# Java code/library to calculate the earth mover's distance

I'm looking for java code (or a library) that calculates the earth mover's distance (EMD) between two histograms. This could be directly or indirectly (e.g. using the Hungarian algorithm). I found several implementations of this in c/c++ (e.g. "Fast and Robust Earth Mover's Distances", but I'm wondering if there is a Java version readily available.

I will be using the EMD calculation to evaluate the approach given by this paper in the context of a science project I'm working on.

Update

Using a variety of resources I estimate that the code below should do the trick. determineMinCostAssignment is the calculation of the optimal assignment as determined by the Hungarian algorithm. For this I will be using the code from http://konstantinosnedas.com/dev/soft/munkres.htm My main concern is the calculated flow: I am not sure if this is correct. Is there someone who can verify that this is correct or not?

``````    /**
* Determines the Earth Mover's Distance between two histogram assuming an equal distance between two buckets of a histogram. The distance between
* two buckets is equal to the differences in the indexes of the buckets.
*
* @param threshold
*          The maximum distance to use between two buckets.
*/
public static double determineEarthMoversDistance(double[] histogram1, double[] histogram2, int threshold) {
if (histogram1.length != histogram2.length)
throw new InvalidParameterException("Each histogram must have the same number of elements");

double[][] groundDistances = new double[histogram1.length][histogram2.length];
for (int i = 0; i < histogram1.length; ++i) {
for (int j = 0; j < histogram2.length; ++j) {
int abs_diff = Math.abs(i - j);
groundDistances[i][j] = Math.min(abs_diff, threshold);
}
}

int[][] assignment = determineMinCostAssignment(groundDistances);
double costSum = 0, flowSum = 0;
for (int i = 0; i < assignment.length; i++) {
double cost = groundDistances[assignment[i][0]][assignment[i][1]];
double flow = histogram2[assignment[i][1]];
costSum += cost * flow;
flowSum += flow;
}
return costSum / flowSum;
}
``````
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Optimal transportation cost is obviously a linear problem with linear constraints. Any linear optimization library (interior point methods work well) will do (btw, what does the Hungarian algorithm do here ? You are not looking for integer solutions). Other keywords to search for are "Monge-Kantorovich distance", "Wasserstein distance", or "Optimal transportation". There are also algorithms based on convex optimization (where you directly find convex conjugate pairs phi, phi^* for the dual Kantorovich problem; best for continuous spaces). –  Alexandre C. Mar 30 '12 at 12:23

Here's a pure Java port of the FastEMD algorithm, that I just released: https://github.com/telmomenezes/JFastEMD

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Great! And just in time as well, since I was just preparing to distribute it to some other people to verify the results –  Erik Apr 15 '12 at 17:25

The website "Fast and Robust Earth Mover's Distances" has a Java wrapper for the C/C++ code with compiled binary for Linux and Windows.

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I know (I added the compiled binary for windows myself), but I'm still hoping that there is a full java version available somewhere. That would allow me to transfer the complete experiments code to others with a little less explanation. –  Erik Mar 16 '12 at 22:36

A simple Google search for hungarian algorithm java turned up several links, including this link and this one.

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I found those indeed, but it is not entirely clear to me what the input for the Hungarian algorithm should be. Obviously the number of rows and columns of the NxN matrix conform to the number of buckets in the histogram, but that doesn't explain the cell contents. Should that be the distance between the buckets (i.e. cell (1,3) should contain |1-3|=2)? –  Erik Jan 15 '12 at 21:39

https://github.com/wihoho/VideoRecognition

• Adapt the author's C implementation with python module through a file interface
• The modified C codes are under the folder EarthMoverDistance SourceCode

I am pretty sure that you can do the same thing with Java. Just add a file interface to connect the C implementation of EMD with your Java codes.

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