# Understanding (and forming) the regular expression of this finite automaton

For the above automaton, the regular expression that has been given in my textbook is the following :

``````a*(a*ba*ba*ba*)*(a+a*ba*ba*ba*)
``````

I am having trouble deriving this...the following is my attempt at it :

``````aa* + aa*(ba*ba*ba*)* + ba*ba*ba* + ba*ba*ba*(ba*ba*ba*)*
``````

Either I am wrong or I am not being able to simplify it into the form given in the book. Can someone please guide me here, point out the mistake or explain it to me step-by-step?

I'd really really thankful and appreciate that.

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Two things. I assume the "G" in your picture is "b" in the regular expression. Also, am I right in assuming "1" is the initial state and "3" the final state? – Nico Huysamen Jan 12 '12 at 18:56
I think your answer is equivalent to the book's. Please check my answer, where I attempt to demonstrate that the book's answer can be transformed to yours according to algebra of regular expressions. – Patrick87 Jan 12 '12 at 19:52

Check this out. It presents three good, algorithmic methods for answering questions like these. Learn one of them, or all three of them if you have the time or inclination. State removal is fairly intuitive, although I like Kleene's transitive closure method.

http://krchowdhary.com/toc/dfa-to-reg-exp.pdf

EDIT: Your RE is equivalent to the one provided. here's the reduction of theirs to yours:

``````0. a*(a*ba*ba*ba*)*(a+a*ba*ba*ba*)

1. = a*(a*ba*ba*ba*)*a + a*(a*ba*ba*ba*)*a*ba*ba*ba*

2. = a*(ba*ba*ba*)*a + a*(ba*ba*ba*)*ba*ba*ba*

3. = a*a + a*(ba*ba*ba*)*a + a*(ba*ba*ba*)*ba*ba*ba*

4. = aa* + a*(ba*ba*ba*)*ba*ba*ba*a + a*(ba*ba*ba*)*ba*ba*ba*

5. = aa* + a*(ba*ba*ba*)*ba*ba*ba*

6. = aa* + aa*(ba*ba*ba*)*ba*ba*ba* + (ba*ba*ba*)*ba*ba*ba*

7. = aa* + aa*(ba*ba*ba*)* + (ba*ba*ba*)*ba*ba*ba*

8. = aa* + aa*(ba*ba*ba*)* + ba*ba*ba* + (ba*ba*ba*)*ba*ba*ba*

9. = aa* + aa*(ba*ba*ba*)* + ba*ba*ba* + ba*ba*ba*(ba*ba*ba*)*
``````

Step 1 is right since r(s+t) = rs + rt.

Step 2 is right since r*(r*sr*)* = r*(sr*)*.

Step 3 is right since r = r + s if L(s) is a subset of L(r).

Step 4 is right since r*r = rr* and rs + rq*s = rs + rqq*s.

Step 5 is right since rs + r = r.

Step 6 is right since r*s = rr*s + s.

Step 7 is right since rs + rqq*s = rs + rq*s.

Step 8 is right since r = r + s if L(s) is a subset of L(r).

Step 9 is right since r*r = rr*.

EDIT2: If you are interested in these kinds of questions, show some love for the new Computer Science StackExchange by going to this link and committing!!!

http://area51.stackexchange.com/proposals/35636/computer-science-non-programming?referrer=rpnXA1_2BNYzXN85c5ibxQ2

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Thank you !!! It's amazing how you did so much for me and even went in so far as to actually do that transformation for me. I can't say through words how grateful I am and no words can show my appreciation! Thanks so much! And much thanks for the link that you gave to the pdf file with the three algorithms. I have only just returned from the university and I'll read the algorithms and try to implement it tonight. :) Thanks again. – finitenessofinfinity Jan 13 '12 at 11:29

The textbook seems correct. Taking it step by step:

a*(a*

If this part of the regular expression is true (in other words you do actually read in an 'a'), you will move to state 3. Following the rest of the expression:

ba*

will have you in state 2,

ba*

in state 4 and

ba*

will have you back in state 3.

Now, suppose that you did not read in an 'a' during `a*(a*`, reading the next `b` will move you to state 2. You then end up in exactly the same situation as previously, and by following the rest `a*ba*ba*)` you end up back in state 3.

Since you are now back in state 3, the part `(a*ba*ba*ba*)*` can execute as many times as it wants, as this will simply be the same as our first scenario (where you read in an 'a' during `a*(a*`).

The second part simply explains the first scenario again, where you have to read at least one 'a', and then the rest is the same.

Hope this helps, let me know if it still does not make sense. Don't know if my explanation is too clear.

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thank you! And yes, your assumptions were correct :) – finitenessofinfinity Jan 13 '12 at 11:30