## How to write regular expression for a DFA using Arden theorem

Lets instead of language symbols `0`

,`1`

we take `Σ = {a, b}`

and following is new DFA.

Notice start state is Q_{0}

You have not given but In my answer initial state is Q_{0}, Where final state is also Q_{0}.

Language accepted by is DFA is set of all strings consist of symbol `a`

and `b`

where number of symbol `a`

and `b`

are even (including `Λ`

).

Some example strings are `{Λ, aa, bb, abba, babbab }`

, there is no constraint of order and patter of appearance of symbol just both should be even number of time.

note: `Λ`

is allowed because numberOf(`a`

) and numberOf(`b`

) is zero that is even.

As I said in my lined answer: How to write regular expression for a DFA every state stores some information. Below is a what information is stored in each state in above DFA.

Q_{0}: Even number of `a`

and even number of `b`

Q_{1}: Odd number of `a`

and even number of `b`

Q_{2}: Odd number of `a`

and odd number of `b`

Q_{3}: Even number of `a`

and odd number of `b`

(*You can make DFAs for more interesting languages by changing set of final sates*)

_{One should read the lined answer, because my approach to fined RE for DFA in both answer is different}

**What is Regular Expression?**

The approach below explained using Arden's Therm, can be applicable on transition diagram in which there is single start state and there is no null move defined (Our DFA is in this form). This technique is explain in a book: Formal Languages And Automata Theory

Remember 4.2 ARDEN THEOREM:

Let `B`

and `C`

be are two Regular Expressions over `Σ`

. If `C`

does not contain `Λ`

, then for the equation A = B + AC has a unique (one and only one) solution A = BC*.

**[Solution]:**

**Step-1**: Write initial equation, one equation for corresponding to each state in DFA. This equation means how a state can be reach in a single step

So according to our DFA following 4-equations are possible:

- Q
_{0} = `Λ`

+ Q_{1}a + Q_{3}b
- Q
_{1} = Q_{0}a + Q_{2}b
- Q
_{2} = Q_{1}b + Q_{3}a
- Q
_{3} = Q_{0}b + Q_{2}a

In equation (1) extra `Λ`

is because Q_{0} is initial state, can be reached without any input (a point of start).
Because Q_{0} is also only a final state, a string consist of `a, b`

is acceptable if it ends at Q_{0}. Value of Q_{0} will give us required regular expression so our target is to simply equation-(1) in terms of `a, b`

.

**Step-2:** Simplify equation using by putting value of states from other equations and using Arden's simplification equation.

Lets we first take equation-(4) and replace value of Q_{2} from equation-(3).

Q_{3} = Q_{0}b + Q_{2}a

Q_{3} = Q_{0}b + (Q_{1}b + Q_{3}a) a

Q_{3} = Q_{0}b + Q_{1}ba + Q_{3}aa

The last equation can be view in the form of Arden's equation `A = B + AC`

. Where A is Q_{3}, B = Q_{0}b + Q_{1}ba and C = `aa`

. So according to Arden's therm, equation Q_{3} = Q_{0}b + Q_{1}ba + Q_{3}aa has a unique solution that is:

Q_{3} = (Q_{0}b + Q_{1}ba)(aa)*

Or one can write this as follows:

`5.`

Q_{3} = Q_{0}b(aa)* + Q_{1}ba(aa)*

Logically you can check/understand eq-(5) means Q_{3} can be reached in two ways (`+`

) fist from by applying `b`

on Q_{0} then there is a loop with label `aa`

on Q_{3}, second way is from Q_{1} with application of `ba`

.

In similar ways, we can simplify equation-(2)

Q_{1} = Q_{0}a + Q_{2}b

Q_{1} = Q_{0}a + (Q_{1}b + Q_{3}a)b

Q_{1} = Q_{0}a + Q_{1}bb + Q_{3}ab

Use Arden's simplification rules here.

Q_{1} = (Q_{0}a + Q_{3}ab)(bb)*

further simplify

`6.`

Q_{1} = Q_{0}a(bb)* + Q_{3}ab(bb)*

Now value of Q_{3} from equation-(5) into equation-(6)

Q_{1} = Q_{0}a(bb)* + (Q_{0}b(aa)* + Q_{1}ba(aa)* )ab(bb)*

Q_{1} = Q_{0}a(bb)* + Q_{0}b(aa)* ab(bb)* + Q_{1}ba(aa)* ab(bb)*

Again improve this last equation using Arden law of simplification.

Q_{1} = (Q_{0}a(bb)* + Q_{0}b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )*

take Q_{0} conman:

`7.`

Q_{1} = Q_{0}(a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )*

Can you understand this equation, Its how you can go to Q_{1} from state Q_{0}? We remember this solution as equation-(7)

As above we can evaluate value of Q_{1} in terms of state Q_{0} and `a, b`

, Similarly we are to evaluate value for state Q_{3}. For this we can simple put value of state Q_{1} from equation-(5) into equation-(7).

