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# How do I generate points that match a histogram?

I am working on a simulation system. I will soon have experimental data (histograms) for the real-world distribution of values for several simulation inputs.

When the simulation runs, I would like to be able to produce random values that match the measured distribution. I'd prefer to do this without storing the original histograms. What are some good ways of

1. Mapping a histogram to a set of parameters representing the distribution?
2. Generating values that based on those parameters at runtime?

EDIT: The input data are event durations for several different types of events. I expect that different types will have different distribution functions.

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I've just read the question again, and I'm afraid I answered the title, but not the text. The text seems to ask how to guess a closed form representation for a given histogram. Different problem. – dmckee Jan 8 '09 at 2:58
I think you answered part 2, which is my end goal. Numeric integration seems like it could work for me. Part 1 comes from my desire to completely describe each event's characteristics in a simple config file. – AShelly Jan 8 '09 at 6:07

At least two options:

1. Integrate the histogram and invert numerically.
2. Rejection

## Numeric integration

From Computation in Modern Physics by William R. Gibbs:

One can always numerically integrate [the function] and invert the [cdf] but this is often not very satisfactory especially if the pdf is changing rapidly.

You literally build up a table that translates the range [0-1) into appropriate ranges in the target distribution. Then throw your usual (high quality) PRNG and translate with the table. It is cumbersome, but clear, workable, and completely general.

## Rejection:

Normalize the target histogram, then

1. Throw the dice to choose a position (x) along the range randomly.
2. Throw again, and select this point if the new random number is less than the normalized histogram in this bin. Otherwise goto (1).

Again, simple minded but clear and working. It can be slow for distribution with a lot of very low probability (peaks with long tails).

With both of these methods, you can approximate the data with piecewise polynomial fits or splines to generate a smooth curve if a step-function histogram is not desired---but leave that for later as it may be premature optimization.

Better methods may exist for special cases.

All of this is pretty standard and should appear in any Numeric Analysis textbook if I more detail is needed.

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I think I'm going to try the first method. I'll probably store the inverse CDF as a lookup table for interpolation. That should be easy to generate from the input data. – AShelly Jan 8 '09 at 18:20

More information about the problem would be useful. For example, what sort of values are the histograms over? Are they categorical (e.g., colours, letters) or continuous (e.g., heights, time)?

If the histograms are over categorical data I think it may be difficult to parameterise the distributions unless there are many correlations between categories.

If the histograms are over continuous data you might try to fit the distribution using mixtures of Gaussians. That is, try to fit the histogram using a $\sum_{i=1}^n w_i N(m_i,v_i)$ where m_i and v_i are the mean and variance. Then, when you want to generate data you first sample an i from 1..n with probability proportional to the weights w_i and then sample an x ~ n(m_i,v_i) as you would from any Gaussian.

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Rejection will work with catagorical data, though I'm having trouble visualizing the problem that would call for it. Multiple Gaussians are good for some kinds of data, but you may also have non-Gaussian backgrounds... +1 – dmckee Jan 8 '09 at 3:16
The input data are event durations, so it's continuous. I expect that the distributions will have some fairly simple forms, but I don't know yet if they are uniform, gaussian, bimodal, or what. I suspect there will be some of each. – AShelly Jan 8 '09 at 5:57
Fortunately, mixtures of Gaussians tend to be pretty flexible. The more you mix the larger the variety of distributions you can model. They have the advantage of being a well-defined and meaningful way of modelling distributions while other approaches, such as spline-fitting, have dubious semantics. – Mark Reid Jan 8 '09 at 6:08

So it seems that what I want in order to generate a given probablity distribution is a Quantile Function, which is the inverse of the cumulative distribution function, as @dmckee says.

The question becomes: What is the best way to generate and store a quantile function describing a given continuous histogram? I have a feeling the answer will depend greatly on the shape of the input - if it follows any kind of pattern there should be simplifications over the most general case. I'll update here as I go.

Edit:

I had a conversation this week that reminded me of this problem. If I forgo describing the histogram as an equation, and just store the table, can I do selections in O(1) time? It turns out you can, without any loss of precision, at the cost of O(N lgN) construction time.

Create an array of N items. A uniform random selection into the array will find an item with probablilty 1/N. For each item, store the fraction of hits for which this item should actually be selected, and the index of another item which will be selected if this one is not.

Weighted Random Sampling, C implementation:

//data structure
typedef struct wrs_data {
double share;
int pair;
int idx;
} wrs_t;

//sort helper
int wrs_sharecmp(const void* a, const void* b) {
double delta = ((wrs_t*)a)->share - ((wrs_t*)b)->share;
return (delta<0) ? -1 : (delta>0);
}

//Initialize the data structure
wrs_t* wrs_create(int* weights, size_t N) {
wrs_t* data = malloc(sizeof(wrs_t));
double sum = 0;
int i;
for (i=0;i<N;i++) { sum+=weights[i]; }
for (i=0;i<N;i++) {
//what percent of the ideal distribution is in this bucket?
data[i].share = weights[i]/(sum/N);
data[i].pair = N;
data[i].idx = i;
}
//sort ascending by size
qsort(data,N, sizeof(wrs_t),wrs_sharecmp);

int j=N-1; //the biggest bucket
for (i=0;i<j;i++) {
int check = i;
double excess = 1.0 - data[check].share;
while (excess>0 && i<j) {
//If this bucket has less samples than a flat distribution,
//it will be hit more frequently than it should be.
//So send excess hits to a bucket which has too many samples.
data[check].pair=j;
// Account for the fact that the paired bucket will be hit more often,
data[j].share -= excess;
excess = 1.0 - data[j].share;
// If paired bucket now has excess hits, send to new largest bucket at j-1
if (excess >= 0) { check=j--;}
}
}
return data;
}

int wrs_pick(wrs_t* collection, size_t N)
//O(1) weighted random sampling (after preparing the collection).
//Randomly select a bucket, and a percentage.
//If the percentage is greater than that bucket's share of hits,
// use it's paired bucket.
{
int idx = rand_in_range(0,N);
double pct = rand_percent();
if (pct > collection[idx].share) { idx = collection[idx].pair; }
return collection[idx].idx;
}


Edit 2: After a little research, I found it's even possible to do the construction in O(N) time. With careful tracking, you don't need to sort the array to find the large and small bins. Updated implementation here

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I know it i not what you wanted to hear, but unless you have some fundamental reason to select a functional form, you're probably best off storing a table of some kind. – dmckee Jan 8 '09 at 18:26
proof: ideone.com/i6CBZg – AShelly Apr 17 '15 at 23:03

If you need to pull a large number of samples with a weighted distribution of discrete points, then look at an answer to a similar question.

However, if you need to approximate some continuous random function using a histogram, then your best bet is probably dmckee's numeric integration answer. Alternatively, you can use the aliasing, and store the point to the left, and pick a uniform number between the two points.

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To choose from a histogram (original or reduced), Walker's alias method is fast and simple.

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