3. Algebra

3.1. Galois connections

Fixed points, idempotent functions

∀_Fnc f, Fix f = {x∈ Dom f | f(x) = x} ⊂ Dom f ⋂ Im f

A function f is called idempotent if, equivalently,

Im f ⊂ Dom f ∧ f⚬f = f
Im f = Fix f

Monotone, antitone, strictly monotone functions

• monotone if ∀x,y∈E, x ≤ y ⇒ f(x) ≤ f(y)
• antitone if ∀x,y∈E, x ≤ y ⇒ f(y) ≤ f(x)
• strictly monotone if ∀x,y∈E, x ≤ y ⇔ f(x) ≤ f(y)
• strictly antitone if ∀x,y∈E, x ≤ y ⇔ f(y) ≤ f(x).

Order between functions, extensive functions

Galois connections : definition and examples

Gal(E,F) = {(⊥,⊤) ∈ F^E×E^F|∀x∈E, ∀y∈F, x ≤_E⊤(y) ⇔ y ≤_F ⊥(x)} = ^tGal(F,E)
Gal⁺(E,F) = {(u,v) ∈ F^E×E^F|∀x∈E, ∀y∈F, x ≤_E v(y) ⇔ u(x) ≤_F y} = Gal(E,F⁻)

Galois connections between powersets. Any R ⊂ X×Y defines (⊥,⊤) ∈ Gal(℘(X),℘(Y)) by

∀A⊂X, ⊥(A) = {y∈Y | ∀x∈A, x R y} = ∩_x∈A R⃗(x)
∀B⊂Y, ⊤(B) = {x∈X | ∀y∈B, x R y} = {x∈X | B ⊂ R⃗(x)}

if (⊥,⊤) ∈ Gal(℘(X),℘(Y)) and R = ∐_x∈X ⊥({x}) then
∀B⊂Y, ∀x∈X, x ∈ ⊤(B) ⇔ B ⊂ ⊥({x}) = R⃗(x).∎

∀A⊂X, u(A) = {y∈Y | ∃x∈A, x R y} = ⋃_x∈A R⃗(x)
∀B⊂Y, v(B) = {x∈X | R⃗(x) ⊂ B}.

(A ↦ f[A], B ↦ f_⋆(B)) ∈ Gal⁺(℘(X),℘(Y))

Properties of Galois connections

1. Cl and Cl′ are extensive.
2. ⊥ and ⊤ are antitone
3. Cl and Cl′ are monotone
4. ⊥⚬⊤⚬⊥ = ⊥, and similarly ⊤⚬⊥⚬⊤ = ⊤
5. Im ⊤ = Im Cl = Fix Cl, called the set of closed elements of E.
6. Cl⚬Cl = Cl
7. (⊥ strictly antitone) ⇔ Inj ⊥ ⇔ Cl = Id_E ⇔ Im ⊤ = E
8. ∀x,x′∈E, ⊥(x) ≤ ⊥(x′) ⇔ (Im⊤∩ ≤⃗(x) ⊂ ≤⃗(x′)).
9. Denoting K = Im ⊤, ⊤⚬⊥_|K = Id_K, thus ⊥_|K is strictly antitone and ⊥_|K⁻¹ = ⊤_|Im⊥.

Remark. Properties 1. and 2. conversely imply that (⊥,⊤) ∈ Gal(E,F).

Analogues of the above properties for monotone Galois connections are obtained by reversing the order in F:
If (u,v) ∈ Gal⁺(E,F) then u and v are monotone, v⚬u is extensive and u⚬v ≤ Id_F.

Characterization of closures

1. There exists a set F and an (u,v) ∈ Gal(E,F) or Gal⁺(E,F) such that v⚬u=f
2. f is monotone, idempotent and extensive
3. ∀x∈E, ∀y∈ Im f, x ≤ y ⇔ f(x) ≤ y, i.e. (f, Id_K) ∈ Gal⁺(E,K) where K = Im f

Notes:

• 2.⇒3. is a particular case of the remark: f⚬f = f ⇒ f⚬Id_K ≤ Id_K (extensivity of f⚬Id_K in K⁻).
• ∀K⊂E, ∀f∈K^E, (f,Id_K) ∈ Gal⁺(E,K) ⇒ Im f = K from the above 7. with Id_K injective.

More on Galois connections

3.2. Relational systems and concrete categories

• Eⁿ = E×...×E = E^V_n, set of all n-tuples of elements of E (n-ary product or exponentiation).
• Rel_E⁽ⁿ⁾ = ℘(Eⁿ), set of all n-ary relations in E
• Op_E⁽ⁿ⁾ = E^En, set of all n-ary operations in E.

Languages

^LE = ∐_s∈L E^n_s

A relational language is a language L of relation symbols, where each s∈L aims to be interpreted in any L-system E as an n_s-ary relation. These form a family called an L-structure on E, element of

∏_s∈L ℘(E^n_s) ⥬ ℘(^LE).

^LId_E = Id_^LE
∀_fncf,g, Im f ⊂ Dom g ⇒ ^L(g⚬f) = ^Lg ⚬ ^Lf
Inj f ⇒ Inj ^Lf
Im ^Lf = ^LIm f

∀A⊂E, ^Lf[^LA] = ^L(f[A])
∀B⊂F, ^Lf_⋆(^LB) = ^L(f_⋆(B))

Relational systems

The case of an algebraic language, whose symbols aim to represent operations, will be studied in 3.3.

s_E = {x∈E^n_s | s(x)} = E⃗(s)
E = {(s,x)∈^LE | s(x)} = ∐_s∈L s_E.

Morphisms

f ∈ Mor_L(E,F) ⇔ ∀(s,x)∈E, (s,f⚬x)∈F
⇔ (∀s∈L,∀x∈E^n_s, s(x) ⇒ s(f⚬x))
⇔ ^Lf[E] ⊂ F ⇔ E ⊂ (^Lf)_⋆F.

Concrete categories

• a class of sets called objects ;
• a class of functions called morphisms; then for any objects E,F, we define
  Mor(E,F) = {f∈F^E | f is a morphism}

• Every morphism belongs to some Mor(E,F), i.e. its domain is an object and its image is included in an object (in practice, images of morphisms will be objects too);
• For any object E, Id_E ∈ Mor(E,E) ;
• Any composite of morphisms is a morphism: for any 3 objects E,F,G , ∀f ∈ Mor(E,F), ∀g∈Mor(F,G), g⚬f ∈ Mor(E,G).

A category is small if its class of objects is a set.