`5.`

Q_{3} = Q_{0}b(aa)* + Q_{1}ba(aa)*

`.`

Q_{3} = Q_{0}b(aa)* + Q_{0}(a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* ba(aa)*

`8.`

Q_{3} = Q_{0} ( b(aa)* + (a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* ba(aa)* )

Now, in equation number (1) put value of state Q_{3} and Q_{1} from equation number (8) and (7) receptively.

Q_{0} = `Λ`

+ Q_{1}a + Q_{3}b

Q_{0} = `Λ`

+ Q_{0}(a(bb)* + (aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* a + Q_{0} ( b(aa)* + (a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* ba(aa)* ) b

Now, Last time apply Arden solution to find value of state Q_{0} in terms of symbols `a`

and `b`

.

Q_{0} = `Λ`

+ ( (a(bb)* + (aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* a + ( b(aa)* + (a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* ba(aa)* ) b )*

that is same as (we can discard `Λ`

here) RE:

( (a(bb)* + (aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* a + ( b(aa)* + (a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* ba(aa)* ) b )*

This is the RE you where looking for.

I am not sure that it can be further simplified. I am leaving it as an exercise for you.

In linked question I suggested a non-formal and analytical method but it was hard to apply and find RE for this DFA and this question demonstrate power of Arden's theorem and step by step solution.

**Edit**:

My previous regular expression is correct but hard to grapes because unsymmetrical form. Below I am writing new form of RE that is more symmetrical.

We have equation-(5), (6) as follows:

`5.`

Q_{3} = Q_{0}b(aa)* + Q_{1}ba(aa)*

`6.`

Q_{1} = Q_{0}a(bb)* + Q_{3}ab(bb)*

Both are symmetrical in construction and easy to learn. (*read my comment after eq-(5) above*)

To evaluate value of state Q_{1} in terms of Q_{0}, I putted value of Q_{3} from equation-(5) into equation-(6) that gives me equation-(7) as follows:

`7.`

Q_{1} = Q_{0}(a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )*

Similarly, to evaluate value of state Q_{3} in terms of Q_{0}, we can put value of Q_{1} from equation-(6) into equation-(5) that will give us new form of equation-(8) as follows:

Q_{3} = Q_{0}b(aa)* + Q_{1}ba(aa)*

Q_{3} = Q_{0}b(aa)* + (Q_{0}a(bb)* + Q_{3}ab(bb)* ) ba(aa)*

Q_{3} = Q_{0}b(aa)* + Q_{0}a(bb)* ba(aa)* + Q_{3}ab(bb)* ba(aa)*

Now, we can have equation-(8) in our desired form:

`8.`

Q_{3} = Q_{0}(b(aa)* + a(bb)* ba(aa)* )(ab(bb)* ba(aa)* )*

Now, we have equation-(1), (7), (8):

`1.`

Q_{0} = `Λ`

+ Q_{1}a + Q_{3}b

`7.`

Q_{1} = Q_{0}(a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )*

`8.`

Q_{3} = Q_{0}(b(aa)* + a(bb)* ba(aa)* ) (ab(bb)* ba(aa)* )*

Now, we can have equation-(8) in our desired form:

`8.`

Q_{3} = Q_{0}(b(aa)* + a(bb)* ba(aa)* )(ab(bb)* ba(aa)* )*

Now, we have equation-(1), (7), (8):

`1.`

Q_{0} = `Λ`

+ Q_{1}a + Q_{3}b

`7.`

Q_{1} = Q_{0}(a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )*

`8.`

Q_{3} = Q_{0}(b(aa)* + a(bb)* ba(aa)* ) (ab(bb)* ba(aa)* )*

Now put value of state Q_{1} and Q_{3} into equation-(1):

Q_{0} = `Λ`

+ Q_{0}(a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* a + Q_{0}(b(aa)* + a(bb)* ba(aa)* ) (ab(bb)* ba(aa)* )* b

can also be written as:

Q_{0} = `Λ`

+ Q_{0} ( (a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* a + (b(aa)* + a(bb)* ba(aa)* ) (ab(bb)* ba(aa)* )* b )

Next, apply Arden's theorem on this equation, and we get the final RE:

## Regular Expression for even numbers of *'a'* and even numbers of *'b'*:

( (a(bb)* + b(aa)* ab(bb)* ) (ba(aa)* ab(bb)* )* a + (b(aa)* +
a(bb)* ba(aa)* ) (ab(bb)* ba(aa)* )* b )*

Can one step further simplified as below:

```
((a + b(aa)*ab)(bb)*(ba(aa)*ab(bb)*)*a + (b + a(bb)*ba)(aa)*(ab(bb)*ba(aa)*)*b)*
```

directlyfor your DFA bit typical. (Even with Arden's therm solution will be long) – Grijesh Chauhan Jul 2 '13 at 9:08