Have a look at the two values of `x`

alone to simplify this investigation. After your first iteration, `x`

will be `2`

and `1`

, in the second iteration `1`

and `0.5`

. This means you are approaching zero with squares that are getting smaller and smaller, the opposite of what you intended to do.

How about you start big close to the origin and shrink as you go further away? You could initialize `x = [0, 2];`

and `y = [0, 2];`

. We're using only two elements here because for a square that's aligned with your axes, that's all we need. The first iteration may start with a shift by the edge length of the previous square as in `x = x + x(2) - x(1);`

. The square will have to shrink though as well, so you could move the left corners by some small fraction of the edge length, e.g. `x(1) = x(1) + (x(2) - x(1)) * 0.1;`

. To summarize, your loop would look like

```
close all, clear all;
x = [0, 2];
y = [0, 2];
hold on;
for k = 0 : 9
edge_len = x(2) - x(1);
x = x + edge_len; % shift
x(1) = x(1) + 0.2 * edge_len; % slightly shift right to shrink
y = y + edge_len;
y(1) = y(1) + 0.2 * edge_len;
fill([x(1), x(1), x(2), x(2)], [y(1), y(2), y(2), y(1)], 'r');
end
```

Note that we replaced `x(2) - x(1)`

by `edge_len`

. Then we another problem of setting your color. You could use a color vector `c = [1, k / 10, k / 10]`

to create a gradient from red to almost white. Then instead of `fill(..., 'r');`

you'd use `fill(..., c);`

With this, there won't be any `fill`

outside the loop. That used to cover all your interesting graphing in the code block you show in the question.