Statement List for Metamath Proof Explorer - 3001-3100 - Page 31 of 107
| Type | Label | Description |
|---|
| Statement |
|---|
| |
| Theorem | ordtr1 3001 |
Transitive law for ordinal classes.
|
| ⊢
(Ord C → ((A ∈ B
⋀ B ∈ C) → A
∈ C)) |
| |
| Theorem | ordtr2 3002 |
Transitive law for ordinal classes.
|
| ⊢
((Ord A ⋀ Ord C) → ((A
⊆ B ⋀ B ∈ C)
→ A ∈ C)) |
| |
| Theorem | ontr1 3003 |
Transitive law for ordinal numbers. Theorem 7M(b) of [Enderton]
p. 192.
|
| ⊢
(C ∈ On → ((A ∈ B
⋀ B ∈ C) → A
∈ C)) |
| |
| Theorem | ontr2 3004 |
Transitive law for ordinal numbers. Exercise 3 of [TakeutiZaring]
p. 40.
|
| ⊢
((A ∈ On ⋀ C ∈ On) → ((A ⊆ B
⋀ B ∈ C) → A
∈ C)) |
| |
| Theorem | ordunidif 3005 |
The union of an ordinal stays the same if a subset equal to one of its
elements is removed.
|
| ⊢
((Ord A ⋀ B ∈ A)
→ ∪(A
∖ B) = ∪A) |
| |
| Theorem | onint 3006 |
The intersection (infimum) of a non-empty class of ordinal numbers
belongs to the class. Compare Exercise 4 of [TakeutiZaring] p. 45.
|
| ⊢
((A ⊆ On ⋀ A ≠ ∅) → ∩A ∈ A) |
| |
| Theorem | onint0 3007 |
The intersection of a class of ordinal numbers is zero iff the class
contains zero.
|
| ⊢
(A ⊆ On → (∩A = ∅ ↔
∅ ∈ A)) |
| |
| Theorem | onssmin 3008 |
A non-empty class of ordinal numbers has a smallest member. Exercise
9 of [TakeutiZaring] p. 40.
|
| ⊢
((A ⊆ On ⋀ A ≠ ∅) → ∃x ∈ A
∀y ∈ A x ⊆
y) |
| |
| Theorem | onminsb 3009 |
If a property is true for some ordinal number, it is true for a minimal
ordinal number. This version uses implicit substitution. Theorem
Schema 62 of [Suppes] p. 228.
|
| ⊢
(ψ → ∀xψ)
& ⊢ (x = ∩{x ∈ On∣φ} → (φ ↔ ψ))
⇒ ⊢ (∃x ∈ On φ → ψ) |
| |
| Theorem | onminesb 3010 |
If a property is true for some ordinal number, it is true for a minimal
ordinal number. This version uses explicit substitution. Theorem
Schema 62 of [Suppes] p. 228.
|
| ⊢
(∃x ∈ On φ → [∩{x ∈
On∣φ} / x]φ) |
| |
| Theorem | onintss 3011 |
If a property is true for an ordinal number, then the minimum ordinal
number for which it is true is smaller or equal. Theorem Schema 61 of
[Suppes] p. 228.
|
| ⊢
(x = A → (φ
↔ ψ))
⇒ ⊢ (A ∈ On → (ψ → ∩{x ∈
On∣φ} ⊆ A)) |
| |
| Theorem | oninton 3012 |
The intersection of a non-empty collection of ordinal numbers is an
ordinal number. Compare Exercise 6 of [TakeutiZaring] p. 44.
|
| ⊢
((A ⊆ On ⋀ A ≠ ∅) → ∩A ∈
On) |
| |
| Theorem | onintrab 3013 |
The intersection of a class of ordinal numbers exists iff it is an ordinal
number.
|
| ⊢
(∩{x
∈ On∣φ} ∈ V
↔ ∩{x
∈ On∣φ} ∈
On) |
| |
| Theorem | onintrab2 3014 |
An existence condition equivalent to an intersection's being an ordinal
number.
|
| ⊢
(∃x ∈ On φ ↔ ∩{x ∈
On∣φ} ∈ On) |
| |
| Theorem | onnmin 3015 |
No member of a set of ordinal numbers belongs to its minimum.
