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I am asked to show DFA diagram and RegEx for the complement of the RegEx (00 + 1)*. In the previous problem I had to prove that the complement of a DFA is closed and is a regular expression also, so I know that to convert a DFA, M to the complement, M`, I just need to swap the initial accepting states and final accepting states.

However, it appears that the initial accepting states for the RegEx are {00, 1, ^} and the final accepting states are {00, 1, ^} as well. So swapping them will just result in the exact same RegEx and DFA which seems contradictory.

Am I doing something wrong or is this RegEx supposed to not have a real complement?

Thank you

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A DFA only has one initial state, so you're probably making a mistake there. Write the DFA itself and verify it before trying to complement it. –  aaaaaa123456789 Feb 10 '13 at 21:26
Also, in order to complement the DFA, you just swap "final-ness" for each state -- that is, make every non-final state final, and every final state non-final. –  aaaaaa123456789 Feb 10 '13 at 21:28
Well couldn't the initial state be 00 or 1? –  Matt Hintzke Feb 10 '13 at 21:35
Not really -- keep in mind that the initial state is where it begins reading the string, so it has read nothing so far. There's transitions from it with 00 and 1, though. Maybe you should look up some info on DFAs? –  aaaaaa123456789 Feb 10 '13 at 21:40
well I understand that. technically, it starts as a null string and then 00 or 1 can be read. but that would not change my predicament –  Matt Hintzke Feb 10 '13 at 21:49

2 Answers 2

up vote 16 down vote accepted

As you says in question:

I know that to convert a DFA, M to the complement, M`, I just need to swap the initial accepting states and final accepting states.

Its not complement, but you are doing something like reverse of a language and regular languages are closure under reversal.

Reversal of DFA

What is the Reversal Language ?

The reversal of a language L (denoted LR) is the language consisting of the reversal of all strings in L.

Given that L is L(A) for some FA A, we can construct an automaton for LR:

  • reverse all edges (arcs) in the transition diagram

  • the accepting state for the LR automaton is the start state for A

  • create a new start state for the new automaton with epsilon transitions to each of the accept states for A

Note: By reversing all its arrows and exchanging the roles of initial and accepting states of a DFA you may get an NFA instead.
that's why I written FA(not DFA)

Complement DFA

Finding the complement of a DFA?

Defination: The complement of a language is defined in terms of set difference from Σ* (sigma star). that is L' = Σ* - L.

And the complement language (L') of L has all strings from Σ* (sigma star) except the strings in L. Σ* is all possible strings over the alphabet Σ.
Σ = Set of language symbols

To construct the DFA D that accepts the complement of L, simply convert each accepting state in A into a non-accepting state in D and convert each non-accepting state in A into an accept state in D.
(Warning! This is not true for NFA's)

A is DFA of L, D is for complement

Note: To construct complement DFA, old DFA must be a complete means there should all possible out going edge from each state(or in other words δ should be a complete function).

Complement: reference with example

Complement DFA for Regular Expression (00+1)*

below is DFA named A:


But not this DFA is not complete DFA. transition function δ is partially defined but not for full domain Q×Σ (missing out going edge from q1 for lable 1).

Its complete DFA can be as follows (A):


In the above DFA, all possible transactions are defined (*for every pair of Q,Σ *) and δ is a complete function in this case.

Reff: to learn what is Partial Function.

New complement DFA D can be constructed by changing all final states q0 to not final states and vice-versa.

So in complement q0 become non-final and q1, q2 are the final states.


Now you can write Regular expression for complement language using ARDEN'S THEOREM and DFA I given.

Here I am writing Regular Expression for complement directly:

(00 + 1)* 0 (^ + 1(1 + 0)*)

where ^ is null symbol.

some helpful links:
From here and through my profile you can find some more helpful answers on FA. Also, two good links on properties of regular language: one, second

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check this also HOW TO WRITE REGULAR EXPRESSION FOR A DFA –  Grijesh Chauhan Feb 11 '13 at 17:41
what about dead state ??If the DFA of a language L contains a dead state ,then how to tackle it..??Do i have to make the dead state also as accepting state ? –  Coffee_lover Dec 10 '13 at 2:46
@Coffee_lover 'Dead state' means string is unaccepted. Suppose while processing a string you reach to a dead state then string is not belongs to language of DFA. E.g in diagram-2 in above answer state q2 is dead state Now suppose you have a string 10110 then to process this string you need this move q0--1-->q0--0-->q1--1-->q2--1-->q2--0-->q2 Notice in this once you reach a dead q2 then you can't change state for all language symbols. -----Generally we can ignore drawing dead states in a DFA. –  Grijesh Chauhan Dec 10 '13 at 4:38
my question is about complement for eg. L=10110 now how to draw complemented DFA for it.. u said change accepting into non accepting and vice versa but what about dead state...do i consider it as a non accepting state and convert into accepting state while drawing the complemented dfa –  Coffee_lover Dec 10 '13 at 5:35
@Coffee_lover First read this answer How does “δ:Q×Σ→Q” read in the definition of a DFA Learn definition of complete DFA. Again 'Dead states' means a stat from which a 'Accepting state' is unreachable. See expression/statement L = 10110 is wrong do you means L = {10110} because a language is a set. –  Grijesh Chauhan Dec 10 '13 at 6:15

I didn't take the time to read all of Grijesh's answer, but here's the simple way to get a DFA accepting the complement of a language, given a DFA accepting the language: use the same DFA, but change accepting states to non-accepting, and vice-versa.

Strings previously accepted will be rejected, and strings previously rejected will be accepted. Since all transitions must be defined in any valid DFA, and since all input strings lead to exactly one state, this always works.

To get a DFA for the reversal, you can first construct an NFA by adding a new initial state that branches non-deterministically to all of the accepting states of the original DFA. Reverse all the transitions of the original DFA, and make the only accepting state be the initial state of the original DFA.

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It is not correct. Consider binary alphabet {0,1} and FA accepting "1*". Complement of it would be FA accepting "0+". But since you don't have arcs labeled "0" in your initial FA you can switch whatever you like and you still don't get a complement of initial FA. –  greenoldman Feb 22 '13 at 22:29
@greenoldman In a DFA, you do have transitions for 0. These transitions lead to a "dead" state. Note that, in general, you are correct that this algorithm fails for NFAs, including those which resemble DFAs (except that they do not show all transitions and states, including a dead state as necessary). I content that the algorithm should work for any complete DFA (note that one might define DFAs in non-standard ways such that my algorithm is incorrect; this is what you appear to be doing) –  Patrick87 Feb 22 '13 at 23:14
No, I don't. There is no such requirement for DFA to have dead arcs (or dead nodes). The aim of construct DFA is to create DFA to accept all acceptable input. You don't have to add phony arcs and phony nodes for non-acceptable input, because lack of recognition is equal to rejecting the input. –  greenoldman Feb 23 '13 at 20:54
@greenoldman I don't disagree that it's equivalent in terms of power; but the canonical definition of a DFA, as far as I'm aware, requires all transitions and states be defined. If your definition does not, you'd need to add them for this answer to apply. If you think it would be better to clarify this in the answer, I can, or the clarification can stay in the comments. –  Patrick87 Feb 24 '13 at 2:36

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