# 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.

`integral`

with`interp1`

will work fine. – horchler Mar 21 '17 at 22:33typicalaccuracy/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`matlab`

tag. Is there an easy, automated way to move this question to one of those sites? – jvriesem Mar 22 '17 at 16:09