Preservation of some defined structures

• Substituting arguments of a s∈L by a map σ to n' other variables (∀E,∀x∈E^n', s'(x) ⇔ s(x⚬σ)), works :
  s'(x) ⇒ s(x⚬σ) ⇒ s(f⚬x⚬σ) ⇒ s'(f⚬x).
• ∀s,s'∈L, n_s = n_s' ⇒ ∀x∈E^n_s, (s(x) ∧ s'(x)) ⇒ (s(f⚬x) ∧ s'(f⚬x))
• ∀s,s'∈L, n_s = n_s' ⇒ ∀x∈E^n_s, (s(x) ∨ s'(x)) ⇒ (s(f⚬x) ∨ s'(f⚬x))
• For 0 and 1 it is trivial
  
• ∀x,y∈E, x = y ⇒ f(x) = f(y)
• ∀x∈E^n_s,(∃y∈E, s(x,y)) ⇒ (∃z=f(y)∈F, s(f⚬x, z)) ∎

• In the nullary case: for any f ∈ Mor_L(E,F), if a ground formula with language L using only these logical symbols is true in E, then it is also true in F.
• The graph of any operation defined by a term is expressible in this way, and thus also preserved. But the proofs given by the above means are only a schema of one proof for each "small" (concretely written) term. A single proof for the full range of all terms will be given in 4.1.

• Any union of a family of preserved structures in a concrete category is a preserved structure.
• Any intersection of a family of preserved structures is also a preserved structure.

Categories of typed systems

• As a tuple or family of functions (f_i)_i∈τ, where ∀i∈τ, f_i : E_i → F_i ;
• As a τ-morphism f : E → F seeing τ as a list of unary relation symbols (like for the use of classes as notions in set theory), i.e. a function such that t_F ⚬ f = t_E.

3.3. Algebras

Algebras and their morphisms

s_E : E^n_s → E
φ_E = ∐_s∈L s_E : ^LE → E

Mor_L(E,F) = {f∈F^E | ∀(s,x)∈^LE, s_F(f⚬x) = f(s_E(x))} = {f∈F^E| φ_F⚬^Lf = f⚬φ_E}.

Algebras as relational systems

Let L' be the copy of L as a relational language, where the copy s'∈L' of each s∈L has increased arity n_s' = n_s+1, so that

^L'E ⇌ ∐_s∈L E^n_s×E ⇌ ^LE × E = {((s,x),y) | s∈L ∧ x∈E^n_s ∧ y∈E}.
∐_s∈L Gr s_E ⇌ Gr φ_E ⊂ ^LE × E

Qualities of systems with algebraic languages

• Functional or a partial algebra if E is functional (graph of a function from a subset of ^LE);
• Serial if Dom E = ^LE;
• Algebraic if a serial partial algebra, i.e. essentially an algebra (E, φ_E) by E = Gr φ_E ;
• Injective if ^tE is functional ;
• Surjective if Im E = E.

∀f∈F^E, (∀(x,y)∈Gr φ_E, (^Lf(x),f(y)) ∈ Gr φ_F) ⇔ (∀x∈^LE, φ_F(^Lf(x)) = f(φ_E(x))).

Mor_L(E,F) = {f∈F^E | Im f⚬φ_E ⊂ Dom ψ_F ∧ ^Lf_{|Dom φE} = ψ_F⚬f⚬φ_E}
Mor_L(F,E) = {f∈E^F | Im ^Lf⚬ψ_F ⊂ Dom φ_E ∧ φ_E⚬^Lf⚬ψ_F = f_{|Dom ψF}}

• If F is functional then E is functional;
• If F is injective then E is injective.

• If E is serial then F is serial;
• If E is surjective then F is surjective.

Stable subsets and subalgebras

Sub_L E = {A⊂E | E^⋆(^LA) ⊂ A} = {A⊂E | ∀((s,x),y)∈E, Im x⊂A ⇒ y∈A}.

Diverse properties of stability

Intersections of stable subsets. ∀X ⊂ Sub_LE, ⋂X ∈ Sub_L E where ⋂X ≝ {x∈E | ∀B∈X, x∈B}.

Other way: E^⋆(^L⋂X) = E^⋆(⋂_B∈X ^LB) ⊂ ⋂_B∈X E^⋆(^LB) ⊂ ⋂X.

〈A〉_L = {x∈E | ∀B∈ Sub_LE, A⊂B ⇒ x∈B} = ⋂{B∈ Sub_LE | A⊂B} ∈ Sub_LE

∀X⊂E, ∀Y⊂Sub_LE, X ⊂ ⋂Y ⇔ (∀B∈Y, X⊂B) ⇔ Y ⊂ {B∈ Sub_LE | X⊂B}.

Stability of equalizers. The equalizer Eq(f, g) = {x∈E | f(x) = g(x)} of any two L-morphisms f,g∈Mor_L(E,F) from an L-system E to a partial L-algebra F, is L-stable.

Minimal systems

Min_LE = 〈∅〉_L,E = ⋂ Sub_L E ∈ Sub_L E.

An L-system E is minimal when E = Min_L E, or equivalently Sub_LE = {E}.

For any L-system E and any A⊂E,

• ∀B∈ Sub_LE, A ∩ B ∈ Sub_L A
• Min_L A ⊂ Min_L E
• A is minimal ⇒ A ⊂ Min_L E
• A ∈ Sub_LE ⇒ E^⋆(^LA) ∈ Sub_LE ∩ ℘(A) = Sub_LA
• A ∈ Sub_LE ⇒ Min_LA = Min_LE
• A = Min_LE ⇔ (A is minimal ∧ A∈ Sub_LE) ⇒ E^⋆(^LA) = A
  In particular, any minimal system is surjective.
• 〈A〉_L = Min_L∪A E where A is seen as a set of constants.
• A ∪ E^⋆(^LA) ⊂ 〈A〉_L = A ∪ E^⋆(^L〈A〉_L)
• E_⋆A ⊂ ^LA ⇒ Min_L A = A ∩ Min_L E

Cantor-Bernstein theorem

Proof. 〈∁_E Im g〉_{g⚬f} = A = (∁_E Im g) ∪ g[f[A]] ⇒ ∁_E A = g[∁_F f[A]] ⇒ (E ∋ x ↦ x∈A ? f(x) : g^-1(x)) : E ↔ F ∎

3.4. Special morphisms

Isomorphisms, endomorphisms, automorphisms.

f ∈Mor(E,F) ∧ (f : E ↔ F) ∧ f ^-1∈Mor(F,E).

Two objects E, F are said to be isomorphic (to each other) if there exists an isomorphism between them. This is an equivalence predicate, i.e. it works as an equivalence relation on the class of objects in this category.
The isomorphism class of an object in a category, is the class of all objects which are isomorphic to it. Then an isomorphism class of objects is a class of objects which is the isomorphism class of some object in it (independently of the choice).

An endomorphism of an object E, is an element of Mor(E,E) = End(E). It is called non-trivial if it differs from Id_E.

An automorphism of E is an isomorphism of E to itself:

Automorphism ⇔ (Endomorphism ∧ Isomorphism)

Embeddings

∀x∈E^n_r, x∈r_E ⇔ f⚬x∈r_F.

