The main idea of the pumping lemma is to tell you that when you have a regular language `L`

with infinite number of terms, then there is a size `S`

and an infinite subset `X`

of terms `T`

in language `L`

with `length(T) > S`

for all `T in X`

such that **all** the terms in `X`

will contain **the same** pattern `P`

inside them.

Intuitively, each term in the set `X`

will repeat the pattern `P`

a number of times distinct than the number of repetitions of `P`

from the other terms of `X`

, and for each number `k`

there is a term in `X`

that repeats the pattern `P`

exactly `k`

times.

*In other words*, that regular language `L`

will contain the `Kleene operator`

in the regular expression that defines the subset `X`

. Or, simpler, there is a `subset X of L`

such that `X`

is defined with the `Kleene operator`

.

This is very suggestive.

Note that all terms must start in q0 and end in qn in this case. So, the automata defining the language is finite (max N states), so there are a limited number of states, but the words (i.e. terms) can have >N letters. The pigeon principle tells us that there must be a state that is reached 2 times, so at that state a loop will be present.

In your notation, you can make the correspondence with the image so:

your `u`

is `x`

from image

`v`

is `y`

in image

`w`

is `z`

from image

To arrive from `q0`

to `qn`

, you can use any of the strings from the set: `{ uw , uvw, uvvw, uvvvw, ... }`

.

In this particular case the pattern `P`

is `y`

, the set `X`

is `{xz xyz xyyz xyyyz ...}`

and `S`

is `length(x)+length(y)`

.

nsuch that in any sentencesof length >=nthere is some division ofsintouvwsuch that |uw| <n, |v| >= 1, anduv^iwis a sentence for alli. (Since 'c' is always repeatable in this language, you may have a challenge finding sentences in which dividing the sentence on some internal c does not work.) – C. M. Sperberg-McQueen Sep 17 at 15:38