It can definitely be done more efficiently. In the end what you've got is a series of calculations:

- Integrate LCDMf from 0 to 1.
- Integrate LCDMf from 0 to 2.
- Integrate LCDMf from 0 to 3.

So the very first thing you can do is change it to integrate distinct subintervals and then sum them (after all, what else is integration!):

- Integrate LCDMf from 0 to 1.
- Integrate LCDMf from 1 to 2, add result from step 1.
- Integrate LCDMf from 2 to 3, add result from step 2.

Next you can dive into LCDMf, which is defined this way:

```
1.0/np.sqrt(0.3*(1+x)**3+0.7)
```

You can use NumPy broadcasting to evaluate this function at many points instantly:

```
dx = 0.0001
x = np.arange(0, 100, dx)
y = LCDMf(x)
```

That should be quite fast, and gives you one million points on the curve. Now you can integrate it using `scipy.integrate.trapz()`

or one of the related functions. Call this with the y and dx already computed, using the workflow above where you integrate each interval and then use `cumsum()`

to get your final result. The only function you need to call in a loop then is the integrator itself.

`np.vectorize`

just wraps the iteration in a function call. It doesn't speed up your code.