For any subset A⊂F of a relational system F, we define its structure by restriction : A = F ∩ ^LA. It is the only structure on A such that, equivalently

• Id_A : A ↪ F is an embedding ;
• For any system E, Mor_L(E,A) = {h∈Mor_L(E,F) | Im h ⊂ A}

From Id_A∈Mor_L(A,F), we deduce for all systems N, Mor_L(A,N) ⊂ {g_|A | g∈Mor_L(F,N)} but generally without equality (details in 3.8).

Elementary embeddings

Isomorphism ⇒ Elementary embedding ⇒ Embedding ⇒ Injective morphism

Elementary equivalence. Different systems are said to be elementarily equivalent, if they have all the same properties.
The existence of an elementary embedding between systems implies that they are elementarily equivalent.

Non-surjective elementary embeddings, and more generally the diversity of elementarily equivalent but non-isomorphic systems, play special roles in high-level studies of the foundations of mathematics, as we shall see with Skolem's paradox and non-standard models of arithmetic. However they are ignored by the most usual practice of mathematics, because of how far-fetched (hard to find) they usually are.
Here is an aspect of such "difficulties" which is very easy to prove. If an elementary embedding f : E ↪ E is invariant then it is surjective, thus an automorphism :

Im f is also invariant (defined by ∃y∈E, f(y) = x)
∀x∈E, x ∈ Im f ⇔ f(x) ∈ Im f
Im f = E. ∎

The Galois connection (End, Inv)

∀M⊂E^E, ∀F⊂℘(E), M ⊂ End_FE ⇔ (∀f∈M, ∀A∈F, f[A] ⊂ A) ⇔ F ⊂ Sub_ME.

Inv = ⊓_n∈ℕ Inv⁽ⁿ⁾ : ℘(E^E) → ∏_n∈ℕ ℘(Rel_E⁽ⁿ⁾) ⥬ ℘(Rel_E).

Morphisms of algebras

∀x∈^LE, ∀y∈F, (^Lf(x),y) ∈ F ⇒ ∃z∈E, f(z) = y ∧ (x,z)∈E.

(φ_F⚬^Lf = f⚬φ_E ∧ Inj f) ⇒ ∀(x,y)∈^LE×E, f(y) = φ_F(^Lf(x)) ⇒ y = φ_E(x).

Conversely, if f is a pre-embedding and (E is surjective, or some s_E is injective for one of its arguments) then f is injective.
Bijective morphisms between algebras are isomorphisms. This can also be deduced by

(^Lf)^-1 = ^L(f ^-1) ∴ φ_E ⚬ ^Lf ^-1 = f ^-1 ⚬ f ⚬ φ_E ⚬ ^Lf ^-1 = f ^-1 ⚬ φ_F ⚬ ^Lf ⚬ ^Lf ^-1 = f ^-1 ⚬ φ_F.

Images and preimages with algebraic languages

∀A⊂E, E^⋆(^LA) ⊂ A ⇒ F^⋆(^L(f[A])) ⊂ f[A]
∀A∈ Sub_LE, f[A] ∈ Sub_LF

Images of algebras. For any two L-algebras E,F, ∀f ∈Mor_L(E,F), Im f ∈ Sub_LF.

Preimages of stable subsets. ∀f∈Mor_L(E,F), ∀B∈ Sub_LF, f_⋆(B) ∈ Sub_L E.

Proposition. For any L-systems E, F, ∀f ∈Mor_L(E,F),

1. f [Min_LE] is minimal (thus f [Min_LE] ⊂ Min_LF).
2. ∀A⊂E, f[〈A〉_L] = 〈f[A]〉_{L,f[〈A〉L]} ⊂ 〈f[A]〉_L

Thus when f is full (in particular when E, F are algebras) we have equalities:

f [Min_LE] = Min_LF
∀A⊂E, f [〈A〉_L] = 〈f [A]〉_L.

3.5. Monoids

Transformations monoids

• Id_E ∈ M
  
• ∀f,g∈M, g⚬f ∈ M.
  

Monoids

• Two operation symbols
  • a constant symbol e of "identity"
  • a binary operation • of "composition"
• Axioms
  • Associativity : ∀x,y,z, x•(y•z) = (x•y)•z so that either term can be written x•y•z
  • Identity axiom : ∀x, x•e = x = e•x

• A left identity of a binary operation • is an element e such that ∀x, e • x = x ;
• A right identity of • is an element e' such that ∀x, x•e' = x.

From any associative operation on a set E we can form a monoid by adding the identity e as an extra element, E' = E ⊔ {e}, to which the interpretation of • is extended as determined by the identity axiom. This preserves associativity; but any identity element from E loses its status of identity in E'.

Cancellativity

∀y,z, x•y = x•z ⇒ y = z.

∀y,z, y•x = z•x ⇒ y = z.

a•e' = a = a•e ⇒ e' = e.

Other concepts of submonoids and morphisms

• its image is a monoid (A,a,▪) where A = Im f and a = f(e)
• f is a morphism of monoid from M to this monoid A.

f ∈ Mor_{e}(M,X) ⇔ a = e' ⇔ e' ∈ A ⇔ A ∈ Sub_{{e, ▪}} X

Anti-morphisms. The opposite of a monoid is the monoid with the same base set but where composition is replaced by its transpose. An anti-morphism from (M,e,•) to (X,e',▪) is a morphism f from one monoid to the opposite of the other (or equivalently vice-versa):

f(e) = e'
∀a,b∈M, f(a•b) = f(b)▪f(a)

Commutants and centralizers

C(A) = {x∈E|∀y∈A, x•y = y•x}.

∀A,B⊂E, B⊂C(A) ⇔ A⊂C(B).

If • is associative then ∀A⊂E, C(A) ∈ Sub_{•}F.
Proof: ∀x,y∈C(A), (∀z∈A, x•y•z = x•z•y = z•x•y) ∴ x•y∈C(A).

∀A⊂M, C_M(A) = M ∩ End_A X

A binary operation • in a set E, is called commutative when • = ^t•, i.e. C(E) = E.

If A⊂C(A) and 〈A〉_{•} = E then • is commutative.
Proof: A⊂C(A)∈ Sub_{•}F ⇒ E = C(A) ⇒ A⊂C(E) ∈ Sub_{•}F ⇒ C(E) = E.∎

Categories

• the class of its "objects" ; the category is small if this class is a set;
• to any objects E,F is given a set Mor(E,F) of «morphisms from E to F»; these are usually regarded as pairwise disjoint;
• to any object E is given a constant symbol 1_E ∈ Mor(E,E);
• to any triple of objects E,F,G is given a "composition" operation (abusively all denoted by the same symbol)

∘ : Mor(F,G)×Mor(E,F) → Mor(E,G)

• ∀_C E,F, ∀x∈Mor(E,F), x∘1_E = x = 1_F∘x
• ∀_C E,F,G,H, ∀x∈Mor(E,F), ∀y∈Mor(F,G),∀z∈Mor(G,H), (z∘y)∘x = z∘(y∘x) ∈ Mor(E,H)

; = ^t∘ : Mor(E,F)×Mor(F,G) → Mor(E,G)
x;y = y∘x

The concept of opposite category is defined similarly to opposite monoids, as re-reading the category with sides reversed, the Mor(E,F) of the one serving as the Mor(F,E) of the other. For any concept relative to a given category, its dual will mean the similar concept following the same definition with sides reversed, which amounts to applying this concept to the opposite category; it will usually be called by appending the prefix co- to the concept's name.

