In order for k-means to produce usable results, the **means must be meaningful**.

Even if you would e.g. use binary vectors, k-means on these would not make a lot of sense IMHO.

Probably the best use case to get started with k-means is color quantization. Take a picture, and use the RGB values of every pixel as 3d vectors. Then run k-means with k as the desired number of colors. The color centers are your final palette, and every pixel will be mapped to the closest center for color reduction.

The reason why this works well with k-means are twofold:

- the mean actually makes sense for finding the mean color of multiple pixels
- the axes R, G and B have a similar meaning and scale, so there is no bias

If you want to step beyond, try to do the same e.g. in HSB space. And you'll run into difficulties if you want it to be really good. Because the hue value is cyclic, which is inconcistent with the mean. Assuming the hue is on 0-360 degrees, then the "mean" hue of "1" and "359" is *not* 180 degrees, but 0. So on this data, k-means results will be suboptimal.

See e.g. https://en.wikipedia.org/wiki/Color_quantization for details as well as the two dozen k-means questions here with respect to sparse and binary data.