The problem is that the types are different. The "title" is part of the type, and `y`

uses different names from `x`

, so the types are incompatible. If you use compatible types, everything works fine:

```
>>> x = numpy.array([(1, 2), (3, 4)], dtype=[('a', '<f4'), ('b', '<f4')])
>>> y = numpy.array([(5, 6), (7, 8)], dtype=[('a', '<f4'), ('b', '<f4')])
>>> numpy.vstack((x, y))
array([[(1.0, 2.0), (3.0, 4.0)],
[(5.0, 6.0), (7.0, 8.0)]],
dtype=[('a', '<f4'), ('b', '<f4')])
>>> numpy.hstack((x, y))
array([(1.0, 2.0), (3.0, 4.0), (5.0, 6.0), (7.0, 8.0)],
dtype=[('a', '<f4'), ('b', '<f4')])
>>> numpy.dstack((x, y))
array([[[(1.0, 2.0), (5.0, 6.0)],
[(3.0, 4.0), (7.0, 8.0)]]],
dtype=[('a', '<f4'), ('b', '<f4')])
```

Sometimes `dstack`

, etc. are smart enough to coerce types in a sensible way, but `numpy`

has no way to know how to combine record arrays with different user-defined field names.

If you want to concatenate the *datatypes*, then you have to create a new datatype. Don't make the mistake of thinking that the sequence of names (`x['a']`

, `x['b']`

...) constitutes a true dimension of the array; `x`

and `y`

above are *1-d arrays* of blocks of memory, each of which contains two 32-bit floats that can be accessed using the names `'a'`

and `'b'`

. But as you can see, if you access an individual item in the array, you don't get another array as you would if it were truly a second dimension. You can see the difference here:

```
>>> x = numpy.array([(1, 2), (3, 4)], dtype=[('a', '<f4'), ('b', '<f4')])
>>> x[0]
(1.0, 2.0)
>>> type(x[0])
<type 'numpy.void'>
>>> z = numpy.array([(1, 2), (3, 4)])
>>> z[0]
array([1, 2])
>>> type(z[0])
<type 'numpy.ndarray'>
```

This is what allows record arrays to contain heterogenous data; record arrays can contain both strings and ints, but the trade-off is that you don't get the full power of an `ndarray`

at the level of individual records.

The upshot is that to join individual blocks of memory, you actually have to modify the `dtype`

of the array. There are a few ways to do this but the simplest I could find involves the little-known `numpy.lib.recfunctions`

library (which I see you've already found!):

```
>>> numpy.lib.recfunctions.rec_append_fields(x,
y.dtype.names,
[y[n] for n in y.dtype.names])
rec.array([(1.0, 2.0, 1.0, 2.0), (3.0, 4.0, 3.0, 4.0)],
dtype=[('a', '<f4'), ('b', '<f4'), ('c', '<f4'), ('d', '<f4')])
```