3.6. Actions of monoids and categories

Actions of monoids

• ∀x∈X, e⋅x = x
• ∀a,b∈M, ∀x∈X, (a•b)⋅x = a⋅(b⋅x)

• Any monoid naturally acts on itself by its composition operation.
• Any transformation monoid (or other acting monoid) M on a set E, also acts by restriction on any M-stable subset A⊂E (preserved unary predicate in the concrete category M with object E).
• In particular, the monoid of endomorphisms of any typed system E = ∐_i∈I E_i, acts on every type E_i it contains.

Acts as algebraic structures

⋅⃖_x(e) = x ⇔ e⋅x = x
⋅⃖_x ∈ Mor_M(M,X) ⇔ ∀a,b∈M, (a•b)⋅x = a⋅(b⋅x)
•⃖_e = Id_M ⇔ (∀a∈M, a•e = a) ⇒ ∀g∈ Mor_M(M,X), ⋅⃖_g(e) = g

∀x∈X, ∀g∈X^M, g = ⋅⃖_x ⇔ (g ∈ Mor_M(M,X) ∧ g(e) = x)

(Id_M ∈ Mor_M(M,M) ∧ Id_M(e) = e) ∴ •⃖_e = Id_M

Effectiveness and free elements

∀a,b∈M, (∀x∈X, a·x = b·x) ⇒ a = b

An element x∈X of an M-set (X, ·), is free if ⋅⃖_x : M ↪ X. The existence of a free element implies the effectiveness of the action :

(∃x∈X, ∀a≠b∈M, a·x ≠ b·x) ⇒ (∀a≠b∈M, ∃x∈X, a·x ≠ b·x)
Inj(π_x ⚬ ⋅⃗ ) ⇒ Inj ⋅⃗

Trajectories

〈{x}〉_M = {a⋅x | a∈M} = Im ⋅⃖_x ⊂ E

Right actions

• ∀x∈X, x⋅e = x
• ∀a,b∈M, ∀x∈X, (x⋅a)⋅b = x ⋅(a•b)

The commutation of 2 submonoids of X^X looks like an associativity formula when written as acting by opposite sides on X: a∈M acting on X commutes with b∈N co-acting on X when

∀x∈X, (a⋅x)⋅b = a⋅(x⋅b)

Actions of categories

∀_CX, (1_X)^α = Id_X^α
∀_CX,Y,Z, ∀f∈ Mor(X,Y), ∀g∈ Mor(Y,Z), (g∘f)^α = g^α⚬f^α

Mor(X^α, Y^α) = {f^α | f∈Mor(X,Y)}

∀_CX, (1_X)_β = Id_Xβ
∀_CX,Y,Z, ∀f∈ Mor(X,Y), ∀g∈ Mor(Y,Z), (g∘f)_β = f_β⚬g_β

Some constructions of actions

∀_CX, X^β ⊂ X^α
∀_CX,Y, ∀f∈ Mor(X,Y), f^α[X^β] ⊂ Y^β ∧ f^β = f^α_|X^β.

∀_CX, X^(M) = Mor(M,X)
∀f∈Mor(X,Y), f^(M) = Hom(M, f) = ∘⃗(f)_|Mor(M,X) : X^(M) → Y^(M)

∀_CX, X_(M) = Mor(X,M)
∀f∈Mor(X,Y), f_(M) = Hom(f,M) = ∘⃖(f)_|Mor(Y,M) : Y_(M) → X_(M)

The axioms for monoids M and M-sets X can be read as contained in the axioms of categories. Namely, pick an object K of a category C, and let M = End(K). Then any object E defines an M-set X = K^(E) = E_(K). As actions by composition on opposite sides commute by associativity, morphisms in the co-acting category C_(K) preserve this M-structure :

∀f ∈Mor(E,F), f_(K) ∈ Mor_M(F_(K), E_(K))
∀x∈X=Mor(E,K), x_(K) = ⋅⃖_x ∈ Mor_M(K_(K), E_(K)).

Trajectories of tuples in concrete categories

Proof : ∀g∈Mor(E,F), ∀x∈s_E, ∃f∈Mor(K,E), (x = f⚬t ∧ g⚬f ∈ Mor(K,F)) ∴ g⚬x = g⚬f⚬t ∈ s_F.∎

3.7. Invertibility and groups

Permutation groups

∐_x∈E 〈{x}〉_M

While the concepts of full transformation monoid and symmetric group depend on the powerset, those of transformation monoid and permutation group do not use it, being expressed as first-order theories.

Inverses

y•x = e = x•z ⇒ y = y•x•z = z

x•y = y•x ⇔ x = y•x•z ⇔ z•x = x•z

Transpositions

∀x,y∈E, (x y)_E = (E ∋ z ↦ (z = x ? y : (z = y ? x : z))) = (y x)_E ∈ 𝔖_E

Groups

• The axiom that all elements are invertible, or
• The function symbol ^-1 of inversion, with the axiom ∀x, x•x^-1 = x^-1•x = e

• e is its own inverse.
• If x, y have inverses x^-1, y^-1, then x•y has inverse y^-1•x^-1.
• Any inverse x^-1 is invertible, with (x^-1)^-1 = x (inversion is an involutive transformation of any group).

In a group, the subgroup generated by a subset A coincides with the submonoid generated by A∪-A where -A = {x^-1|x∈A}. (It is stable by inversion because its definition is unchanged by inversion, which is involutive)

Special actions

If an M-set is both monogenic and generated by the set of its free elements, then it is regular (there is a free element that generates it).
Proof: as a generator is in the set generated by that of free elements, it must be in the trajectory of one of them, which is thus also generating.∎
(A monogenic action of a monoid may have free elements without being generated by them ; but if a monogenic action of a group has a free element then all its elements are free).

The trajectory Y of any element x of an M-set X is M-stable, and thus an M-set. It is generated by x, and stays so when replacing the language M by its image as a transformation monoid N ⊂ Y^Y.
Now if N is commutative (which is the case if M is commutative) then x is free for the action of N (thus Y is a regular N-set). The proof is easy and left as an exercise.

An action of a group G on a set X, is equivalently an action of monoid, or a group morphism from G to 𝔖_X.
As inversion is an anti-morphism, it switches any action ⋅ of G on X into a co-action ▪ by ∀x∈X, ∀g∈G, x▪g = g^-1⋅x.
If an action of group is monogenic then every element is generating; if it is regular then every element is regular.

