Integrating bivariate normal distribution in polar coordinates efficiently
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Hi there,
I have a bivariate normal distribution which I would like to integrate over a specified area in polar coordinates. I have the distribution either as mvnpdf() or as a 2D matrix of values. I do not have it as an equation/expression, though I could cast it into one. What is the fastest way to integrate over this distribution in polar coordinates? I can see that I can evaluate double integrals in polar coordinates using integral2 (https://www.mathworks.com/help/matlab/ref/integral2.html) but I will first have to express my pdf as an equation in polar coordinates. I am concerned about speed/efficiency as I have to do this over and over again as part of a simulation. Thanks in advance!
2 comentarios
Torsten
el 3 de Jul. de 2018
See the example "Multiple Numerical Integrations" under
https://de.mathworks.com/help/matlab/ref/trapz.html
Best wishes
Torsten.
Respuestas (1)
John D'Errico
el 3 de Jul. de 2018
Editada: John D'Errico
el 3 de Jul. de 2018
Why do you need to re-express the PDF in polar form? It is one line of code to convert polar form into cartesian form to do the integration in the form you desire, thus in polar coordinates.
Integral2 will send points into your kernel function to evaluate the integrand. They will be in polar form. So what? In one line of code, convert them into cartesian coordinates.
help pol2cart
Send them into the multivariate normal PDF. This costs almost nothing in terms of time, as far more of the time will be taken by the PDF evaluation and by integral2 itself.
Don't trust me? Seriously, this takes NO effort at all to do. For example, what is the integral of a bivariate normal PDF within a unit circle of radius 1?
function K = polarkernel(r,theta)
% convert to cartesian coords
[x,y] = pol2cart(theta,r);
Prtheta = reshape(mvnpdf([x(:),y(:)]),size(r));
% don't forget to multiply by r, because the
% differential term when you work in polar
% coordinates converts from dx*dy, into r*dr*dtheta.
K = Prtheta.*r;
end
Now, call integral2.
integral2(@polarkernel,0,1,0,2*pi)
ans =
0.393469340287005
Now, is this the correct result? To verify that fact, lets do the conversion ourselves. Ok, I'll do it myself.
A standard bivariate normal distribution, with unit variances, and zero correlation & covariances is simple, even trivial to write:
P(x,y) = exp(-(x^2 + y^2)/2)/(2*pi)
In polar form? In this case, it is even simpler! This is because it is rotationally symmetric. And in polar form, (x^2+y^2) reduces to just r^2.
P(r,theta) = exp(-r^2/2)/(2*pi)
Even easier, is then to recognize the integrand itself is not dependent on theta. That is ONLY true in this specific case, because I chose a trivial case to do my test. If you have some non-trivial normal pdf, with non-zero correlation, you will still need to convert to cartesian coordinates as I showed. But this is a test to see if what I did worked!
The integral of P(r,theta)*r is simple here, because for a rotationaly symmetric kernel, the integral on theta becomes merely a multiplication by 2*pi. So the 1/(2*pi) just cancels out, goes away like dust on the wind.
I'll do it symbolically. Actually, I could do this part with paper and pencil. But then, you would need to trust my algebraic capabilities.
syms r
int(exp(-r^2/2)*r,[0,1])
ans =
1 - exp(-1/2)
vpa(ans)
ans =
0.39346934028736657639620046500882
Which, to within the default tolerances of integral2, is as close as it will get. Well, at least good enough for government work.
4 comentarios
John D'Errico
el 3 de Jul. de 2018
No. You simply have not understood anything I said. I'm not trying to be rude. Merely to explain to you that you are spending a lot of effort to optimize something that is almost certainly not worth the effort.
You stated that you want to integrate in polar coordinates. That means integral2 will be working on r and theta. You give it limits of integration on those parameters to define the domain. It will feed your kernel r and theta values in the domain of interest.
Then you need to convert r and theta into cartesian coordinates, because the multivariate Normal PDF is defined in that domain. Even if you have someother function that uses r and theta, multiplied by the multivariate normal PDF, you need x and y.
(Note: IF the bivariate normal PDF in question has a diagonal covariance matrix, then the conversion to polar form is actually quite simple. In fact, I did that for you in my answer. So IF the bivariate normal has a diagonal covariance matrix, with both variances identical, then you can indeed avoid the conversion into cartesian coordinates.) You have said nothing about the specific bivariate PDF at all, so I cannot know.
Is the conversion a complicated thing to do? Not even close. Nor is it even remotely expensive to compute.
For example, a typical call to integral2 will probably require something on the order of 1000 points to evaluate, to rarely as many as 10000 points, depending upon the integration tolerances, and the complexity of your function. How nonlinear is it? 10K is pretty high in my experience with that code on any average function. For an average case, I'll assume 3000 function evaluations. So lets guess 3000 conversions to cartesian coordinates for EACH time you call integral2.
How long does that take to do? Again, 3k conversions is FAST. For example, I'll do 30 million such conversions for a test, equivalent to calling integral2 10000 times.
r = rand(1,3e7);
th = rand(1,3e7)*2*pi;
timeit(@() pol2cart(th,r))
ans =
0.5896013544015
So roughly 0.6 seconds for 30 million such operations. I could just divide by 10000 to infer the time for 3000 points. Or just use timeit again.
r = rand(1,3000);
th = rand(1,3000)*2*pi;
timeit(@() pol2cart(th,r))
ans =
7.20480022142857e-05
Really short times like this are difficult to estimate exactly, which is why I did it for 30 million sets of r and theta the first time. But the point is, are there places in your code where you are wasting 0.00007 seconds of CPU time? I'll guarantee that there are dozens of places where your code is wasting 0.00007 seconds, many thousands of times. But even there, we might still be talking about a few seconds of CPU time wasted in total. And when we are talking about code written by a relatively new programmer in MATLAB, this is certainly small potatoes.
And that is my point. Don't spend time trying to pre-optimize your code. Don't waste your time trying to save such a small amount of time. This is a classic mistake that people make, and you are falling into that trap.
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