Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# How do we know that an NFA has a minimum amount of states?

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

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

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.

-
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