# Approximate median of an immutable array

I need to find a median value of an array of doubles (in Java) without modifying it (so selection is out) or allocating a lot of new memory. I also don't care to find the exact median, but within 10% is fine (so if median splits the sorted array 40%-60% it's fine).

How can I achieve this efficiently?

Taking into account suggestions from rfreak, ILMTitan and Peter I wrote this code:

``````public static double median(double[] array) {
final int smallArraySize = 5000;
final int bigArraySize = 100000;
if (array.length < smallArraySize + 2) { // small size, so can just sort
double[] arr = array.clone();
Arrays.sort(arr);
return arr[arr.length / 2];
} else if (array.length > bigArraySize) { // large size, don't want to make passes
double[] arr = new double[smallArraySize + 1];
int factor = array.length / arr.length;
for (int i = 0; i < arr.length; i++)
arr[i] = array[i * factor];
return median(arr);
} else { // average size, can sacrifice time for accuracy
final int buckets = 1000;
final double desiredPrecision = .005; // in percent
final int maxNumberOfPasses = 10;
int[] histogram = new int[buckets + 1];
int acceptableMin, acceptableMax;
double min, max, range, scale,
medianMin = -Double.MAX_VALUE, medianMax = Double.MAX_VALUE;
int sum, numbers, bin, neighborhood = (int) (array.length * 2 * desiredPrecision);
for (int r = 0; r < maxNumberOfPasses; r ++) { // enter search for number around median
max = -Double.MAX_VALUE; min = Double.MAX_VALUE;
numbers = 0;
for (int i = 0; i < array.length; i ++)
if (array[i] > medianMin && array[i] < medianMax) {
if (array[i] > max) max = array[i];
if (array[i] < min) min = array[i];
numbers ++;
}
if (min == max) return min;
if (numbers <= neighborhood) return (medianMin + medianMax) / 2;
acceptableMin = (int) (numbers * (50d - desiredPrecision) / 100);
acceptableMax = (int) (numbers * (50d + desiredPrecision) / 100);
range = max - min;
scale = range / buckets;
for (int i = 0; i < array.length; i ++)
histogram[(int) ((array[i] - min) / scale)] ++;
sum = 0;
for (bin = 0; bin <= buckets; bin ++) {
sum += histogram[bin];
if (sum > acceptableMin && sum < acceptableMax)
return ((.5d + bin) * scale) + min;
if (sum > acceptableMax) break; // one bin has too many values
}
medianMin = ((bin - 1) * scale) + min;
medianMax = (bin * scale) + min;
for (int i = 0; i < histogram.length; i ++)
histogram[i] = 0;
}
return .5d * medianMin + .5d * medianMax;
}
}
``````

Here I take into account the size of the array. If it's small, then just sort and get the true median. If it's very large, sample it and get the median of the samples, and otherwise iteratively bin the values and see if the median can be narrowed down to an acceptable range.

I don't have any problems with this code. If someone sees something wrong with it, please let me know.

Thank you.

-
How much time do you allow? In a milli-second you can get the median of 10,000 values. – Peter Lawrey Dec 29 '10 at 21:49
If you take the median of a selection of 1 in 30 values it appear to be within 5% of the actual median. It takes about 1/40th of the time. You could try something similar to see what works for your dataset. – Peter Lawrey Dec 29 '10 at 22:02
@Peter You mean exact median for 10000 values? How would you do that? – adamax Dec 29 '10 at 23:34
I think Peter offered a simpler solution that would work for medium and large arrays. Where it may not work (pathological cases, poor distribution), I don't think the more complicated algorithm I offered would give a better answer. Also, depending on the memory of the system you are working with, the copy/sort method may work for dataset sizes that surprise you. Allocating 8MB (1000*1000 double) and throwing it away almost immediately will be a blip in the GC lifecycle. – rfeak Dec 30 '10 at 6:27
@rfreak and @Peter I guess you're right. I could just do selection median finding on some new space since RAM is not REALLY an issue. – McTrafik Dec 30 '10 at 7:20

Assuming you mean median and not average. Also assuming you are working with fairly large double[], or memory wouldn't be an issue for sorting a copy and performing an exact median. ...

With minimal additional memory overhead you could probably run a O(n) algorithm that would get in the ballpark. I'd try this and see how accurate it is.

