I figured it out on my own, so here's an explanation for anyone future person who is confused by this.

As an example, let's use the simple lattice of points that I was working with in my code, which I generate as follows

```
import numpy as np
import itertools as it
from matplotlib import pyplot as plt
import scipy as sp
inputs = list(it.product([0,1,2],[0,1,2]))
i = 0
lattice = range(0,len(inputs))
for pair in inputs:
lattice[i] = mksite(pair[0], pair[1])
i = i +1
```

Details here not really important, suffice to say it generates a regular triangular lattice in which the distance between a point and any of its six nearest neighbors is 1.

To plot it

```
plt.plot(*np.transpose(lattice), marker = 'o', ls = '')
axes().set_aspect('equal')
```

Which looks like this image (I don't have enough reputation yet to embed images, sorry)

Now compute the triangulation:

```
dela = sp.spatial.Delaunay
triang = dela(lattice)
```

Let's look at what this gives us.

```
triang.points
```

output:

```
array([[ 0. , 0. ],
[ 0.5 , 0.8660254 ],
[ 1. , 1.73205081],
[ 1. , 0. ],
[ 1.5 , 0.8660254 ],
[ 2. , 1.73205081],
[ 2. , 0. ],
[ 2.5 , 0.8660254 ],
[ 3. , 1.73205081]])
```

simple, just an array of all nine points in the lattice illustrated above. How let's look at:

```
triang.vertices
```

output:

```
array([[4, 3, 6],
[5, 4, 2],
[1, 3, 0],
[1, 4, 2],
[1, 4, 3],
[7, 4, 6],
[7, 5, 8],
[7, 5, 4]], dtype=int32)
```

In this array, each row represents one simplex (triangle) in the triangulation. The three entries in each row are the indices of the vertices of that simplex in the points array we just saw. So for example the first simplex in this array, `[4, 3, 6]`

is composed of the points:

```
[ 1.5 , 0.8660254 ]
[ 1. , 0. ]
[ 2. , 0. ]
```

Its easy to see this by drawing the lattice on a piece of paper, labeling each point according to its index, and then tracing through each row in `triang.vertices`

.

This is all the information we need to write the function I specified in my question.
It looks like:

```
def find_neighbors(pindex, triang):
neighbors = list()
for simplex in triang.vertices:
if pindex in simplex:
neighbors.extend([simplex[i] for i in range(len(simplex)) if simplex[i] != pindex])
'''
this is a one liner for if a simplex contains the point we`re interested in,
extend the neighbors list by appending all the *other* point indices in the simplex
'''
#now we just have to strip out all the dulicate indices and return the neighbors list:
return list(set(neighbors))
```

And that's it! I'm sure the function above could do with some optimization, its just what I came up with in a few minutes. If anyone has any suggestions, feel free to post them. Hopefully this helps somebody in the future who is as confused about this as I was.