%
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% pca.m
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% projectData.m
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% recoverData.m
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% computeCentroids.m
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% findClosestCentroids.m
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% kMeansInitCentroids.m
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%
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% For this exercise, you will not need to change any code in this file,
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% or any other files other than those mentioned above.
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%
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%% Initialization
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clear ; close all; clc
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%% ================= Part 1: Find Closest Centroids ====================
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% To help you implement K-Means, we have divided the learning algorithm
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% into two functions -- findClosestCentroids and computeCentroids. In this
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% part, you shoudl complete the code in the findClosestCentroids function.
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%
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fprintf('Finding closest centroids.\n\n');
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% Load an example dataset that we will be using
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load('ex7data2.mat');
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% Select an initial set of centroids
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K = 3; % 3 Centroids
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initial_centroids = [3 3; 6 2; 8 5];
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% Find the closest centroids for the examples using the
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% initial_centroids
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idx = findClosestCentroids(X, initial_centroids);
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fprintf('Closest centroids for the first 3 examples: \n')
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fprintf(' %d', idx(1:3));
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fprintf('\n(the closest centroids should be 1, 3, 2 respectively)\n');
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fprintf('Program paused. Press enter to continue.\n');
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pause;
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%% ===================== Part 2: Compute Means =========================
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% After implementing the closest centroids function, you should now
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% complete the computeCentroids function.
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%
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fprintf('\nComputing centroids means.\n\n');
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% Compute means based on the closest centroids found in the previous part.
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centroids = computeCentroids(X, idx, K);
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fprintf('Centroids computed after initial finding of closest centroids: \n')
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fprintf(' %f %f \n' , centroids');
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fprintf('\n(the centroids should be\n');
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fprintf(' [ 2.428301 3.157924 ]\n');
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fprintf(' [ 5.813503 2.633656 ]\n');
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fprintf(' [ 7.119387 3.616684 ]\n\n');
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fprintf('Program paused. Press enter to continue.\n');
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pause;
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%% =================== Part 3: K-Means Clustering ======================
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% After you have completed the two functions computeCentroids and
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% findClosestCentroids, you have all the necessary pieces to run the
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% kMeans algorithm. In this part, you will run the K-Means algorithm on
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% the example dataset we have provided.
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%
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fprintf('\nRunning K-Means clustering on example dataset.\n\n');
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% Load an example dataset
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load('ex7data2.mat');
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% Settings for running K-Means
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K = 3;
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max_iters = 10;
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% For consistency, here we set centroids to specific values
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% but in practice you want to generate them automatically, such as by
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% settings them to be random examples (as can be seen in
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% kMeansInitCentroids).
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initial_centroids = [3 3; 6 2; 8 5];
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%initial_centroids = kMeansInitCentroids(X, K);
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% Run K-Means algorithm. The 'true' at the end tells our function to plot
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% the progress of K-Means
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[centroids, idx] = runkMeans(X, initial_centroids, max_iters, true);
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fprintf('\nK-Means Done.\n\n');
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fprintf('Program paused. Press enter to continue.\n');
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pause;
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%% ============= Part 4: K-Means Clustering on Pixels ===============
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% In this exercise, you will use K-Means to compress an image. To do this,
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% you will first run K-Means on the colors of the pixels in the image and
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% then you will map each pixel on to it's closest centroid.
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%
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% You should now complete the code in kMeansInitCentroids.m
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%
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fprintf('\nRunning K-Means clustering on pixels from an image.\n\n');
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% Load an image of a bird
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A = double(imread('bird_small.png'));
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% If imread does not work for you, you can try instead
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% load ('bird_small.mat');
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A = A / 255; % Divide by 255 so that all values are in the range 0 - 1
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% Size of the image
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img_size = size(A);
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% Reshape the image into an Nx3 matrix where N = number of pixels.
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% Each row will contain the Red, Green and Blue pixel values
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% This gives us our dataset matrix X that we will use K-Means on.
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X = reshape(A, img_size(1) * img_size(2), 3);
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% Run your K-Means algorithm on this data
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% You should try different values of K and max_iters here
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K = 16;
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max_iters = 10;
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% When using K-Means, it is important the initialize the centroids
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% randomly.
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% You should complete the code in kMeansInitCentroids.m before proceeding
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initial_centroids = kMeansInitCentroids(X, K);
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% Run K-Means
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[centroids, idx] = runkMeans(X, initial_centroids, max_iters);
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fprintf('Program paused. Press enter to continue.\n');
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pause;
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%% ================= Part 5: Image Compression ======================
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% In this part of the exercise, you will use the clusters of K-Means to
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% compress an image. To do this, we first find the closest clusters for
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% each example. After that, we
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fprintf('\nApplying K-Means to compress an image.\n\n');
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% Find closest cluster members
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idx = findClosestCentroids(X, centroids);
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% Essentially, now we have represented the image X as in terms of the
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% indices in idx.
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% We can now recover the image from the indices (idx) by mapping each pixel
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% (specified by it's index in idx) to the centroid value
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X_recovered = centroids(idx,:);
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% Reshape the recovered image into proper dimensions
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X_recovered = reshape(X_recovered, img_size(1), img_size(2), 3);
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% Display the original image
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subplot(1, 2, 1);
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imagesc(A);
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title('Original');
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% Display compressed image side by side
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subplot(1, 2, 2);
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imagesc(X_recovered)
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title(sprintf('Compressed, with %d colors.', K));
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fprintf('Program paused. Press enter to continue.\n');
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pause;
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