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159 lines
5.3 KiB
Java
159 lines
5.3 KiB
Java
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/*************************************************************************
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* Compilation: javac -cp .:jama.jar PolynomialRegression.java
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* Execution: java -cp .:jama.jar PolynomialRegression
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* Dependencies: jama.jar StdOut.java
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*
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* % java -cp .:jama.jar PolynomialRegression
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* 0.01 N^3 + -1.64 N^2 + 168.92 N + -2113.73 (R^2 = 0.997)
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*
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*************************************************************************/
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import Jama.Matrix;
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import Jama.QRDecomposition;
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import edu.princeton.cs.introcs.StdOut;
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/**
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* The PolynomialRegression class performs a polynomial regression
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* on an set of N data points ( y<sub>i</sub> , x<sub>i</sub> ).
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* That is, it fits a polynomial
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* y = β<sub>0</sub> + β<sub>1</sub> x +
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* β<sub>2</sub> x <sup>2</sup> + ... +
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* β<sub> d </sub> x <sup> d </sup>
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* (where y is the response variable, x is the predictor variable,
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* and the β<sub> i </sub> are the regression coefficients)
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* that minimizes the sum of squared residuals of the multiple regression model.
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* It also computes associated the coefficient of determination R <sup>2</sup>.
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*
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* This implementation performs a QR-decomposition of the underlying
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* Vandermonde matrix, so it is not the fastest or most numerically
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* stable way to perform the polynomial regression.
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*
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* @author Robert Sedgewick
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* @author Kevin Wayne
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*/
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public class PolynomialRegression {
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private final int N; // number of observations
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private final int degree; // degree of the polynomial regression
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private final Matrix beta; // the polynomial regression coefficients
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private double SSE; // sum of squares due to error
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private double SST; // total sum of squares
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/**
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* Performs a polynomial reggression on the data points (y[i], x[i]) .
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* @param x the values of the predictor variable
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* @param y the corresponding values of the response variable
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* @param degree the degree of the polynomial to fit
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* @throws java.lang.IllegalArgumentException if the lengths of the two arrays are not equal
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*/
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public PolynomialRegression(double[] x, double[] y, int degree) {
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this.degree = degree;
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N = x.length;
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// build Vandermonde matrix
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double[][] vandermonde = new double[N][degree+1];
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for (int i = 0; i < N; i++) {
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for (int j = 0; j <= degree; j++) {
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vandermonde[i][j] = Math.pow(x[i], j);
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}
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}
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Matrix X = new Matrix(vandermonde);
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// create matrix from vector
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Matrix Y = new Matrix(y, N);
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// find least squares solution
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QRDecomposition qr = new QRDecomposition(X);
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beta = qr.solve(Y);
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// mean of y[] values
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double sum = 0.0;
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for (int i = 0; i < N; i++)
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sum += y[i];
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double mean = sum / N;
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// total variation to be accounted for
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for (int i = 0; i < N; i++) {
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double dev = y[i] - mean;
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SST += dev*dev;
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}
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// variation not accounted for
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Matrix residuals = X.times(beta).minus(Y);
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SSE = residuals.norm2() * residuals.norm2();
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}
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/**
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* Returns the j th regression coefficient
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* @return the j th regression coefficient
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*/
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public double beta(int j) {
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return beta.get(j, 0);
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}
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/**
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* Returns the degree of the polynomial to fit
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* @return the degree of the polynomial to fit
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*/
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public int degree() {
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return degree;
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}
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/**
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* Returns the coefficient of determination R <sup>2</sup>.
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* @return the coefficient of determination R <sup>2</sup>, which is a real number between 0 and 1
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*/
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public double R2() {
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if (SST == 0.0) return 1.0; // constant function
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return 1.0 - SSE/SST;
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}
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/**
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* Returns the expected response y given the value of the predictor
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* variable x .
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* @param x the value of the predictor variable
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* @return the expected response y given the value of the predictor
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* variable x
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*/
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public double predict(double x) {
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// horner's method
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double y = 0.0;
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for (int j = degree; j >= 0; j--)
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y = beta(j) + (x * y);
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return y;
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}
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/**
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* Returns a string representation of the polynomial regression model.
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* @return a string representation of the polynomial regression model,
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* including the best-fit polynomial and the coefficient of determination R <sup>2</sup>
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*/
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@Override
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public String toString() {
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String s = "";
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int j = degree;
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// ignoring leading zero coefficients
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while (j >= 0 && Math.abs(beta(j)) < 1E-5)
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j--;
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// create remaining terms
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for (j = j; j >= 0; j--) {
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if (j == 0) s += String.format("%.2f ", beta(j));
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else if (j == 1) s += String.format("%.2f N + ", beta(j));
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else s += String.format("%.2f N^%d + ", beta(j), j);
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}
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return s + " (R^2 = " + String.format("%.3f", R2()) + ")";
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}
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public static void main(String[] args) {
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double[] x = { 10, 20, 40, 80, 160, 200 };
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double[] y = { 100, 350, 1500, 6700, 20160, 40000 };
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PolynomialRegression regression = new PolynomialRegression(x, y, 3);
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StdOut.println(regression);
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}
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}
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