# inverse of a cdf

I would like to compute the inverse cumulative density function (inverse cdf) of a given pdf. The pdf is directly given as a histogram, ie., a vector of N equally spaced components.

My current approach is to do :

cdf = cumsum(pdf);
K = 3;   %// some upsampling factor
maxVal = 1;   %// just for my own usage - a scaling factor
M = length(cdf);
N = M*K;   %// increase resolution for higher accuracy
y = zeros(N, 1);
cursor = 2;
for i=1:N
desiredF = (i-1)/(N-1)*maxVal;
while (cursor<M && cdf(cursor)<desiredF)
cursor = cursor+1;
end;

if (cdf(cursor)==cdf(cursor-1))
y(i) = cursor-1;
else
alpha = min(1, max(0,(desiredF - cdf(cursor-1))/(cdf(cursor)-cdf(cursor-1))));
y(i) = ((cursor-1)*(1-alpha) + alpha*cursor )/maxVal;
end;

end;

y = resample(y, 1, K, 0);


which means that I upsample with linear interpolation, inverse and downsample my histogram. This is rather an ugly code, is not very robust (if I change the upsampling factor, I can get really different results), and is uselessly slow... could anyone suggest a better approach ?

Note : the generalized inverse I am trying to compute (in the case the cdf is not invertible) is :

F^{-1}(t) = \inf{x \in R ; F(x)>t }


with F the cumulative density function

[EDIT : actually, K = 1 (ie., no upsampling) seems to give more accurate results...]

Thanks!

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If your input is specified in the form of a non-normalized histogram, then simply using the built-in quantile() function automatically computes the data point for a specified quantile, which is what the inverse-CDF does. If the histogram is normalized by the number of data points (making it a probability vector), then just multiply it by the number of data points first. See here for the quantile() details. Basically, you'll assume that given your histogram/data, the first parameter is fixed, which turns quantiles() into a function only of the specified probability values p. You could easily write a wrapper function to make it more convenient if necessary. This removes the need to explicitly compute the CDF with cumsum().

If we assume the histogram, bins, and number of data points are h, b, and N, respectively, then:

 h1 = N*h; %// Only if histogram frequencies have been normalized.
data = [];
for kk = 1:length(h1)
data = [data repmat(b(kk), 1, h1(kk))];
end

%// Set p to the probability you want the inv-cdf for...
p = 0.5;
inv_cdf = quantiles(data,p)


For solutions that must leverage the existing PDF vector, we can do the following. Assume that x_old and pdf_old are the histogram bins and histogram frequencies, respectively.

 p = 0.5; %// the inv-cdf probability that I want
num_points_i_want = 100; %// the number of points I want in my histogram vector

x_new = linspace(min(x_old),max(x_old),num_points_i_want);
pdf_new = interp1(x_old,pdf_old,x_new);
cdf_new = cumsum(pdf_new);
inv_cdf = min(x_new(cdf_new >= p));


Alternatively, we could create the cumsum() CDF first and use interp1() on that if it's not desirable to interpolate first.

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as I understood, the quantile function doesn't work on histograms but rather on samples drawn for a given histogram... isn't it ? –  WhitAngl Feb 8 '12 at 1:24
A histogram is a set of frequencies f and a set of bins b. If you repeat each bin value b(i) for f(i) number of repetitions, then you've got yourself a synthetic data set that has the exact same empirical distribution as your original, up to binning errors which would affect both the synthetic set and the histogram identically. –  EMS Feb 8 '12 at 1:34
Indeed, thanks. But since f(i) are real numbers, everything needs to be normalized to some big factor. At the end, this means generating N samples from the histogram (with N possibly very large), and finding the percentiles. Although definitely shorter to write, I am not sure this is much much better in terms of complexity –  WhitAngl Feb 8 '12 at 2:01
I am also not sure this is very precise since we cannot have the linear interpolation between the bins of the histogram. A better approach (in term of precision) would be to really generate N samples from the pdf... which would mean sampling the pdf using the inverse cdf formula which is a chicken and egg problem! ;) (or sampling it with a rejection method, which would handle the linear interpolation in the histogram, but which would add yet another level of complexity) –  WhitAngl Feb 8 '12 at 2:09
f(i) won't be real numbers if you just use the regular output of Matlab's hist() function -- they'll only become floating point representations if you normalize that vector to make it a probability vector. Additionally, the quantiles() and repmat() functions are pretty efficient. –  EMS Feb 8 '12 at 2:13

Ok, I think I found a much shorter version, which works at least as fast and as accurately :

cdf = cumsum(pdf);
M = length(cdf);
xx = linspace(0,1,M);
invcdf = interp1(cdf,xx,xx)


[EDIT : No this is actually still two to three times slower than the initial code... don't ask me why! And it does not handle non strictly monotonous functions : this produces the error : "The values of X should be distinct"]

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Also, is there a typo in the arguments to interp1()? It looks like you're using the exact same grid. –  EMS Feb 9 '12 at 0:39
no typo : the goal is to replace the function (x, f(x)), by (f(x), x) sampled at x... hence the redundancy. –  WhitAngl Feb 9 '12 at 4:11
I copied and pasted this code as it, and it works when the cdf is invertible, albeit more slowly. –  WhitAngl Feb 9 '12 at 4:17
I'm still not following. I didn't mean to imply it would fail to work; I just don't understand how invcdf can be different from xx in the code. You're basically asking it to interpolate a vector into itself. xx already represents the 'independent variable' values at each point in cdf, how does the interpolation change anything? –  EMS Feb 9 '12 at 4:22
The thing is to realize that in terms of graph, the inverse of the function whose graph is plot(x,y) is the function whose graph is plot(y,x). So this is just a matter of resampling the data "x" which were originally sampled at f^-1(y) to the new samples "x". One of the "x" represents the value of the function to be interpolated while the other "x" represents the positions where we want the interpolation... The syntax for interp1 is interp1(x,Y,xi) where xi are the new sample points. –  WhitAngl Feb 9 '12 at 14:57