# Problem

I have computed a probability density function that depends on two variables. I want to use this multivariate distribution to generate some random numbers that occur with a probability proportional to the PDF.

As it seems, SciPy currently only supports univariate distributions. Are there any simple methods or easy-to-use packages that allow 2d-distributions?

As a workaround, I might try creating random numbers on the domain of interest and throwing them away or keeping them with a chance related to my PDF, but still there might be other options. The random number generation does not have to be fast.

# Here's a possible solution

Based on the answers (thanks a lot!), I hacked in some code the you may find in this gist. If you run this example with a sin^2*Gauss PDF, 2000 random random variates that fulfil a given condition (be inside a circle) will be plotted over the PDF. Maybe that's helpful for others, too.

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possibly i don't understand correctly. Why can't you pass two random variables into your distribution: `F(random(),random())` –  fraxel Jun 18 '12 at 13:43
pymvpa.org –  orokusaki Jun 18 '12 at 14:02
@fraxel, this would give me the probability density at a random position in my domain, not a random number that has a a probability of occurrence given by the probability density function. Furthermore, my PDF is available on a discrete grid only (I might use interp2d()). –  AlexE Jun 18 '12 at 14:03

So you have a PDF `F(x,y)` and you want to generate the pairs of `x` and `y` distributed according to this PDF?
@Steve: He already has `f(x,y)` in a discrete grid (see 3rd comment to the question). Shouldn't `f(y|x)` simply correspond to row `x` in that matrix then? –  Junuxx Jun 18 '12 at 14:34
From the use of "density", along with the link in the post which discusses `rv_continuous`, I assumed X and Y were continuous random variables. From the third comment above, I interpret that as having discrete points of the continuous PDF. Yes, I suppose you could use those discrete points to approximate the true PDF, in which case, yes, just compute sums to get the marginals/conditionals. –  Steve Tjoa Jun 18 '12 at 16:23