## 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 a Regular Expression?**

The approach is explained below using Arden's Theorem, applicable on a transition diagram in which there is a single start state and no null move defined (our DFA is in this form). The technique is explained 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)