The Galois connection (Aut, sInv)

∀P⊂𝔖_E, sInv P = Inv (P ∪ -P) = Inv (P) ∩ Inv(-P) ⊂ Rel_E
∀L⊂Rel_E, ∀P⊂ 𝔖_E, L ⊂ sInv P ⇔ P ⊂ Aut_L E.

Isomorphisms

Iso(E,F) = {f∈Mor(E,F) | ∃g∈Mor(F,E), g∘f = 1_E ∧ f∘g = 1_F)}

A groupoid is a category where all morphisms are invertible. Groups are the groupoids with only one object, and the monoid of endomorphisms of any object of a groupoid is a group.
Generalizing from monoids, the core of a category is the groupoid with the same objects and only accepting isomorphisms as morphisms.
An automorphism of an object E, is an isomorphism from E to itself. Their set Aut(E), core of End(E), is a group called the automorphism group of E.

3.8. Properties in categories

Monomorphisms, Epimorphisms

A morphism f∈Mor(E,F) is called monic, or a monomorphism, if all f^(X) are injective:

∀_CX, ∀g,h∈Mor(X,E), f∘g = f∘h ⇒ g = h.

Dually, a morphism f∈Mor(E,F) is called epic, or an epimorphism, if all f_(X) are injective :

∀_CX, ∀g,h∈Mor(F,X), f;g = f;h ⇒ g = h
∀_CX, f_(X) : X^(F) ↪ X^(E)
f_(C) : C^(F) ↪ C^(E).

Sections, retractions

1. ∃f∈Mor(E,F), f;g = 1_E
2. For any action α of C, g^α is surjective (Im g^α = E^α).
3. g^(E) is surjective, i.e. Im g^(E) = End(E).

Dually, f∈Mor(E,F) is a section (or section in F if the category is concrete), if, equivalently,

1. ∃g∈Mor(F,E), f;g = 1_E.
2. For any co-action β of C, f_β is surjective (Im f_β = E_β).
3. f_(E) is surjective, i.e. Im f_(E) = End(E).

• All actions of sections are injective; thus, all sections are monic;
• All co-actions of retractions are injective; thus, all retractions are epic.

Section ⇒ Injective morphism ⇒ Monomorphism
Retraction ⇒ Surjective morphism ⇒ Epimorphism

Modules

If b is an isomorphism then all objects are b-modules, i.e. b is an epic section, and

∀_CX, (b_(M)^-1 = b^-1_(M)) ∧ (b^{(M) -1} = b^{-1 (M)}).

Thus :

• If both X,Y are b-modules then all other objects are also b-modules ;
• Epic section ⇔ Isomorphism ⇔ Monic retraction ;
• If an element of a monoid is both left invertible and right cancellative, then it is invertible.

Examples of modules

An important kind of examples is when b is bijective (and thus epic), in the category of relational systems for a given language L. To simplify, let b be the identity Id_X into Y with larger structure Y = X ∪ Z.

For example, given a binary symbol r∈L, the properties of reflexivity, symmetry and transitivity of the interpretation of r in a system M, are respectively expressible as M being a Re-module, a Sy-module and a Tr-module, where the morphisms Re, Sy and Tr are respectively defined by

• (Re) : X = {0}, X = ∅, Z = {(r,(0,0))}
• (Sy) : X = {0,1}, X = {(r,(0,1))}, Z = {(r,(1,0))}
• (Tr) : X = {0,1,2}, X = {(r,(0,1)), (r,(1,2))}, Z = {(r,(0,2))}

So formalized, this general case of a bijective b can be thought of as giving Z the role of a set of L-typed X-ary algebraic symbols, which for every set M gives to ^LM the Z-structure {((s,^Lu_|X),^Lu(s)) | (s,u) ∈ Z×M^X}, so that

(M, M) is a b-module ⇔ M ∈ Sub_Z ^LM.

Subobjects

• The anti-preservation of ⚬ by C_(X) is written Hom_F(f, X) ⚬ Hom_G(g, X) = Hom_G(g∘f, X).
• f∈Mor(E,F) is F-epic, or an F-epimorphism, if all Hom_F(f,X) are injective.

Let us analyze the concept of an object S being included in an object E of a concrete category, to re-express it as a separate object X with an isomorphism to S (by which references to target sets of morphisms could be omitted). This concept has 2 variants.

The "weak" version is the concept of subobject (by the standard terminology), applicable to any abstract category. It amounts to only requiring the inclusion morphism of the subobject S in E (usually Id_S : S ↪ E in concrete categories) to be monic, and not even necessarily injective.

Namely, a subobject of E is formalized by a presentation in the form (X,u) where u ∈ Mor(X,E) is monic (indirect description of Im u seen as isomorphic to X, thus defining the morphisms to and from Im u as copied from those X, but this direct meaning is lost in abstract categories).
The class of presentations (X,u) of subobjects of an object E, is meta-preordered by

(X, u) ⊆ (Y, v) ⇔ ∃ϕ∈Mor(X,Y), u = v∘ϕ

∀g,h∈Mor(Z,X), ϕ∘g = ϕ∘h ⇒ u∘g = v∘ϕ∘g = v∘ϕ∘h = u∘h ⇒ g = h.

(X, u) ≡ (Y, v) ⇔ ((X, u) ⊆ (Y, v) ∧ (Y, v) ⊆ (X, u)) ⇔ (∃ϕ∈Iso(X,Y) | u = v∘ϕ).

The "strong" version requires u to be an embedding. This concept of embedding, first introduced for relational systems in 3.4, will be generalized to any concrete category in 3.9 (while expressible classes of monomorphisms in abstract categories which may play a similar role are not equivalent).

Representation theorem

Theorem. Any small category is isomorphic to that of all morphisms in a family of typed algebras.

• As a set T of types, we can take a copy of the set of objects, but one type per isomorphism class suffices.
• Each object E is interpreted as a typed set ∐_t∈T E^(t).
• L = ∐_t,t'∈T Mor(t',t) seeing Mor(t',t) as a set of functions symbols from t to t', co-acting on each E.

In particular, any monoid is isomorphic to End_L X for an algebra X on some language L of function symbols; any group is isomorphic to an automorphism group of such an algebra.

3.9. Initial and final objects

For any initial objects X, Y, ∃f∈Mor(X,Y), ∃g∈Mor(Y,X), {g∘f, 1_X} ⊂ Mor(X,X) ∴ g∘f = 1_X.
Similarly, f∘g = 1_Y. Thus f is an isomorphism, unique as ∃!:Mor(X,Y). ∎

• The empty set where Boolean constants are false is the initial system ;
• Final systems (with a single type) are the singletons where all relations are constantly true;
• Final multi-type systems are made of one singleton per type.

