In automata theory, a branch of theoretical computer science, an ω-automaton is a variation of finite automata that runs on infinite, rather than finite, strings as input. Since ω-automata do not stop, they have a variety of acceptance conditions rather than simply a set of accepting states. ω-automata are useful for specifying behavior of systems that are not expected to terminate, such as hardware, operating systems and control systems. For such systems, one may want to specify a property such as "for every request, an acknowledge eventually follows", or its negation "there is a request that is not followed by an acknowledge". The former is a property of infinite words: one cannot say of a finite sequence that it satisfies this property. Classes of ω-automata include the Büchi automata, Rabin automata, Streett automata, parity automata and Muller automata, each deterministic or non-deterministic. These classes of ω-automata differ only in terms of acceptance condition. They all recognize precisely the regular ω-languagesexcept for the deterministic Büchi automata, which is strictly weaker than all the others. Although all these types of automata recognize the same set of ω-languages, they nonetheless differ in succinctness of representation for a given ω-language.
Deterministic ω-automata
Formally, a deterministic ω-automaton is a tuple A = that consists of the following components:
Q is a finite set. The elements of Q are called the states of A.
Acc is the acceptance condition, formally a subset of Qω.
An input for A is an infinite string over the alphabet Σ, i.e. it is an infinite sequence α = . The run of A on such an input is an infinite sequence ρ = of states, defined as follows:
r0 = q0.
r1 = δ.
r2 = δ.
rn = δ.
The main purpose of an ω-automaton is to define a subset of the set of all inputs: The set of accepted inputs. Whereas in the case of an ordinary finite automaton every run ends with a state rn and the input is accepted if and only ifrn is an accepting state, the definition of the set of accepted inputs is more complicated for ω-automata. Here we must look at the entire run ρ. The input is accepted if the corresponding run is in Acc. The set of accepted input ω-words is called the recognized ω-language by the automaton, which is denoted as L. The definition of Acc as a subset of Qω is purely formal and not suitable for practice because normally such sets are infinite. The difference between various types of ω-automata consists in how they encode certain subsets Acc of Qω as finite sets, and therefore in which such subsets they can encode.
Nondeterministic ω-automata
Formally, a nondeterministic ω-automaton is a tuple A = that consists of the following components:
Q is a finite set. The elements of Q are called the states of A.
Σ is a finite set called the alphabet of A.
Δ is a subset of Q × Σ × Q and is called the transition relation of A.
Q0 is a subset of Q, called the initial set of states.
Acc is the acceptance condition, a subset of Qω.
Unlike a deterministic ω-automaton, which has a transition function δ, the non-deterministic version has a transition relation Δ. Note that Δ can be regarded as a function : Q × Σ → P from Q × Σ to the power setP. Thus, given a state qn and a symbol an, the next state qn+1 is not necessarily determined uniquely, rather there is a set of possible next states. A run of A on the input α = is any infinite sequence ρ = of states that satisfies the following conditions:
r0 is an element of Q0.
r1 is an element of Δ.
r2 is an element of Δ.
rn is an element of Δ.
A nondeterministic ω-automaton may admit many different runs on any given input, or none at all. The input is accepted if at least one of the possible runs is accepting. Whether a run is accepting depends only on Acc, as for deterministic ω-automata. Every deterministic ω-automaton can be regarded as a nondeterministic ω-automaton by taking Δ to be the graph of δ. The definitions of runs and acceptance for deterministic ω-automata are then special cases of the nondeterministic cases.
Acceptance conditions
Acceptance conditions may be infinite sets of ω-words. However, people mostly study acceptance conditions that are finitely representable. The following lists a variety of popular acceptance conditions. Before discussing the list, let's make the following observation. In the case of infinitely running systems, one is often interested in whether certain behavior is repeated infinitely often. For example, if a network card receives infinitely many ping requests, then it may fail to respond to some of the requests but should respond to an infinite subset of received ping requests. This motivates the following definition: For any run ρ, let Inf be the set of states that occur infinitely often in ρ. This notion of certain states being visited infinitely often will be helpful in defining the following acceptance conditions.
A Büchi automaton is an ω-automaton A that uses the following acceptance condition, for some subset F of Q:
A ' is an ω-automaton A that uses the following acceptance condition, for some set Ω of pairs of sets of states:
A Streett automaton is an ω-automaton A that uses the following acceptance condition, for some set Ω of pairs of sets of states:
The Streett condition is the negation of the Rabin condition. Therefore a deterministic Streett automaton accepts exactly the complement of the language accepted by the deterministic Rabin automaton consisting of the same data.
A parity automaton is an automaton A whose set of states is Q = for some natural numberk, and that has the following acceptance condition:
A Muller automaton is an ω-automaton A that uses the following acceptance condition, for a subset F of P :
Every Büchi automaton can be regarded as a Muller automaton. It suffices to replace F by F' consisting of all subsets of Q that contain at least one element of F'. Similarly every Rabin, Streett or parity automaton can also be regarded as a Muller automaton.
Example
The following ω-language L over the alphabet Σ = , which can be recognized by a nondeterministic Büchi automaton: L consists of all ω-words in Σω in which 1 occurs only finitely many times. A non-deterministic Büchi automaton recognizing L needs only two statesq0 and q1. Δ consists of the triples,, and. F = . For any input α in which 1 occurs only finitely many times, there is a run that stays in state q0 as long as there are 1s to read, and goes to state q1 afterwards. This run is successful. If there are infinitely many 1s, then there is only one possible run: the one that always stays in state q0. Notice that above language cannot be recognized by a deterministic Büchi automaton, which is strictly less expressive than its non-deterministic counterpart.
Expressive power of ω-automata
An ω-language over a finite alphabet Σ is a set of ω-words over Σ, i.e. it is a subset of Σω. An ω-language over Σ is said to be recognized by an ω-automaton A if it is the set of all ω-words accepted by A. The expressive power of a class of ω-automata is measured by the class of all ω-languages that can be recognized by some automaton in the class. The nondeterministic Büchi, parity, Rabin, Streett, and Muller automata, respectively, all recognize exactly the same class of ω-languages. These are known as the ω-Kleene closure of the regular languages or as the regular ω-languages. Using different proofs it can also be shown that the deterministic parity, Rabin, Streett, and Muller automata all recognize the regular ω-languages. It follows from this that the class of regular ω-languages is closed under complementation. However, the example above shows that the class of deterministic Büchi automata is strictly weaker.
Conversion between ω-automata
Because nondeterministic Muller, Rabin, Streett, parity, and Büchi automata are equally expressive, they can be translated to each other. Let us the following abbreviation : for example, NB stands for nondeterministic Büchi ω-automaton, while DP stands for deterministic parity ω-automaton. Then the following holds.
with a polynomial blow-up in the state space, i.e., the number of states in the resulting NB is, where is the number of states in the NB and is the number of Rabin acceptance pairs.
with exponential blow-up in the state space.
with exponential blow-up in the state space. This determinization result uses Safra's construction.
A comprehensive overview of translations can be found on the referenced web source.