automata theorem: existance of a DFA [closed]

I need to prove that for every k, there's a DFA M with k+2 states, so in every automat M' who accepts the language reverse(L(M)) there are at least 2^k states.

Help would be really appreciated.

Thanks :)

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closed as off-topic by Rory McCrossan, LaurentG, Pete, joran, animuson♦Mar 2 '14 at 1:47

This question appears to be off-topic. The users who voted to close gave this specific reason:

• "Questions asking for code must demonstrate a minimal understanding of the problem being solved. Include attempted solutions, why they didn't work, and the expected results. See also: Stack Overflow question checklist" – Rory McCrossan, LaurentG, Pete
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Assuming that the alphabet set contains at least two elements, let it be `{0,1}`.

Next, let `M` be the automata accepting the language `L` defined as:

All the strings which k-th position is 1

defined as:

M = {Q,{0,1},q0,{qk+1},δ}, where

Q={q0,q1,...,qk,qF}

δ(qi,a) = qi+1, for a in {0,1} and i=0,1,...,k-2

δ(qk-1,0) = qF,

δ(qk-1,1) = qk,

δ(qF,a) = qF, for a in {0,1}

Note that `M` has exactly `k+2` states, and that it accepts the language `L`.

Now, note that the language `reverse(L(M))` can be translated as:

All the strings which k-th position from the end is 1

To recognize that language, note that we need to remember the last k symbols, because we don't know when the string will end. We know that there are at least 2k possible strings of length k (since the alphabet size is at least 2).

So using a DFA, we need at least 2k states, each to represent one possible string of length k.

Author's note:

The idea of this proof is to find a language which is "easy" to be recognized in normal way, but "difficult" when is read backward. Through experience, I remember that fixing the k-th position from the beginning is "easy", while k-th position from the end is "difficult", hence my answer.

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