• Objects are all (X,ϕ) where X is a set and ϕ: X×A→B ;
• Mor((X,ϕ),(Y,ϕ') = {f∈Y^X | ∀x∈X,∀a∈A, ϕ(x,a) = ϕ'(f(x),a)}.

Eggs

Generalizing the concept of regular element, let us call egg of an acting category C^α, any (M,e) where M is an object and e ∈ M^α, such that

∀_CE, (Mor(M,E) ∋ f ↦ f^α(e)) : E^(M) ↔ E^α.

• C^(M) is a copy of C^α, with correspondence depending on e.
• (M^α,e) is an egg of |C^α|.

• Objects are all data (E,x) of an object E of C and x ∈ E^α
• Mor((E,x),(F,y)) = {f∈Mor(E,F) | f^α(x) = y}

Exercise. Consider the category of sets and their functions acting by direct images on the powersets of its objects (Set^⋆). Does it have an egg ?
Similarly, consider its co-action on these powersets by preimages (Set_⋆). Does it have a co-egg ?
Hint : use the numbers of elements of involved finite sets.

Embeddings in concrete categories

∀_CX, Mor(X,E) = {g∈E^X | f⚬g ∈ Mor(X,F)}

∀_CX, X_(f) = {g∈E^X | f⚬g ∈ Mor(X,F)}.

∀_CX, Mor(X,E) = {f ^-1⚬h | h ∈ Mor(X,F) ∧ Im h ⊂ Im f}
∀_CX, {h ∈ Mor(X,F) | Im h ⊂ Im f} = {f⚬g | g∈Mor(X,E)}

∀_CX, X_(A) = {g∈X_(F) | Im g ⊂ A}

∀_CX, ∀g∈Mor(X,F), Im g ⊂ Im f ⇒ ∃!ϕ∈Mor(X,E), f ⚬ ϕ = g

The diverse properties of a morphism f∈Mor(E,F) are related as follows.

1. If Im f ⊂ A ⊂ F then
   ((E,f) is co-egg of C_(A)) ⇔ (f is a quasi-embedding and ∀g∈Mor(E,F), Im g ⊂ A ⇒ Im g ⊂ Im f)
2. Injection ⇒ (pre-embedding ⇔ quasi-embedding)
3. Quasi-embedding ⇒ monomorphism
4. (Monomorphism ∧ pre-embedding) ⇒ injection
5. Section ⇒ embedding

4. ∀x∈E, ϕ = (E∋y ↦ (f(y) = f(x) ? x : y)) ⇒ f ⚬ ϕ = f ⇒ (ϕ ∈ End E ∴ ϕ = Id_E).
5. ∃h∈Mor(F,E), h ⚬ f = 1_E ∴ ∀g∈E^X, f ⚬ g ∈ Mor(X,F) ⇒ g = h ⚬ f ⚬ g ∈ Mor(X,E).∎

Proof.

∃h∈X^A, g⚬h = Id_A ∴ g⚬h⚬f = f ∈ Mor(E,F) ∴ h⚬f ∈ Mor(E,X)
∃ϕ∈Mor(X,E), f⚬ϕ = g ∴ f⚬ϕ⚬h⚬f = g⚬h⚬f = f ∴ ϕ⚬h⚬f = Id_E.∎

If a subset A of an object F is the image of an embedding f∈Mor(E,F), this gives A the status of an embedded subobject (A, Id_A) ≡ (E,f). (For a quasi-embedding we can do similarly with a copy of E attached to A and thought of as independent of E).
Then for any object X, we can define Mor(X,A) from Mor(X,F) directly as X_(A), while Mor(A,X) is only directly defined from Mor(F,X) if f is a section, as {g_|A | g∈Mor(F,X)}.

Submodules

∀g∈Mor(Y,F), Im g⚬b ⊂ A ⇒ Im g ⊂ A.

1. If f is a pre-embedding and b is bijective then E is a b-module;
2. If f is a quasi-embedding and Im f is b-stable then (E,f) is a b-submodule.

1. ∀u∈Mor(X,E), f⚬u⚬b^-1 ∈ Mor(Y,F) ∴ u⚬b^-1∈Mor(Y,E).
2. ∀u∈Mor(X,E), (∃!g∈Mor(Y,F), g⚬b = f⚬u ∴ Im g ⊂ Im f)
   ∴ (∃!h∈Mor(Y,E), f⚬h⚬b = f⚬u) ∴ (∃!h∈Mor(Y,E), h⚬b = u).∎

3.10. Products of systems

Products of actions

∀_CX, X^β = ∏_i∈I X^α_i
∀_CX,Y, ∀f∈ Mor(X,Y), f ^β = ⨉_i∈I f ^α_i = ⊓_i∈I f ^α_i ⚬ π_i
∀x∈X^β, ∀y∈Y^β, f ^β(x) = y ⇔ ∀i∈I, f ^α_i(x_i) = y_i

Products in categories

∀_CF, ⊓_i∈I π_i^(F) : P^(F) ↔ ∏_i∈I E_i^(F)

The product in the category of sets, coincides with the product of sets (⊓ : ∏_i∈I E_i^F ⥬ P^F).

Products in concrete categories

∐_t∈τ ∏_i∈I E_t,i.

On the other hand, if the product as sets P = ∏_i∈I E_i of objects in a concrete category C is otherwise given a role of object, then the condition for it to serve as the product in C is that

∀F, ⊓[Mor(F,P)] = ∏_i∈I Mor(F,E_i).

(π_i)_i∈I = ⊓ Id_P ∈ ⊓[Mor(P,P)] ⊂ ∏_i∈I Mor(P,E_i) ⇒ ∀i∈I, π_i ∈ Mor(P,E_i).
Conversely (simple reason) : ∀i∈I, π_i ∈ Mor(P,E_i) ⇒ ∀f∈Mor(F,P), π_i⚬f ∈ Mor(F,E_i).
Other presentation : ∀F, ⊓[Mor(F,P)] = Im ⊓_i∈I π_i^(F) ⊂ ∏_i∈I Mor(F,E_i). ∎

If C is a concrete category with products, the statement of (M,e) being an egg can be re-expressed as

∀_CE, ∃!f∈Mor(M,E^E), f(e) = Id_E.

Products of modules

(∀i∈I, ∃!g∈Mor(Y, E_i), g∘b = π_i∘f)
∴ ∃!h∈Mor(Y,P), ∀i∈I, π_i∘h∘b = π_i∘f.
By Inj ⊓_i∈I π_i^(X) we conclude ∃!h∈Mor(Y,P), h∘b = f. ∎

∃!h∈Mor(Y, ^C∏_Mor(X,M) M), ∀u∈Mor(X,M), π_u∘h∘b = u.

