My question addresses both mathematical and CS issues, but since I need a performant implementation I am posting it here.
I have an estimated normal bivariate distribution, defined as a python matrix, but then I will need to transpose the same computation in Java. (dummy values here)
mean = numpy.matrix([,]) cov = numpy.matrix([[1,0],[0,1]])
When I receive in inupt a column vector of integers values (x,y) I want to compute the probability of that given tuple.
value = numpy.matrix([,]) probability_of_value_given_the_distribution = ???
Now, from a matematical point of view, this would be the integral for
3.5 < x < 4.5 and
2.5 < y < 3.5 over the probability density function of my normal.
What I want to know:
Is there a way to avoid the effective implementation of this, that implies dealing with expressions defined over matrices and with double integrals? Besides that it will take me a while if I had to implement it by myself, this would be computationally expensive. An approximate solution would be perfectly fine for me.
In an univariate normal, one could simply use the cumulative distribution function (or even store its values for the standard one and then normalize), but unfortunately there appears not to be a closed cdf form for multivariates.
Another approach for univariate is to use the inverse of bivariate approximation (so, approximate a normal as a binomial), but extending this to the multivariate I can't figure out how to keep in count the covariances.
I really hope someone has already implemented this, I need it soon (finishing my thesis) and I couldn't find anything.