Two passes.

First pass find the min and max. Create a set of buckets that represent evenly spaced number ranges between the min and max. Make a second pass and "count" how many numbers fall in each bin. You should then be able to make a reasonable estimate of the median. Using 1000 buckets would only cost 4k if you use int[] to store the buckets. The math should be fast.

The only question is accuracy, and I think you should be able to tune the number of buckets to get in the error range for your data sets.

I'm sure someone with a better math/stats background than I could provide a precise size to get the error range you are looking for.

-
First, median != average and mean == average. Second, doing ANYTHING in 2 passes is not O(n) – Falmarri Dec 29 '10 at 22:37
Doh. Meant median. Will edit. 2n = O(n). Constant are dropped when determining O. – rfeak Dec 29 '10 at 22:46
@Falmarri: I suggest you read up on Big-O notation... Doing it in 10 passes would still be O(n) if it took the same number of passes for a million elements as for a hundred. – Michael Borgwardt Dec 29 '10 at 23:19
@zeuxcg - I agree. This may be incredibly inaccurate, but it depends on the data set. The question goes back to McTrafik. Are your datasets large and evenly distributed, or are they all over the map? If they are all over the place, then any algorithm that doesn't perform a sort may be too inaccurate. – rfeak Dec 29 '10 at 23:21
If you kept the running mean of each bucket as well, and returned the mean of the bucket that contained the median, that would solve zeuxcg's problem (though it may create others). Or, you could recur until your count was sufficiently small (but that would up the time O(n*m), where m is the number of needed recursions. – ILMTitan Dec 29 '10 at 23:49

Pick a small number of array elements at random, and find the median of those.

-

Following on from the OPs question about; how to extract N values from a much larger array.

The following code shows how long it takes to find the median of a large array and then shows how long it take to find the median of a fixed size selection of values. The fixed size selection has a fixed cost, but is increasingly inaccurate as the the size of the original array grows.

The following prints

``````Avg time 17345 us. median=0.5009231700563378
Avg time 24 us. median=0.5146687617507585
``````

the code

``````double[] nums = new double[100 * 1000 + 1];
for (int i = 0; i < nums.length; i++) nums[i] = Math.random();

{
int runs = 200;
double median = 0;
long start = System.nanoTime();
for (int r = 0; r < runs; r++) {
double[] arr = nums.clone();
Arrays.sort(arr);
median = arr[arr.length / 2];
}
long time = System.nanoTime() - start;
System.out.println("Avg time " + time / 1000 / runs + " us. median=" + median);
}
{
int runs = 20000;
double median = 0;
long start = System.nanoTime();
for (int r = 0; r < runs; r++) {
double[] arr = new double[301]; // fixed size to sample.
int factor = nums.length / arr.length; // take every nth value.
for (int i = 0; i < arr.length; i++)
arr[i] = nums[i * factor];
Arrays.sort(arr);
median = arr[arr.length / 2];
}
long time = System.nanoTime() - start;
System.out.println("Avg time " + time / 1000 / runs + " us. median=" + median);
}
``````

To meet your requirement of not creating objects, I would put the fixed size array in a ThreadLocal so there is no ongoing object creation. You adjust the size of the array to suit how fast you want the function to be.

-

1) How much is a lot of new memory? Does it preclude a sorted copy of the data, or of references to the data?

2) Is your data repetitive (are there many distinct values)? If yes, then your answer to (1) is less likely to cause problems, because you may be able to do something with a lookup map and an array: e.g. Map and an an array of short and a suitably tweaked comparison object.

3) The typical case for the your "close to the mean" approximation is more likely to be O(n.log(n)). Most sort algorithms only degrade to O(n^2) with pathological data. Additionally, the exact median is only going to be (typically) O(n.log(n)), assuming you can afford a sorted copy.

4) Random sampling (a-la dan04) is more likely to be accurate than choosing values near the mean, unless your distribution is well behaved. For example poisson distribution and log normal both have different medians to means.

-
Say I have an double[150000] for every image and an arbitrary number of images, so having a sorted copy is definitely not optimal. You are right about random sampling being better than the mean. I don't know what I was thinking. – McTrafik Dec 30 '10 at 4:53