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Is there some kind of proof for this? How can we know that the current NFA has the minimum amount?

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Your post probably was marked down, because of lack of detail in your question. – octopusgrabbus Jan 30 '12 at 19:00
up vote 3 down vote accepted

As opposed to DFA minimization, where efficient methods exist to not only determine the size of, but actually compute, the smallest DFA in terms of number of states that describes a given regular language, no such general method is known for determining the size of a smallest NFA. Moreover, unless P=PSPACE, no polynomial-time algorithm exists to compute a minimal NFA to recognize a language, as the following decision problem is PSPACE-complete:

Given a DFA M that accepts the regular language L, and an integer k, is there an NFA with ≤ k states accepting L?

(Jiang & Ravikumar 1993).

There is, however, a simple theorem from Glaister and Shallit that can be used to determine lower bounds on the number of states of a minimal NFA:

Let L ⊆ Σ* be a regular language and suppose that there exist n pairs P = { (xi, wi) | 1 ≤ in } such that:

  1. xi wiL for 1 ≤ in
  2. xj wiL for 1 ≤ j, in and ji

Then any NFA accepting L has at least n states.

See: Ian Glaister and Jeffrey Shallit (1996). "A lower bound technique for the size of nondeterministic finite automata". Information Processing Letters 59 (2), pp. 75–77. DOI:10.1016/0020-0190(96)00095-6.

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OK, so polynomial time or space is not possible. What if we aren't concerned with performance. Surely there is an exhaustive algorithm, no? PSPACE-complete doesn't mean unsolvable, right? – Brent Jul 27 '13 at 19:49
@Brent: Correct, PSPACE-complete does not mean unsolvable (after all, TQBF is solvable by a recursive algorithm). However, in this case, the claim that no such general method is known for determining the smallest NFA comes from the Glaister & Shallit paper. See also "Computational complexity of NFA minimization for finite and unary languages" by Hermann Gruber and Markus Holzer. – Daniel Trebbien Jul 27 '13 at 22:53
Note that the Glaister-Shallit lower bound (also known as the fooling-set method in computational complexity, and a special case of more general computational complexity lower bounds on NFA sizes) is not tight. Unfortunately, it could be that the biggest possible fooling set P has n elements, but the minimal NFAs have $2^O(n)$ states. – Artem Kaznatcheev Oct 3 '13 at 6:51

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