∀x∈X, h(b(x)) = π_x|Mor(X,M)

Products of relational systems

P = ⋂_i∈I ^Lπ_i⋆(E_i) = ∐_s∈L ⊓[ ∏_i∈I s_i]

s_G = {x⊓y | x∈s_E ∧ y∈s_F} = {z∈G^n_s | π₀⚬z ∈s_E ∧ π₁⚬z ∈s_F}

f ∈ Mor_L(F,P) ⇔ ^Lf[F] ⊂ P ⇔ ∀i∈I, ^Lf[F] ⊂ ^Lπ_i⋆(E_i)
⇔ ∀i∈I, f_i ∈ Mor_L(F,E_i) ⇔ ⊓f ∈ ∏_i∈I Mor_L(F,E_i)

Products of algebras

(∀i∈I, π_i ∈ Mor_L(P,E_i)) ⇔ (∀i∈I, φ_i⚬^Lπ_i = π_i⚬φ_P) ⇔ φ_P = ⊓_i∈I φ_i⚬^Lπ_i

f ∈ Mor_L(F,P) ⇔ φ_P⚬^Lf = f⚬φ_F ⇔ ∀i∈I, φ_i⚬^Lf_i = φ_i⚬^Lπ_i⚬^Lf = f_i⚬φ_F
⇔ ∀i∈I, f_i ∈ Mor_L(F,E_i) ⇔ ⊓f ∈ ∏_i∈I Mor_L(F,E_i)

∀(x,y)∈^LP×P, y = φ_P(x) ⇔ ∀i∈I, y_i = φ_i(^Lπ_i(x))

^LP∋(s,x) ↦ s_E ⚬ ⊓x

Among systems, aside the case of algebras, any product of partial algebras is a partial algebra ; any product of injective systems is an injective system ; if AC_I holds then any product over I of serial systems is serial. But the surjectivity of a product system cannot be ensured unless it is achieved by a single symbol in L.

Intersections of subobjects

In any concrete category, any intersection of quasi-embedded subobjects is quasi-embedded, with image the greatest image of a morphism into the intersection of images of given subobjects.

Intersections of submodules

1. if F is a b-module ;
2. or, if I ≠ ∅ and b is epic.

Here is the proof for case 2 (a bit longer).
Let us denote (A,a) this intersection, with ϕ_i∈Mor(A,E_i) such that a = e_i∘ϕ_i for each i∈I.
Let u∈Mor(X,A). As b is epic we just need to prove (∃w∈Mor(Y,A), w∘b = u).
∃i∈I, ∃v∈Mor(Y,E_i), v∘b = ϕ_i∘u
∀j∈I, ∃!w∈Mor(Y,E_j), w∘b = ϕ_j∘u ∴ e_j∘w∘b = e_j∘ϕ_j∘u = a∘u = e_i∘ϕ_i∘u = e_i∘v∘b ∴ e_j∘w = e_i∘v.
As (A,a) is an intersection of the (E_j,e_j),
∃w∈Mor(Y,A), a∘w = e_i∘v ∴ a∘w∘b = e_i∘v∘b = e_i∘ϕ_i∘u = a∘u ∴ w∘b = u.∎

Intersections of subsystems

In any category of relational systems, subobjects of a system (F, F) are bijectively represented by its subsystems (E, E) in the sense that E⊂F ∧ E⊂F, with the monomorphism Id_E : E↪F. Then, the intersection of a family of subobjects (E_i, E_i) of (F, F) is represented by (⋂_I∈I E_i, ⋂_I∈I E_i) if we use the cateogry of all systems with a given language, or more generally if this system belongs to the considered category (which will be usually the case for categories defined as those of systems which are modules for some morphisms). This has two important special cases :

• Intersections of embedded subsystems (∀i∈I, E_i = F∩^LE_i): these are also embedded;
• Intersections of structures on the same system (∀i∈I, E_i = F).

As first noted in 2.9 for a binary relation symbol, an intersection of preimages of structures by some functions from a given set, coincides with the preimage of the product structure by the product function.

3.11. Basis

Eggs as acting monoids

Conversely, for any egg (M,e) of a concrete category, seeing M as a set of function symbols, there is a unique M-algebra structure on every object X satisfying both axioms of action and Mor_M(M,X) ⊂ Mor(M,X). This structure • on M makes (M,e,•) a monoid acting on all objects and ∀_CX,Y, Mor(X,Y) ⊂ Mor_M(X,Y), with equality for X = M.

In a concrete category with products, the definition of ⋅ can be written

⋅⃗ ∈ Mor(M,X^X) ∧ ⋅⃗(e) = Id_X.

This monoid (M,e,•) is essentially the opposite of the monoid End(M). Indeed

∀x,y∈M, •⃖_x ∈ End(M) ∧ •⃖_y ∈ End(M) ∧ •⃖_x ⚬ •⃖_y (e) = •⃖_x(y) = y•x.

Algebraic structures on modules

∀_CE, ∀u∈E^(V), ∃!f∈Mor(K,E), f⚬b = u

∀_CE, ∀u∈E^(V), φ⃖_E(u) = ℩{f∈Mor(K,E) | f⚬b = u} = b_(E)^-1(u)
∴ Mor(K,E) = {φ⃖_E(u) | u∈E^(V)}
∀_CE,F, Mor(E,F) ⊂ Mor_K(E,F)

As Mor(K,E) was expressed from φ_E, it will more precisely coincide with Mor_K(K,E), once K is given a proper K-structure. A minimal natural candidate is the trajectory of (b,s), which depends on End(K); but the choice of End(K) (fitting axioms of categories with fixed Mor(K,E)) will not matter.
Indeed, the smallest End(K) = {Id_K} gives to K its smallest trajectories-defined K-structure {((s,b),s) | s∈K}. This gives the greatest candidate Mor_K(K,E), equal to Mor(K,E); but the reverse inclusion Mor(K,E) ⊂ Mor_K(K,E) is another natural requirement (preservation of the K-structure). So the equality is necessary.

For φ_E to be algebraic, we shall assume V to be structureless, which means ∀E, E^(V) = E^V. For this to hold with K-morphisms (Mor_K(V,E) = E^V),

• The empty structure V = ∅ ensures it in all U in any case (then K ≠ ∅ ⇒ Mor_K(K,V) = ∅).
• For example V = {((π_x,Id_V),x) | x∈V} still gives Mor_K(V,E) = Mor(V,E) for b-modules E structured by trajectories ; precisely, Mor_K(V,E) = E^V when all π_x work in E as projections from E^V to E.

Basis

For any object K in C with a chosen basis b, and any possible symbol s of (preserved) V-ary operation in objects of C, the element s' = s_K(b) ∈ K is the unique element of K whose role of operation in all objects of C (trajectory of (b,s')) coincides with s. In particular for any (X,a) in B and any s∈X, this s' is the image of s by the unique morphism from (X,a) to (K,b).

Any operation s with lower arity also has a copy s' = s_K(x) for any injective substitution of variables x : V_ns ↪ V. Such a s' plays the same role as s with unused extra variables (∀_CE, ∀u∈E^V, s'_E(u) = s_E(u⚬x)), except for the inability of languages without constants to replace the role of a constant symbol to exclude ∅ (the empty algebra) from the considered category.

