# automata: using only Equivalence class to proove regularity

I have tried to go about this problem in several ways, and looked in several places with no answer. the question is as follow:

[Question]
Given two regular languages (may be referred to as finitely described languages ,idk) `L1` and `L2`, we define a new language as such:

``````L =  {w1w2| there are two words, x,y such that : xw1 is in L1, w2y is in L2}
``````

I am supposed to use to show that `L is regular`, however I have the following restrictions:

• I must use Equivalence class, and no other way

• I cannot use `Rank(L)`, as in show a limit to the number of equivalence class, instead I must show them

• I may use the Closure properties that all regular languages hold

I am not expecting a full proof (though that would be appreciated) but an explanation to how to go about such a thing.

• `L` is not regular for present statement, But I also feel you did some mistake in writing question. may be `L = w1w2`. – Grijesh Chauhan Dec 15 '12 at 14:00
• yes I did mean w1w2. sorry for the confusion – Tom S. Dawn Dec 15 '12 at 19:34

L = {w1w2| there are two words, x,y such that : xw1 is in L1, w2y is in L2} is regular if L1 and L2 are regular languages.

Lsuff = { w1 | xw1 ∈ L1 }
Lpref = { w2 | w2y ∈ L2 }

And,

L = LsuffLpref

We can easily proof by construction Finite Automata for `L`.

Suppose Finite Automata(FA) for L1 is M1 and FA for L2 is M2.

[SOLUTION]
Non-Deterministic Finite Automata(NFA) for L can be drawn by introducing NULL-transition (^-edge) form every state in M1 to every state in M2. then NFA can be converted into DFA.

e.g.
L1 = {ab ,ac} and L2 = {12, 13}

L = {ab, ac, 12, 13, a12, a2, ab12, ab2, a13, a3, ab13, ab3, ............}
Note: w1 and w2 can be NULL

M1 =is consist of Q = {q0,q1,qf} with edges:

q0 ---a----->q1,
q1 ---b/c--->qf

Similarly :

M2 =is consist of Q = {p0,p1,pf} with edges:

p0 ---1----->p1,
p1 ---2/3--->pf

Now, NFA for L called M will be consist of Q = {q0,q1,qf, p0,p1,pf} Where Final state of M is pf and edges are:

q0 ---a----->q1,
q1 ---b/c--->qf,
p0 ---1----->p1,
p1 ---2/3--->pf,

q0 ----^----> p0,
q1 ----^----> p0,
qf ----^----> p0,

q0 ----^----> p1,
q1 ----^----> p1,
qf ----^----> p1,

q0 ----^----> pf,
q1 ----^----> pf,
qf ----^----> pf

`^` means NULL-Transition.

Now, A NFA can easily convert into DFA.(I leave it for you)

DFA for L is possible hence L is Regular Language.

I will highly encourage you to draw DFA/NFA figures, then concept will be clear.>

• Let me know if you need more help on this. – Grijesh Chauhan Dec 18 '12 at 10:49

Note

I am writing this answer, because I believe that the current available doesn't really satisfy the post requirements, i.e.

I must use Equivalence class, and no other way

A more direct and simple approach is to not construct a DFA/NFA because of time reasons, but to just check if `#EquivalenceClasses < ∞` holds. Specifically, you would have the following ones here:

``````[w1] = {all w1 in L1}
[e]
[w1w2] = L
``````

So `ind(R)`, the index of the equivalence relation, is `3`, therefore finite. Hence, `L` is regular. Q.E.D.

To make it more clear, just have a look at the definition of the equivalence relation for languager, i.e. `R_L`.

Moreover, regular languages are closed under concatenation. De facto you just need to concatenate the two DFA/NFA's into one.