Shift space explained

In symbolic dynamics and related branches of mathematics, a shift space or subshift is a set of infinite words that represent the evolution of a discrete system. In fact, shift spaces and symbolic dynamical systems are often considered synonyms. The most widely studied shift spaces are the subshifts of finite type and the sofic shifts.

In the classical framework^[1] a shift space is any subset

	Z:=\{(x
A
	i)

_i\inZ: x_i\inA \foralli\inZ\}

, where

is a finite set, which is closed for the Tychonov topology and invariant by translations. More generally one can define a shift space as the closed and translation-invariant subsets of

A^G

, where

is any non-empty set and

is any monoid.^[2]

Definition

Let

be a monoid, and given

g,h\inG

, denote the operation of

with

by the product

. Let

1_G

denote the identity of

. Consider a non-empty set

(an alphabet) with the discrete topology, and define

A^G

as the set of all patterns over

indexed by

. For

x=(x_i)_i\in\inA^G

and a subset

N\subsetG

, we denote the restriction of

to the indices of

x_N:=(x_i)_i\in

A^G

, we consider the prodiscrete topology, which makes

A^G

a Hausdorff and totally disconnected topological space. In the case of

being finite, it follows that

A^G

is compact. However, if

is not finite, then

A^G

is not even locally compact.

This topology will be metrizable if and only if

is countable, and, in any case, the base of this topology consists of a collection of open/closed sets (called cylinders), defined as follows: given a finite set of indices

D\subsetG

, and for each

i\inD

, let

a_i\inA

. The cylinder given by

and

(a_i)_i\in\inA^|D|

is the set

[(a_i)_i\in]_D:=\{x\in

	G: x
A
	i=a

_i, \foralli\inD\}.

When

D=\{g\}

, we denote the cylinder fixing the symbol

at the entry indexed by

simply as

[b]_g

In other words, a cylinder

[(a_i)_i\in]_D

is the set of all set of all infinite patterns of

A^G

which contain the finite pattern

(a_i)_i\in\inA^|D|

Given

g\inG

, the g-shift map on

A^G

is denoted by

\sigma^g:A^G\toA^G

and defined as

	g((x
\sigma
	i)

_i\inG)=(x_gi)_i\inG

A shift space over the alphabet

is a set

Λ\subsetA^G

that is closed under the topology of

A^G

and invariant under translations, i.e.,

\sigma^g(Λ)\subsetΛ

for all

g\inG

.^[3] We consider in the shift space

the induced topology from

A^G

, which has as basic open sets the cylinders

[(a_i)_i\in]_Λ:=[(a_i)_i\in]\capΛ

For each

k\in\N^*

, define

l{N}_k:=cup_{N\subset

}A^N, and

	f
l{N}
	A^G

:=cup_{k\in\N

}\mathcal_k= \bigcup_A^N. An equivalent way to define a shift space is to take a set of forbidden patterns

	f
F\subsetl{N}
	A^G

and define a shift space as the set

X_F:=\{x\inA^G: \forallN\subsetG,\forall

	g(x)\right)
g\inG, \left(\sigma
	N

=x_gN\notinF\}.

Intuitively, a shift space

X_F

is the set of all infinite patterns that do not contain any forbidden finite pattern of

Language of shift space

Given a shift space

Λ\subsetA^G

and a finite set of indices

N\subsetG

, let

W_{\emptyset(Λ):=\{\epsilon\}}

, where

\epsilon

stands for the empty word, and for

N ≠ \emptyset

let

W_N(Λ)\subsetA^N

be the set of all finite configurations of

A^N

that appear in some sequence of

, i.e.,

W_N(Λ):=\{(w_i)_i\in\inA^N: \exists x\inΛs.t.x_i=w_i \foralli\inN\}.

Note that, since

is a shift space, if

M\subsetG

is a translation of

N\subsetG

, i.e.,

M=gN

for some

g\inG

, then

(w_j)_j\in\inW_M(Λ)

if and only if there exists

(v_i)_i\in\inW_N(Λ)

such that

w_j=v_i

j=gi

. In other words,

W_M(Λ)

and

W_N(Λ)

contain the same configurations modulo translation. We will call the set

W(Λ):=cup_{N\subset

}W_N(\Lambda)

the language of

. In the general context stated here, the language of a shift space has not the same mean of that in Formal Language Theory, but in the classical framework which considers the alphabet

being finite, and

being

with the usual addition, the language of a shift space is a formal language.

Classical framework

The classical framework for shift spaces consists of considering the alphabet

as finite, and

as the set of non-negative integers (

) with the usual addition, or the set of all integers (

) with the usual addition. In both cases, the identity element

1_G

corresponds to the number 0. Furthermore, when

G=N

, since all

N\setminus\{0\}

can be generated from the number 1, it is sufficient to consider a unique shift map given by

\sigma(x)_n=x_n+1

for all

. On the other hand, for the case of

G=Z

, since all

can be generated from the numbers, it is sufficient to consider two shift maps given for all

\sigma(x)_n=x_n+1

and by

\sigma^-1(x)_n=x_n-1

Furthermore, whenever

with the usual addition (independently of the cardinality of

), due to its algebraic structure, it is sufficient consider only cylinders in the form

[a_0a_1...a_n]:=\{(x_i)_i\inG: x_i=a_i \foralli=0,..,n\}.

Moreover, the language of a shift space

Λ\subsetA^G

will be given by

W(Λ):=cup_n\geqW_n(Λ),

where

W_{0:=\{\epsilon\}}

and

\epsilon

stands for the empty word, and

W_n(Λ):=\{((a_i)_i=0,..n\inA^n: \existsx\inΛ s.t. x_i=a_i \foralli=0,...,n\}.

