The essential idea of a Kohonen map is that the data points are mapped to a
*lattice*, which is often a 2D rectangular grid.

In the simplest implementations, the lattice is initialized by creating a 3D
array with these dimensions:

```
width * height * number_features
```

**This is the U-matrix**.

Width and height are chosen by the user; number_features is just the number
of features (columns or fields) in your data.

Intuitively this is just creating a 2D grid of dimensions w * h
(e.g., if w = 10 and h = 10 then your lattice has 100 cells), then
into each cell, placing a random 1D array (sometimes called "reference tuples")
whose size and values are constrained by your data.

The reference tuples are also referred to as *weights*.

*How is the U-matrix rendered?*

In my example below, the data is comprised of rgb tuples, so the reference tuples
have length of three and each of the three values must lie between 0 and 255).

It's with this 3D array ("lattice") that you begin the main iterative loop
The algorithm iteratively positions each data point so that it is closest to others similar to it.

If you plot it over time (iteration number) then you can visualize cluster
formation.

The plotting tool i use for this is the brilliant Python library, Matplotlib,
which plots the lattice directly, just by passing it into the imshow function.

Below are eight snapshots of the progress of a SOM algorithm, from initialization to 700 iterations. The newly initialized (iteration_count = 0) lattice is rendered in the top left panel; the result from the final iteration, in the bottom right panel.

Alternatively, you can use a lower-level imaging library (in Python, e.g., PIL) and transfer the reference tuples onto the 2D grid, one at a time:

```
for y in range(h):
for x in range(w):
img.putpixel( (x, y), (
SOM.Umatrix[y, x, 0],
SOM.Umatrix[y, x, 1],
SOM.Umatrix[y, x, 2])
)
```

Here *img* is an instance of PIL's *Image* class. Here the image is created by iterating over the grid one pixel at a time; for each pixel, *putpixel* is called on *img* three times, the three calls of course corresponding to the three values in an rgb tuple.