|
| ⊢
((A ⊆ On ⋀ B ∈ A)
→ ¬ B ∈ ∩A) |
| |
| Theorem | onnminsb 3016 |
An ordinal number smaller than the minimum of a set of ordinal numbers
does not have the property determining that set. ψ is the wff
resulting from the substitution of A
for x in wff φ.
|
| ⊢
(x = A → (φ
↔ ψ))
⇒ ⊢ (A ∈ On → (A ∈ ∩{x ∈ On∣φ} → ¬ ψ)) |
| |
| Theorem | oneqmini 3017 |
A way to show that an ordinal number equals the minimum of a collection
of ordinal numbers: it must be in the collection, and it must not be
larger than any member of the collection.
|
| ⊢
(B ⊆ On → ((A ∈ B
⋀ ∀x ∈ A ¬ x
∈ B) → A = ∩B)) |
| |
| Theorem | oneqmin 3018 |
A way to show that an ordinal number equals the minimum of a non-empty
collection of ordinal numbers: it must be in the collection, and it must
not be larger than any member of the collection.
|
| ⊢
((B ⊆ On ⋀ B ≠ ∅) → (A = ∩B ↔ (A
∈ B ⋀ ∀x ∈ A
¬ x ∈ B))) |
| |
| Theorem | bm2.5ii 3019 |
Problem 2.5(ii) of [BellMachover] p. 471.
|
| ⊢
A ∈ V
⇒ ⊢ (A ⊆ On → ∪A = ∩{x ∈
On∣∀y ∈ A y ⊆
x}) |
| |
| Theorem | onminex 3020 |
If a wff is true for an ordinal number, there is a smallest ordinal
number for which it is true.
|
| ⊢
(x = y → (φ
↔ ψ))
⇒ ⊢ (∃x ∈ On φ → ∃x ∈ On (φ ⋀ ∀y ∈ x
¬ ψ)) |
| |
| Theorem | ord0 3021 |
The empty set is an ordinal class.
|
| ⊢
Ord ∅ |
| |
| Theorem | 0elon 3022 |
The empty set is an ordinal number. Corollary 7N(b) of [Enderton]
p. 193.
|
| ⊢
∅ ∈ On |
| |
| Theorem | ord0eln0 3023 |
A non-empty ordinal contains the empty set.
|
| ⊢
(Ord A → (∅ ∈
A ↔ A ≠ ∅)) |
| |
| Theorem | on0eln0 3024 |
An ordinal number contains zero iff it is nonzero.
|
| ⊢
(A ∈ On → (∅ ∈
A ↔ A ≠ ∅)) |
| |
| Theorem | dflim2 3025 |
An alternate definition of a limit ordinal.
|
| ⊢
(Lim A ↔ (Ord A ⋀ ∅ ∈ A ⋀ A =
∪A)) |
| |
| Theorem | inton 3026 |
The intersection of the class of ordinal numbers is the empty set.
|
| ⊢
∩On = ∅ |
| |
| Theorem | nlim0 3027 |
The empty set is not a limit ordinal.
|
| ⊢
¬ Lim ∅ |
| |
| Theorem | limord 3028 |
A limit ordinal is ordinal.
|
| ⊢
(Lim A → Ord A) |
| |
| Theorem | limuni 3029 |
A limit ordinal is its own supremum (union).
|
| ⊢
(Lim A → A = ∪A) |
| |
| Theorem | limuni2 3030 |
The union of a limit ordinal is a limit ordinal.
|
| ⊢
(Lim A → Lim ∪A) |
| |
| Theorem | 0ellim 3031 |
A limit ordinal contains the empty set.
|
| ⊢
(Lim A → ∅ ∈
A) |
| |
| Theorem | limelon 3032 |
A limit ordinal class that is also a set is an ordinal number.
|
| ⊢
((A ∈ B ⋀ Lim A) → A
∈ On) |
| |
| Theorem | onne0 3033 |
The class of all ordinal numbers in not empty.
|
| ⊢
On ≠ ∅ |
| |
| Theorem | suceq 3034 |
Equality of successors.
|
| ⊢
(A = B → suc A
= suc B) |
| |
| Theorem | elsuci 3035 |
Membership in a successor. This one-way implication does not require that
either A or B be sets.
