Write a program to estimate the value of the percolation threshold via Monte Carlo simulation.

Install a Java programming environment. Install a Java programming environment on your computer. We recommend (but do not require) these step-by-step instructions for Mac OS X, Windows, or Linux. As of Fall 2024 there is a new version of IntelliJ, if you have a previous version installed we recommend you still follow these steps to install the new version.

If you followed our instructions, the commands javac-algs4 and java-algs4 will classpath in algs4.jar, which contains Java classes for I/O and all of the algorithms in the textbook.

Percolation. Given a composite systems comprised of randomly distributed insulating and metallic materials: what fraction of the materials need to be metallic so that the composite system is an electrical conductor? Given a porous landscape with water on the surface (or oil below), under what conditions will the water be able to drain through to the bottom (or the oil to gush through to the surface)? Scientists have defined an abstract process known as percolation to model such situations.

The model. We model a percolation system using an n-by-n grid of sites. Each site is either open or blocked. A full site is an open site that can be connected to an open site in the top row via a chain of neighboring (left, right, up, down) open sites. We say the system percolates if there is a full site in the bottom row. In other words, a system percolates if we fill all open sites connected to the top row and that process fills some open site on the bottom row. (For the insulating/metallic materials example, the open sites correspond to metallic materials, so that a system that percolates has a metallic path from top to bottom, with full sites conducting. For the porous substance example, the open sites correspond to empty space through which water might flow, so that a system that percolates lets water fill open sites, flowing from top to bottom.)

percolates           does not percolate

The problem. In a famous scientific problem, researchers are interested in the following question: if sites are independently set to be open with probability p (and, therefore, blocked with probability 1 − p), what is the probability that the system percolates? When p equals 0, the system does not percolate; when p equals 1, the system percolates. The plots below show the site vacancy probability p versus the percolation probability for random 20-by-20 grids (left) and 100-by-100 grids (right).

Percolation threshold for 20-by-20 grid                Percolation threshold for 100-by-100 grid          

When n is sufficiently large, there is a threshold value p* such that when p < p* a random n-by-n grid almost never percolates, and when p > p*, a random n-by-n grid almost always percolates. No mathematical solution for determining the percolation threshold p* has yet been derived. Your task is to write a computer program to estimate p*.

Percolation data type. To model a percolation system, create a data type Percolation with the following API:

public class Percolation {

    // creates n-by-n grid, with all sites initially blocked
    public Percolation(int n)

    // opens the site (row, col) if it is not open already
    public void open(int row, int col)

    // is the site (row, col) open?
    public boolean isOpen(int row, int col)

    // is the site (row, col) full?
    public boolean isFull(int row, int col)

    // returns the number of open sites
    public int numberOfOpenSites()

    // does the system percolate?
    public boolean percolates()

    // unit testing (required)
    public static void main(String[] args)

}

Corner cases.  By convention, the row and column indices are integers between 0 and n − 1, where (0, 0) is the upper-left site.

Unit testing.  Your main() method must call each public constructor and method directly and help verify that they work as prescribed (e.g., by printing results to standard output).

Performance requirements.  The constructor must take \(\Theta(n^2)\) time; all instance methods must take \(\Theta(1)\) time plus \(\Theta(1)\) calls to union() and find().

Monte Carlo simulation. To estimate the percolation threshold, consider the following computational experiment:

For example, if sites are opened in a 20-by-20 grid according to the snapshots below, then our estimate of the percolation threshold is 204/400 = 0.51 because the system percolates when the 204th site is opened.

      Percolation 50 sites
50 open sites
Percolation 100 sites
100 open sites
Percolation 150 sites
150 open sites
Percolation 204 sites
204 open sites

By repeating this computation experiment T times and averaging the results, we obtain a more accurate estimate of the percolation threshold. Let xt be the fraction of open sites in computational experiment t. The sample mean \(\overline x\) provides an estimate of the percolation threshold; the sample standard deviation s measures the sharpness of the threshold.

\[ \overline x = \frac{x_1 \, + \, x_2 \, + \, \cdots \, + \, x_{T}}{T}, \quad s^2 = \frac{(x_1 - \overline x )^2 \, + \, (x_2 - \overline x )^2 \,+\, \cdots \,+\, (x_{T} - \overline x )^2}{T-1} \]
Assuming T is sufficiently large (say, at least 30), the following provides a 95% confidence interval for the percolation threshold:

\[ \left [ \overline x - \frac {1.96 s}{\sqrt{T}}, \;\; \overline x + \frac {1.96 s}{\sqrt{T}} \right] \]

To perform a series of computational experiments, create a data type PercolationStats with the following API:

public class PercolationStats {

    // perform independent trials on an n-by-n grid
    public PercolationStats(int n, int trials)

    // sample mean of percolation threshold
    public double mean()

    // sample standard deviation of percolation threshold
    public double stddev()

    // low endpoint of 95% confidence interval
    public double confidenceLow()

    // high endpoint of 95% confidence interval
    public double confidenceHigh()

   // test client (see below)
   public static void main(String[] args)

}

The constructor takes two arguments n and T, and perform T independent computational experiments (discussed above) on an n-by-n grid. Using this experimental data, it calculates the mean, standard deviation, and the 95% confidence interval for the percolation threshold.

Standard libraries.  Use StdRandom to generate random numbers; use StdStats to compute the sample mean and standard deviation; use Stopwatch to measure the running time.

Corner cases.  Throw an IllegalArgumentException in the constructor if either n ≤ 0 or T ≤ 0.

Test client.  The test client takes two command-line arguments n and T and prints the relevant statistics for T computational experiments on an n-by-n grid.

~/Desktop/percolation> java-algs4 PercolationStats 200 100
mean()           = 0.592993
stddev()         = 0.008770
confidenceLow()  = 0.591275
confidenceHigh() = 0.594712
elapsed time     = 0.373

~/Desktop/percolation> java-algs4 PercolationStats 200 100
mean()           = 0.592877
stddev()         = 0.009991
confidenceLow()  = 0.590919
confidenceHigh() = 0.594835
elapsed time     = 0.364

~/Desktop/percolation> java-algs4 PercolationStats 2 100000
mean()           = 0.666948
stddev()         = 0.117752
confidenceLow()  = 0.666218
confidenceHigh() = 0.667677
elapsed time     = 0.087

Comparison of two data structures. Implement Percolation using the quick-find algorithm, then using the weighted quick-union algorithm. Compare the performance of the two algorithms.

Project files. The file percolation.zip contains a test client and sample input files.

Submission. Submit only Percolation.java (using the weighted quick-union algorithm from WeightedQuickUnionUF) and PercolationStats.java. We will supply algs4.jar. Do not call any library functions except those in StdIn, StdOut, StdRandom, StdStats, Stopwatch, WeightedQuickUnionUF, and java.lang. Finally, submit readme.txt and acknowledgments.txt files and answer the questions.

Grading.

file points
Percolation.java 22
PercolationStats.java12
readme.txt 6
40

Reminder: You can lose up to 4 points for inadequate unit testing.

Extra credit: You can earn 1 point of extra credit for handling backwash in a time-efficient manner, and 2 additional points of extra credit for doing so using only \(\sim n^2\) additional memory beyond that of the base solution.


This assignment was developed by Bob Sedgewick and Kevin Wayne.
Copyright © 2008.