Take a look at this answer. In short, you're not pumping the string correctly. The pumping lemma states that your string `w`

can be divided as `w = xyz`

where `|xy| ≥ p`

, and `y`

is not empty. You can then pump the string as xy^{i}z for all i ≥ 0.

The key here, is that the pumping lemma states that *there exists* a division of the string `w`

satisfying these properties, you do not get to choose the division, and that you can only pump the string as xy^{i}z.

However, this language is regular, so the pumping lemma can't be used to prove if a language is regular, it can only prove if a language is irregular (it's a necessary but not sufficient condition). To show that a language is regular you can construct a DFA, NFA or regular expression that describes your language exactly. One such regular expression is:

```
(a^19)*(e|ab|aabb|aaabbb|...|a^18b^18)(b^19)*
```

where `e`

is the empty string.

I suspect that your language is an example from an introductory course in automata or computation. If you're interested, the Myhill-Nerode theorem is not often covered in introductory material, but in this case offers a very easy proof of regularity: consider the distinguising extensions b, bb, bbb, ..., b^19 and the proof follows relatively easily from that.