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Is it possible to come up with a linear grammar with unequal number of 0s and 1s?

Such as 0100, 01100, 111,1,0, 100101001...

I know there is a context-free grammar for this, but is there a linear grammar?


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1 Answer 1

up vote 2 down vote accepted

A grammar is regular if and only if it is either left regular or right regular. The left regular grammars are equivalent to the left linear grammars. The right regular grammars are equivalent to the right linear grammars. Therefore, if a regular grammar exists that generates the indicated language, then it is either right or left regular, and hence equivalent to either a left or right linear grammar.


Note that there's no regular grammar generating the indicated language LUNEQ. To see this, consider the fact that LEQ = { w : na(w) = nb(w)} is the complement of LUNEQ. Because the regular languages are closed under complementation and LEQ is not a regular language, LUNEQ is not a regular language.


I believe the pumping lemma for linear languages can be used to show that the indicated language LUNEQ is not linear. Here is what I've come up with. I'm fairly confident it's correct. My primary concern is that you were asked - presumably - for a linear language generating the indicated language; however, I came to the conclusion that there is no such grammar.

Assume LUNEQ is linear. By the pumping lemma for linear languages, there exists an n > 0 depending on LUNEQ such that for all zLUNEQ, z can be written uvwxy where:

  • |vx| > 0,
  • |uvxy| ≤ n, and
  • uviwxiyLUNEQ for all i ≥ 0.

Let n be the constant guaranteed be the pumping lemma. Consider the string

  • z = anb(n! + 2n)an

Since zLUNEQ, it can be decomposed into substrings uvwxy satisfying the constraints of the pumping lemma such that, for all i ≥ 0, the string

  • uviwxiy = a|u|ai|v|a(n - |u| - |v|)b(n! + 2n)a(n - |x| - |y|)ai|x|a|y|

is a member of LUNEQ. Since 1 ≤ |vx| ≤ n, |vx| divides n!. Hence, (n!|vx|-1 + 1) is a natural number. Setting i to (n!|vx|-1 + 1) gives the string

  • z' = uv(n!|vx|-1 + 1)wx(n!|vx|-1 + 1)y = a|u|a(n!|vx|-1 + 1)|v|a(n - |u| - |v|)b(n! + 2n)a(n - |x| - |y|)a(n!|vx|-1 + 1)|x|a|y|

Simplifying the pumped string gives us an equal number of a's and b's:

  • na(z') = 2n - |vx| + (n!|vx|-1 + 1)|vx| = 2n + n!

Since (2n + n!) is equivalent to the number of b's in the pumped string, z' ∉ LUNEQ. But this contradicts the assumption that LUNEQ is a linear language. Hence, LUNEQ is not a linear language.

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yes sorry i updated my question. I meant i know there is a CFG for this, but i can't seem figure out if there is something linear to solve this problem. – Matt Oct 10 '11 at 9:02
I updated the post with an ostensible proof that the language containing an unequal number of a's and b's isn't linear. If you see any problems, please let me know. – danportin Oct 10 '11 at 19:02
Edit, again. Can I ask what textbook you're using? I just looked through a few formal languages books I had lying around to see whether the author expected the reader to find a grammar, or determine if one exists. – danportin Oct 10 '11 at 21:37
sipser mostly, just reading other online lectures as well. Haven't got to the proofs yet, but i just couldn't find a linear grammar that existed for this situation. Nice answer though. Thanks. – Matt Oct 11 '11 at 0:22
Thanks. I have never read Sipser's book. I'll have to look it up, because most introduction to formal languages books don't present the pumping lemma for linear languages. Sounds good. – danportin Oct 11 '11 at 3:15

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