In mathematics and theoretical computer science, a k-synchronized sequence is an infinite sequence of terms s(n) characterized by a finite automaton taking as input two strings m and n, each expressed in some fixed base k, and accepting if m = s(n). The class of k-synchronized sequences lies between the classes of k-automatic sequences and k-regular sequences.
Let Σ be an alphabet of k symbols where k ≥ 2, and let [n]k denote the base-k representation of some number n. Given r ≥ 2, a subset R of N r {\displaystyle \mathbb {N} ^{r}} is k-synchronized if the relation {([n1]k, ..., [nr]k)} is a right-synchronized[1] rational relation over Σ∗ × ... × Σ∗, where (n1, ..., nr) ∈ {\displaystyle \in } R.[2]
Let n ≥ 0 be a natural number and let f: N → N {\displaystyle \mathbb {N} \rightarrow \mathbb {N} } be a map, where both n and f(n) are expressed in base k. The sequence f(n) is k-synchronized if the language of pairs { ( n , f ( n ) ) } {\displaystyle \{(n,f(n))\}} is regular.
The class of k-synchronized sequences was introduced by Carpi and Maggi.[2]
Given a k-automatic sequence s(n) and an infinite string S = s(1)s(2)..., let ρS(n) denote the subword complexity of S; that is, the number of distinct subwords of length n in S. Goč, Schaeffer, and Shallit[3] demonstrated that there exists a finite automaton accepting the language
This automaton guesses the endpoints of every contiguous block of symbols in S and verifies that each subword of length n starting within a given block is novel while all other subwords are not. It then verifies that m is the sum of the sizes of the blocks. Since the pair (n, m)k is accepted by this automaton, the subword complexity function of the k-automatic sequence s(n) is k-synchronized.
k-synchronized sequences exhibit a number of interesting properties. A non-exhaustive list of these properties is presented below.