# Numerical integration over non-uniform grid in matlab. Is there any function?

I've got function values in a vector `f` and also the vector containing values of the argument `x`. I need to find the define integral value of `f`. But the argument vector `x` is not uniform. Is there any function in Matlab that deals with integration over non-uniform grids?

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Taken from help :

Z = trapz(X,Y) computes the integral of Y with respect to X using the trapezoidal method. X and Y must be vectors of the same length, or X must be a column vector and Y an array whose first non-singleton dimension is length(X). trapz operates along this dimension.

As you can see `x` does not have to be uniform.

For instance:

``````x = sort(rand(100,1)); %# Create random values of x in [0,1]
y = x;
trapz( x, y)
``````

Returns:

``````ans =

0.4990
``````

Another example:

``````x = sort(rand(100,1)); %# Create random values of x in [0,1]
y = x.^2;
trapz( x, y)
``````

returns:

``````ans =

0.3030
``````
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Thank you, Andrey. I think that suits to me. – jacksonslsmg4 Nov 15 '12 at 11:34

Depending on your function (and how `x` is distributed), you might get more accuracy by doing a `spline` interpolation through your data first:

``````pp  = spline(x,y);
``````

That's the quick-n-dirty way. Ther is a faster and more direct approach, but that is fugly and much less transparent:

``````result = sum(sum(...
bsxfun(@times, pp.coefs, 1./(4:-1:1)) .*...  % coefficients of primitive
bsxfun(@power, diff(pp.breaks).', 4:-1:1)... % all 4 powers of shifted x-values
));
``````

As an example why all this could be useful, I borrow the example from here. The exact answer should be

``````>> pi/2/sqrt(2)*(17-40^(3/4))
ans =
1.215778726893561e+00
``````

Defining

``````>> x = [0 sort(3*rand(1,5)) 3];
>> y = (x.^3.*(3-x)).^(1/4)./(5-x);
``````

we find

``````>> trapz(x,y)
ans =
1.142392438652055e+00

>> pp  = spline(x,y);
>> tic; quadgk(@(t) ppval(pp,t), 0, 3), toc
ans =
1.213866446458034e+00
Elapsed time is 0.017472 seconds.

>> tic; result = sum(sum(...
bsxfun(@times, pp.coefs, 1./(4:-1:1)) .*...  % coefficients of primitive
bsxfun(@power, diff(pp.breaks).', 4:-1:1)... % all 4 powers of shifted x-values
)), toc
result =
1.213866467945575e+00
Elapsed time is 0.002887 seconds.
``````

So `trapz` underestimates the value by more than `0.07`. With the latter two methods, the error is an order of magnitude less. Also, the less-readable version of the `spline` approach is an order of magnitude faster.

So, armed with this knowledge: choose wisely :)

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Check out Simpsons rule - that is a way to integrate the spline of the signal in one shot. – Andrey Rubshtein Nov 15 '12 at 14:37
@Andrey: Hmmm...Simpson's rule is based on the quadratic approximation to `f(x)`, where the approximating polynomial equals `f(x)` at the end-points and midpoint...AFAIK, splines are cubic approximations, so how does that work? – Rody Oldenhuis Nov 15 '12 at 14:49
@Andrey: Gauss-Kronrod applies nicely because it also uses a cubic approximation on each interval. I was thinking more in terms of using the info in `pp.breaks` and pp.coefs` in "some smart way" :) – Rody Oldenhuis Nov 15 '12 at 14:50
I think there is a formula that does it for any degree of polynomial. Don't remember it though. Simpsons rule is a private case for N = 2. Do you mean how to select better X values? – Andrey Rubshtein Nov 15 '12 at 15:15
@Andrey: See my edit. – Rody Oldenhuis Nov 15 '12 at 15:23

You can do Gaussian quadrature over each piecewise pair of `x` and sum them up to get the complete integral.

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Gaussian quadrature is not meaningful for a fixed set of points, when you cannot choose the point locations. If you mean to do Gaussian quadrature on an interpolated Lagrange polynomial, then this is no better than a simple direct rule. – user85109 Nov 15 '12 at 15:24
I don't think that's correct. This is routinely done in any finite element code - piecewise integration over non-uniform grids. That's what I'm thinking of. – duffymo Nov 15 '12 at 15:38
WRONG. Yes, finite element codes use a Gaussian integration, to solve a DIFFERENT problem. HOWEVER, given only a list of points sampling a function in one dimension, it is meaningless to do a Gaussian integration. It seems you misunderstand the difference. There is one. A Gaussian integration in 1-d given only that list of points reduces to trapezoidal rule. (All you can meaningfully do is use a midpoint rule for each interval, using a linear interpolation to impute a value, thus trapezoidal rule falls out.) – user85109 Nov 15 '12 at 22:11
If you would use a higher order rule, integrating higher order Lagrange segments, then you might as well integrate a spline, rather than integrating a set of non-differentiable segments. Again, a Gaussian rule is of no value. – user85109 Nov 15 '12 at 22:14
"@Andrey basically this is Gaussian quadrature with a non-uniform gridm; it is inherently more accurate than the trapezoidal rule.. Not for all functions though, that's true, but most anyway." - no value when I write it, inherently more accurate in your comment. Which is it? – duffymo Nov 16 '12 at 12:14