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I have a function z = f(x, y), where z is the value at point (x, y). How may I integrate z over the x-y plane in MATLAB?

By function above, I actually mean I have something similar to a hash table. That is, given a (x, y) pair, I can look up the table to find the corresponding z value.

The problem would be rather simple, if the points were uniformly distributed over x-y plane, in which case I can simply sum up all the z values, multiply it with the bottom area, and finally divide it by the number of points I have. However, the distribution is not uniform as shown below. So I am actually asking for the computation method that minimises the error.

enter image description here

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  • So do you know all the x-y values over which the function is defined?
    – shimizu
    May 15, 2014 at 21:35
  • @shimizu Yes. Basically, for each pair of x and y, I have a corresponding z. I know all of them. The plot above is the scatter plot of (x, y). May 15, 2014 at 21:37
  • Then is your problem essentially 2d integration over a non-uniform set of x and y?
    – shimizu
    May 15, 2014 at 21:39
  • @shimizu Yes, exactly. May 15, 2014 at 21:40

3 Answers 3

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The currently accepted answer will only work for gridded data. If your data is scattered you can use the following approach instead:

scatteredInterpolant + integral2:

f = scatteredInterpolant(x(:), y(:), z(:), 'linear');
int = integral2(@(x,y) f(x,y), xmin, xmax, ymin, ymax);

This defines the linear interpolant f of the data z(i) = f(x(i),y(i)) and uses it as an argument to integral2. Note that ymin and ymax, instead of doubles, can be function handles depending on x. So usually you will be integrating rectangles, but this could be used for integration regions a bit more complicated.

If your integration area is rather complicated or has holes, you should consider triangulating your data.

DIY using triangulation:

Let's say your integration area is given by the triangulation trep, which for example could be obtained by trep = delaunayTriangulation(x(:), y(:)). If you have your values z corresponding to z(i) = f(trep.Points(i,1), trep.Points(i,2)), you can use the following integration routine. It computes the exact integral of the linear interpolant. This is done by evaluating the areas of all the triangles and then using these areas as weights for the midpoint(mean)-value on each triangle.

function int = integrateTriangulation(trep, z)
P = trep.Points; T = trep.ConnectivityList;
d21 = P(T(:,2),:)-P(T(:,1),:);
d31 = P(T(:,3),:)-P(T(:,1),:);
areas = abs(1/2*(d21(:,1).*d31(:,2)-d21(:,2).*d31(:,1)));
int = areas'*mean(z(T),2);
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  • appreciate the triangulation routine. very useful if you have a very non-uniform data set (such as a rectangular region with significant corner refinement). The methods that impose a regular rectangular mesh can become very inefficient and memory intensive if you force that refinement to propagate over the full mesh.
    – Nick J
    Oct 6, 2019 at 3:04
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If you have a discrete dataset for which you have all the x and y values over which z is defined, then just obtain the Zdata matrix corresponding to those (x,y) pairs. Save this matrix, and then you can make it a continuous function using interp2:

function z_interp = fun(x,y)

    z_interp = interp2(Xdata,Ydata,Zdata,x,y);

end

Then you can use integral2 to find the integral:

q = integral2(@fun,xmin,xmax,ymin,ymax)

where @fun is your function handle that takes in two inputs.

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  • problem is, I don't have a function. Instead, I have a series of discrete points. May 15, 2014 at 21:19
  • So do you have a list of x and y points at which z is defined? Are they evenly spaced?
    – shimizu
    May 15, 2014 at 21:25
  • Almost there, except that I am getting the Integrand output size does not match the input size. error. Maybe this is caused by the fact that my integrand output is a complex number? May 16, 2014 at 13:33
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I had to integrate a biavariate normal distribution recently in MatLab. The idea is very simple. Matlab defines a surface through a meshgrid, so from x, y you need to do this:

x = -10:0.05:10;
y = x;

[X,Y] = meshgrid(x',y');

...for example. Then, let's call FX the function that defines the value at each point of the surface. To calculate the integral you just need to do this:

surfint = zeros(length(X),1);
for a = 1:length(X)
   surfint(a,1) = trapz(x,FX(:,a));     
end

trapz(x, surfint)

For me, this is the simplest way.

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