# Introduction

Consider the following two arrays:

``````N = 100;  % for example

x(1:N) = [real values in ascending order];
y(1:N) = foo(x);
``````

I want to compute the integral of `y` with respect to `x`.

Let's assume that `y` is not in general defined via a function of `x` (e.g. `foo`). If that were the case, it would be simple to use `quad`, which would make a number of function calls to `foo`. I explicitly want to avoid function-based quadrature because in my situation, I have only `x` and `y`, and there is no handy function (like `foo`) to evaluate.

Note that I would also assume that `foo` is a well-behaved function: continuous and differentiable throughout the domain `[min(x), max(x)]`. Examples of `foo(x)` include `sin(x)`, `exp(x)`, `sqrt` (if `min(x)>0`), `x^2`, and so on. Of course, these example functions may be easily integrated analytically, but we don't learn anything from that. :-)

## Lower Accuracy Solution via `trapz`

I can perform array-based quadrature via the trapezoid method via `trapz`:

``````result = trapz( x, y );
``````

## Question

I know that there are a number of ways to approximate this integral with higher accuracy than the `trapz` approach, such as using Simpson's Rule. Another way might be to integrate the interpolating Legendre polynomial or spline. I imagine there are other clever ways, as well.

What is a better way to approximate this integral using MATLAB besides `trapz`, and how does it compare with `trapz` in terms of typical accuracy/performance?

Note: Since at least R2014b, `quad` was marked for deprecation in favor of `integral`. It may be helpful to others to specify the version of MATLAB for which an answer works.

• Not sure your exact question can be answered. I'd say that it's overly broad. This will largely depend on the smoothness and density of your discrete data. Just like with ODE integration, there is no single best quadrature or interpolation scheme. In most cases, `integral` with `interp1` will work fine. – horchler Mar 21 '17 at 22:33
• @horchler: Agreed. I meant to address this by asking for typical accuracy/performance. I assumed a comparison would be something like "1st order accurate, assuming a well-behaved function and a uniform grid" — even though the grid is not necessarily uniform and the function is not necessarily well-behaved. This serves as a baseline for comparing different methods. While there isn't a single best scheme for every situation, there are schemes that perform better than others in terms of accuracy (e.g. Runge-Kutta) or speed (Euler method). This comparison is a major part of why I asked. – jvriesem Mar 21 '17 at 22:38
• The problem with that is that you're veering into mathematics or computational science rather than programming and risk being off-topic for this site. It would be better if you provided specific examples of a "well-behaved function and a uniform grid". – horchler Mar 21 '17 at 22:42
• @horchler: I agree about it being better for those sites. (My bad!) I had asked it because this site has the `matlab` tag. Is there an easy, automated way to move this question to one of those sites? – jvriesem Mar 22 '17 at 16:09
• Perhaps this works: stackoverflow.com/questions/25974427/…. If so, however, I'm not sure about how it compares to other methods. – jvriesem Mar 22 '17 at 16:12