Coproducts

(K, j) : ^C∐_i∈I E_i

∀_CF, ⊓_i∈I j_{i (F)} : K_(F) ↔ ∏_i∈I E_{i (F)}

The category of sets has coproducts given by the disjoint union with its natural injections (∏_i∈I F^E_i ⥬ F^{∐_i∈I E_i}).
In categories of all relational systems with fixed language L, the coproduct is given by the disjoint union, with structure ⋃_i∈I ^Lj_i[E_i].

In other concrete categories, the underlying sets of coproducts may differ from disjoint unions, more often than those of products differ from the products of sets. The injectivity of each j_i often remains, but already fails in categories of partial algebras (4.2).

Basis and coproducts

(b is a basis of K^(M) in C^(M)) ⇔ (K, b) : ^C∐_x∈V M.

Products and coproducts have associativity properties like first seen with the product of sets : any product of products of objects, is naturally isomorphic to a simple product indexed by the disjoint union of indexing sets; and the same for coproducts.
In particular, a coproduct (K, j) : ^C∐_i∈I E_i of objects E_i with respective basis b_i : V_i → E_i, is an object with a basis indexed by the disjoint union ∐_i∈I V_i of these bases.

Equational systems

1. Any L-stable subset of an L-system is b-stable
2. Thus, any L-stable subset of a b-module is a b-module.
3. For any partial L-algebra E, Inj b_(E), i.e. ∀u∈E^V, !g∈Mor_L(K,E), g⚬b = u.

So, equational systems usually aim to distinguish among algebras (or partial algebras) E, those for which the injection b_(E) is also surjective. In many cases L has no projection symbol, obliging the chosen L-structure of V to be empty.

• If all symbols in L are n-ary, then V_n ↪ V_n ⊔ L with structure {((s, Id_Vn), s) | s ∈ L} is an equational system, whose modules among L-systems are the algebraic ones ;
• Any monoid K forms a K-equational system with V = {e}; then, the K-sets are the partial K-algebras which are b-modules. Indeed any b-module E gets a K-set structure included in E, then equality is deduced from the functionality of E.
• In the construction of algebraic structures on modules we described K as a K-equational system.
• The axiom of identity on a system is expressible as it being a module by an equational system with V a singleton, and K a pair (details are left as an exercise to the reader) ;
• Similarly for associativity with a 3-elements V and a 6-elements K.

3.12. Composition of relations

The category of relations

∀_grR,S, R;S = {(x₀,y₁) | (x,y)∈R×S ∧ x₁=y₀}
∀R⊂E×F, ∀S⊂F×G, R;S = {(x,z)∈E×G | ∃y∈F, xRy ∧ ySz}
= ∐_x∈E S^⋆R⃗(x)

∀A⊂E, (S⚬R)^⋆A = S^⋆(R^⋆A)
∀B⊂G, (R;S)_⋆B = R_⋆(S_⋆B)

＊×(R^⋆A) = (＊×A);R
(R_⋆B)×＊ = R;(B×＊)

(＊×A);R;(B×＊) = ∅ ⇔ A ∩ R_⋆(B) = ∅ ⇔ B ∩ R^⋆(A) = ∅
(∁_F⚬R^⋆, ∁_E⚬R_⋆) ∈ Gal(℘(E), ℘(F))
(R^⋆, ∁_E⚬R_⋆⚬∁_F) ∈ Gal⁺(℘(E), ℘(F))

Re-expressing properties of relations

R⊂S ⇒ R;T ⊂ S;T
R⊂S ⇒ T;R ⊂ T;S
(R∪S);T = R;T ∪ S;T
T;(R∪S) = T;R ∪ T;S

T;⋃_i∈I R_i = ⋃_i∈I T;R_i
T⚬⋃_i∈I R_i = ⋃_i∈I T⚬R_i

∀S⊂E×F, S ⊂ R;S
∀S⊂F×E, S ⊂ S;R

Generated preorders

A ∈ Sub_R E ⇔ R^⋆A ⊂ A ⇔ (∀(x,y)∈R, x∈A ⇒ y∈A) ⇔ ∁_E A ∈ Sub_^tR E

E ∋ z ↦ (z=x ? y : z).

∀x,y∈E, (x,y)∈Po(G⃗[K]) ⇔ (∀z∈K, zGx ⇒ zGy) ⇔ G⃖(x)⊂G⃖(y)

The closure Po(Sub_RE) of any R ⊂ E² is called the preorder on E generated by R; we shall write it ⌈R⌉.

Generated stable subsets

First proof. (∀i∈I, R^⋆A_i ⊂ A_i) ⇒ R^⋆⋃_i∈I A_i = ⋃_i∈I R^⋆A_i ⊂ ⋃_i∈I A_i ∎
Second proof. Use A ∈ Sub_R E ⇔ ∁_E A ∈ Sub_^tR E and the similar property with intersections.∎

Proof. First, when A is a singleton {x}, both definitions coincide :

∀y∈E, x⌈R⌉y ⇔ (∀A∈Sub_RE, x∈A ⇒ y∈A) ⇔ y∈〈{x}〉_R

From the end of 3.3 we get ∀A⊂E, 〈A〉_R = A ∪ R^⋆〈A〉_R.
By the faithfulness of the action, it can also be written

⌈R⌉ = 𝛿_E ∪ R⚬⌈R⌉

Transitive closure

T = R⚬⌈R⌉ = ⌈R⌉⚬R.

R⚬⌈R⌉ ⊂ ⌈R⌉ = ⌈R⌉⚬⌈R⌉ ∴ ⌈R⌉⚬R⚬⌈R⌉⚬R ⊂ ⌈R⌉⚬⌈R⌉⚬R = ⌈R⌉⚬R

Well-founded relations

Proposition. The transitive closure T of a well-founded relation R is well-founded.

∀A⊂E, A ⊂ T^⋆A ⇒ P^⋆A = A∪ T^⋆A = R^⋆P^⋆A = ∅ ∎

Proposition. If R is well-founded then ⌈R⌉ is an order, whose strict order coincides with the transitive closure of R.

Well-order

∀A⊂E, A = ∅ ∨ ∃!:A\(R^⋆A)

∀A⊂E, A = ∅ ∨ ∃!x∈A, A ⊂ ≤⃗(x)

Greatest and least elements

x :min A ⇔ (x∈A ∧ A ⊂ ≤⃗(x)) ⇔ (A∈ Dom min ∧ x = min A)
x :max A ⇔ (x∈A ∧ A ⊂ ≤⃖(x)) ⇔ (A∈ Dom max ∧ x = max A)

The successor function

xSy ⇔ y :min <⃗(x) ⇔ ≤⃗(y) = <⃗(x)

xSy ⇔ x :max <⃖(y) ⇔ ≤⃖(x) = <⃖(y)