|
| ⊢
(A ∈ suc B → (A
∈ B ⋁ A = B)) |
| |
| Theorem | elsucg 3036 |
Membership in a successor. Exercise 5 of [TakeutiZaring] p. 17.
|
| ⊢
(A ∈ C → (A
∈ suc B ↔ (A ∈ B
⋁ A = B))) |
| |
| Theorem | elsuc2g 3037 |
Variant of membership in a successor, requiring that B rather than
A be a set.
|
| ⊢
(B ∈ C → (A
∈ suc B ↔ (A ∈ B
⋁ A = B))) |
| |
| Theorem | elsuc 3038 |
Membership in a successor. Exercise 5 of [TakeutiZaring] p. 17.
|
| ⊢
A ∈ V
⇒ ⊢ (A ∈ suc B
↔ (A ∈ B ⋁ A =
B)) |
| |
| Theorem | elsuc2 3039 |
Membership in a successor.
|
| ⊢
A ∈ V
⇒ ⊢ (B ∈ suc A
↔ (B ∈ A ⋁ B =
A)) |
| |
| Theorem | hbsuc 3040 |
Bound-variable hypothesis builder for successor.
|
| ⊢
(y ∈ A → ∀x y ∈
A)
⇒ ⊢ (y ∈ suc A
→ ∀x y ∈ suc A) |
| |
| Theorem | elelsuc 3041 |
Membership in a successor.
|
| ⊢
(A ∈ B → A
∈ suc B) |
| |
| Theorem | sucel 3042 |
Membership of a successor in another class.
|
| ⊢
(suc A ∈ B ↔ ∃x ∈ B
∀y(y ∈ x
↔ (y ∈ A ⋁ y =
A))) |
| |
| Theorem | suc0 3043 |
The successor of the empty set.
|
| ⊢
suc ∅ = {∅} |
| |
| Theorem | sucprc 3044 |
A proper class is its own successor.
|
| ⊢
(¬ A ∈ V → suc
A = A) |
| |
| Theorem | sucon 3045 |
The class of all ordinal numbers is its own successor.
|
| ⊢
suc On = On |
| |
| Theorem | unisuc 3046 |
A transitive class is equal to the union of its successor. Combines
Theorem 4E of [Enderton] p. 72 and
Exercise 6 of [Enderton] p. 73.
|
| ⊢
A ∈ V
⇒ ⊢ (Tr A ↔ ∪suc A = A) |
| |
| Theorem | sssucid 3047 |
A class is included in its own successor. Part of Proposition 7.23 of
[TakeutiZaring] p. 41 (generalized
to arbitrary classes).
|
| ⊢
A ⊆ suc A |
| |
| Theorem | sucexb 3048 |
A successor exists iff its class argument exists.
|
| ⊢
(A ∈ V ↔ suc
A ∈ V) |
| |
| Theorem | sucexg 3049 |
The successor of a set is a set (generalization).
|
| ⊢
(A ∈ B → suc A
∈ V) |
| |
| Theorem | sucex 3050 |
The successor of a set is a set.
|
| ⊢
A ∈ V
⇒ ⊢ suc A ∈ V |
| |
| Theorem | sucid 3051 |
A set belongs to its successor.
|
| ⊢
A ∈ V
⇒ ⊢ A ∈ suc A |
| |
| Theorem | sucidg 3052 |
Part of Proposition 7.23 of [TakeutiZaring] p. 41 (generalized).
|
| ⊢
(A ∈ B → A
∈ suc A) |
| |
| Theorem | nsuceq0 3053 |
No successor is empty.
|
| ⊢
suc A ≠ ∅ |
| |
| Theorem | eqelsuc 3054 |
A set belongs to the successor of an equal set.
|
| ⊢
A ∈ V
⇒ ⊢ (A = B →
A ∈ suc B) |
| |
| Theorem | trsuc 3055 |
A set whose successor belongs to a transitive class also belongs.
|
| ⊢
((Tr A ⋀ suc B ∈ A)
→ B ∈ A) |
| |
| Theorem | trsucss 3056 |
A member of the successor of a transitive class is a subclass of it.
