Quotient automaton

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In computer science, in particular in formal language theory, a quotient automaton can be obtained from a given nondeterministic finite automaton by joining some of its states. The quotient recognizes a superset of the given automaton; in some cases, handled by the Myhill–Nerode theorem, both languages are equal.

Formal definition

A (nondeterministic) finite automaton is a quintuple A = ⟨Σ, S, s0, δ, Sf⟩, where:

  • Σ is the input alphabet (a finite, non-empty set of symbols),
  • S is a finite, non-empty set of states,
  • s0 is the initial state, an element of S,
  • δ is the state-transition relation: δS × Σ × S, and
  • Sf is the set of final states, a (possibly empty) subset of S.[1][note 1]

A string a1...anΣ* is recognized by A if there exist states s1, ..., snS such that ⟨si-1,ai,si⟩ ∈ δ for i=1,...,n, and snSf. The set of all strings recognized by A is called the language recognized by A; it is denoted as L(A).

For an equivalence relation ≈ on the set S of A’s states, the quotient automaton A/ = ⟨Σ, S/, [s0], δ/, Sf/⟩ is defined by[2]:5

  • the input alphabet Σ being the same as that of A,
  • the state set S/ being the set of all equivalence classes of states from S,
  • the start state [s0] being the equivalence class of A’s start state,
  • the state-transition relation δ/ being defined by δ/([s],a,[t]) if δ(s,a,t) for some s ∈ [s] and t ∈ [t], and
  • the set of final states Sf/ being the set of all equivalence classes of final states from Sf.

The process of computing A/ is also called factoring A by ≈.

Example

Quotient examples
Automaton
diagram
Recognized
language
Is the quotient of
A by B by C by
A: Quotient automaton a,b,c,d.gif 1+10+100
B: Quotient automaton a=b,c,d.gif 1*+1*0+1*00 a≈b
C: Quotient automaton a=b,c=d.gif 1*0* a≈b, c≈d c≈d
D: Quotient automaton a=b=c=d.gif (0+1)* a≈b≈c≈d a≈c≈d a≈c

For example, the automaton A shown in the first row of the table[note 2] is formally defined by

  • ΣA = {0,1},
  • SA = {a,b,c,d},
  • sA0 = a,
  • δA = { ⟨a,1,b⟩, ⟨b,0,c⟩, ⟨c,0,d⟩ }, and
  • SAf = { b,c,d }.

It recognizes the finite set of strings { 1, 10, 100 }; this set can also be denoted by the regular expression "1+10+100".

The relation (≈) = { ⟨a,a⟩, ⟨a,b⟩, ⟨b,a⟩, ⟨b,b⟩, ⟨c,c⟩, ⟨c,d⟩, ⟨d,c⟩, ⟨d,d⟩ }, more briefly denoted as a≈b,c≈d, is an equivalence relation on the set {a,b,c,d} of automaton A’s states. Building the quotient of A by that relation results in automaton C in the third table row; it is formally defined by

  • ΣC = {0,1},
  • SC = {a,c},[note 3]
  • sC0 = a,
  • δC = { ⟨a,1,a⟩, ⟨a,0,c⟩, ⟨c,0,c⟩ }, and
  • SCf = { a,c }.

It recognizes the finite set of all strings composed of arbitrarily many 1s, followed by arbitrarily many 0s, i.e. { ε, 1, 10, 100, 1000, ..., 11, 110, 1100, 11000, ..., 111, ... }; this set can also be denoted by the regular expression "1*0*". Informally, C can be thought of resulting from A by glueing state a onto state b, and glueing state c onto state d.

The table shows some more quotient relations, such as B = A/a≈b, and D = C/a≈c.

Properties

  • For every automaton A and every equivalence relation ≈ on its states set, L(A/) is a superset of (or equal to) L(A).[2]:6
  • Given a finite automaton A over some alphabet Σ, an equivalence relation ≈ can be defined on Σ* by xy if ∀ zΣ*: xzL(A) ↔ yzL(A). By the Myhill–Nerode theorem, A/ is a deterministic automaton that recognizes the same language as A.[1]:65–66 As a consequence, the quotient of A by every refinement of ≈ also recognizes the same language as A.

See also

Notes

  1. Hopcroft and Ullman (sect.2.3, p.20) use a slightly deviating definition of δ, viz. as a function from S × Σ to the power set of S.
  2. In the automaton diagrams in the table, symbols from the input alphabet and state names are colored in green and red, respectively; final states are drawn as double circles.
  3. Strictly formal, the set is SC = { [a], [b], [c], [d] } = { [a], [c] }. The class brackets are omitted for readability.

References

  1. 1.0 1.1 John E. Hopcroft; Jeffrey D. Ullman (1979). Introduction to Automata Theory, Languages, and Computation. Reading/MA: Addison-Wesley. ISBN 0-201-02988-X. 
  2. 2.0 2.1 Tristan le Gall and Bertrand Jeannet (Mar 2007). Analysis of Communicating Infinite State Machines Using Lattice Automata (Publication Interne). ISSN 1166-8687. http://www.irisa.fr/vertecs/Publis/Ps/PI-1839.pdf.