Scipy does not provide such a high order integrator for tabulated data by default. The closest you have available without coding it yourself is `scipy.integrate.simps`

, which uses a 3 point Newton-Cotes method.

If you simply want to get comparable integration precision, you could split your `x`

and `f`

arrays into 5 point chunks and integrate them one at a time, using the weights returned by `scipy.integrate.newton_cotes`

doing something along the lines of:

```
def idl_tabulate(x, f, p=5) :
def newton_cotes(x, f) :
if x.shape[0] < 2 :
return 0
rn = (x.shape[0] - 1) * (x - x[0]) / (x[-1] - x[0])
weights = scipy.integrate.newton_cotes(rn)[0]
return (x[-1] - x[0]) / (x.shape[0] - 1) * np.dot(weights, f)
ret = 0
for idx in xrange(0, x.shape[0], p - 1) :
ret += newton_cotes(x[idx:idx + p], f[idx:idx + p])
return ret
```

This does 5-point Newton-Cotes on all intervals, except perhaps the last, where it will do a Newton-Cotes of the number of points remaining. Unfortunately, this will not give you the same results as `IDL_TABULATE`

because the internal methods are different:

Scipy calculates the weights for points not equally spaced using what seems like a least-sqaures fit, I don't fully understand what is going on, but the code is pure python, you can find it in your Scipy installation in file `scipy\integrate\quadrature.py`

.

`INT_TABULATED`

always performs 5-point Newton-Cotes on equispaced data. If the data are not equispaced, it builds an equispaced grid, using a cubic spline to interpolate the values at those points. You can check the code here.

For the example in the `INT_TABULATED`

docstring, which is suppossed to return `1.6271`

using the original code, and have an exact solution of `1.6405`

, the above function returns:

```
>>> x = np.array([0.0, 0.12, 0.22, 0.32, 0.36, 0.40, 0.44, 0.54, 0.64,
... 0.70, 0.80])
>>> f = np.array([0.200000, 1.30973, 1.30524, 1.74339, 2.07490, 2.45600,
... 2.84299, 3.50730, 3.18194, 2.36302, 0.231964])
>>> idl_tabulate(x, f)
1.641998154242472
```