In the same way, for the particular case of

G=Z

, it follows that to define a shift space

Λ=X_F

we do not need to specify the index of

on which the forbidden words of

are defined, that is, we can just consider

F\subsetcup_n\geqAⁿ

and then

X_F=\{x\inA^Z: \foralli\inZ, \forallk\geq0, (x_i...x_i+k)\notinF\}.

However, if

G=N

, if we define a shift space

Λ=X_F

as above, without to specify the index of where the words are forbidden, then we will just capture shift spaces which are invariant through the shift map, that is, such that

\sigma(X_F)=X_F

. In fact, to define a shift space

X_F\subsetA^N

such that

\sigma(X_F)\subsetneqX_F

it will be necessary to specify from which index on the words of

are forbidden.

In particular, in the classical framework of

being finite, and

being

) or

with the usual addition, it follows that

M_F

is finite if and only if

is finite, which leads to classical definition of a shift of finite type as those shift spaces

Λ\subsetA^G

such that

Λ=X_F

for some finite

Some types of shift spaces

Among several types of shift spaces, the most widely studied are the shifts of finite type and the sofic shifts.

In the case when the alphabet

is finite, a shift space

is a shift of finite type if we can take a finite set of forbidden patterns

such that

Λ=X_F

, and

is a sofic shift if it is the image of a shift of finite type under sliding block code (that is, a map

\Phi

that is continuous and invariant for all

-shift maps). If

is finite and

with the usual addition, then the shift

is a sofic shift if and only if

W(Λ)

is a regular language.

The name "sofic" was coined by, based on the Hebrew word סופי meaning "finite", to refer to the fact that this is a generalization of a finiteness property.^[4]

When

is infinite, it is possible to define shifts of finite type as shift spaces

for those one can take a set

of forbidden words such that

M_F:=\{g\inG:\existsN\subsetGs.t.g\inNand(w_i)_i\in\inF\},

is finite and

Λ=X_F

.^[5] In this context of infinite alphabet, a sofic shift will be defined as the image of a shift of finite type under a particular class of sliding block codes. Both, the finiteness of

M_F

and the additional conditions the sliding block codes, are trivially satisfied whenever

is finite.

Topological dynamical systems on shift spaces

Shift spaces are the topological spaces on which symbolic dynamical systems are usually defined.

Given a shift space

Λ\subsetA^G

and a

-shift map

\sigma^g:Λ\toΛ

it follows that the pair

(Λ,\sigma^g)

is a topological dynamical system.

Two shift spaces

Λ\subsetA^G

and

\Gamma\subsetB^G

are said to be topologically conjugate (or simply conjugate) if for each

-shift map it follows that the topological dynamical systems

(Λ,\sigma^g)

and

(\Gamma,\sigma^g)

are topologically conjugate, that is, if there exists a continuous map

\Phi:Λ\to\Gamma

such that

\Phi\circ\sigma^g=\sigma^g\circ\Phi

. Such maps are known as generalized sliding block codes or just as sliding block codes whenever

\Phi

is uniformly continuous.

Although any continuous map

\Phi

from

Λ\subsetA^G

to itself will define a topological dynamical system

(Λ,\Phi)

, in symbolic dynamics it is usual to consider only continuous maps

\Phi:Λ\toΛ

which commute with all

-shift maps, i. e., maps which are generalized sliding block codes. The dynamical system

(Λ,\Phi)

is known as a 'generalized cellular automaton' (or just as a cellular automaton whenever

\Phi

is uniformly continuous).

Examples

The first trivial example of shift space (of finite type) is the full shift

A^N

Let

A=\{a,b\}

. The set of all infinite words over A containing at most one b is a sofic subshift, not of finite type. The set of all infinite words over A whose b form blocks of prime length is not sofic (this can be shown by using the pumping lemma).

The space of infinite strings in two letters,

\{0,1\}^N

is called the Bernoulli process. It is isomorphic to the Cantor set.

The bi-infinite space of strings in two letters,

\{0,1\}^Z

is commonly known as the Baker's map, or rather is homomorphic to the Baker's map.

Notes and References

Book: Lind . Douglas A. . An introduction to symbolic dynamics and coding . Marcus . Brian . 1995 . Cambridge University press . 978-0-521-55900-3 . Cambridge.
Book: Ceccherini-Silberstein . T. . Coornaert . M. . 2010 . Cellular automata and groups Springer Monographs in Mathematics . Springer Monographs in Mathematics . en . Springer Verlag. 10.1007/978-3-642-14034-1 . 978-3-642-14033-4 .
It is common to refer to a shift space using just the expression shift or subshift. However, some authors use the terms shift and subshift for sets of infinite patterns that are just invariant under the
g

-shift maps, and reserve the term shift space for those that are also closed for the prodiscrete topology.
. Weiss does not describe the origin of the word other than calling it a neologism; however, its Hebrew origin is stated by MathSciNet reviewer R. L. Adler.
Sobottka . Marcelo . September 2022 . Some Notes on the Classification of Shift Spaces: Shifts of Finite Type; Sofic Shifts; and Finitely Defined Shifts . Bulletin of the Brazilian Mathematical Society . New Series . en . 53 . 3 . 981–1031 . 10.1007/s00574-022-00292-x . 2010.10595 . 254048586 . 1678-7544.

Shift space explained

Definition

Language of shift space

Classical framework

Some types of shift spaces

Topological dynamical systems on shift spaces

Examples

See also

Further reading

Notes and References