|
| ⊢
(Tr A → (B ∈ suc A
→ B ⊆ A)) |
| |
| Theorem | ordsssuc 3057 |
A subset of an ordinal belongs to its successor.
|
| ⊢
((A ∈ On ⋀ Ord B) → (A
⊆ B ↔ A ∈ suc B)) |
| |
| Theorem | onsssuc 3058 |
A subset of an ordinal number belongs to its successor.
|
| ⊢
((A ∈ On ⋀ B ∈ On) → (A ⊆ B
↔ A ∈ suc B)) |
| |
| Theorem | ordsssuc2 3059 |
An ordinal subset of an ordinal number belongs to its successor.
|
| ⊢
((Ord A ⋀ B ∈ On) → (A ⊆ B
↔ A ∈ suc B)) |
| |
| Theorem | onmindif 3060 |
When its successor is subtracted from a class of ordinal numbers, an
ordinal number is less than the minimum of the resulting subclass.
|
| ⊢
((A ⊆ On ⋀ B ∈ On) → B ∈ ∩(A ∖ suc B)) |
| |
| Theorem | onmindif2 3061 |
The minimum of a class of ordinal numbers is less than the minimum
of that class with its minimum removed.
|
| ⊢
((A ⊆ On ⋀ A ≠ ∅) → ∩A ∈ ∩(A ∖ {∩A})) |
| |
| Theorem | suceloni 3062 |
The successor of an ordinal number is an ordinal number. Proposition
7.24 of [TakeutiZaring] p. 41.
|
| ⊢
(A ∈ On → suc A ∈ On) |
| |
| Theorem | ordnbtwn 3063 |
There is no set between an ordinal class and its successor. Generalized
Proposition 7.25 of [TakeutiZaring]
p. 41.
|
| ⊢
(Ord A → ¬ (A ∈ B
⋀ B ∈ suc A)) |
| |
| Theorem | onnbtwn 3064 |
There is no set between an ordinal number and its successor. Proposition
7.25 of [TakeutiZaring] p. 41.
|
| ⊢
(A ∈ On → ¬ (A ∈ B
⋀ B ∈ suc A)) |
| |
| Theorem | ordsuc 3065 |
The successor of an ordinal class is ordinal.
|
| ⊢
(Ord A ↔ Ord suc A) |
| |
| Theorem | ordpwsuc 3066 |
The collection of ordinals in the power class of an ordinal is its
successor.
|
| ⊢
(Ord A → (℘A ∩ On) = suc A) |
| |
| Theorem | onpwsuc 3067 |
The collection of ordinal numbers in the power set of an ordinal
number is its successor.
|
| ⊢
(A ∈ On →
(℘A ∩ On) = suc A) |
| |
| Theorem | sucelon 3068 |
The successor of an ordinal number is an ordinal number.
|
| ⊢
(A ∈ On ↔ suc A ∈ On) |
| |
| Theorem | ordsucss 3069 |
The successor of an element of an ordinal class is a subset of it.
|
| ⊢
(Ord B → (A ∈ B
→ suc A ⊆ B)) |
| |
| Theorem | sucssel 3070 |
A set whose successor is a subset of another class is a member of that
class.
|
| ⊢
(A ∈ C → (suc A
⊆ B → A ∈ B)) |
| |
| Theorem | ordelsuc 3071 |
A set belongs to an ordinal iff its successor is a subset of the
ordinal. Exercise 8 of [TakeutiZaring] p. 42 and its converse.
|
| ⊢
((A ∈ C ⋀ Ord B) → (A
∈ B ↔ suc A ⊆ B)) |
| |
| Theorem | onsucmin 3072 |
The successor of an ordinal number is the smallest larger ordinal
number.
|
| ⊢
(A ∈ On → suc A = ∩{x ∈ On∣A ∈ x}) |
| |
| Theorem | ordsucelsuc 3073 |
Membership is inherited by successors. Generalization of Exercise
9 of [TakeutiZaring] p. 42.
|
| ⊢
(Ord B → (A ∈ B
↔ suc A ∈ suc B)) |
| |
| Theorem | ordsucsssuc 3074 |
The subclass relationship between two ordinal classes is inherited by
their successors.
|
| ⊢
((Ord A ⋀ Ord B) → (A
⊆ B ↔ suc A ⊆ suc B)) |
| |
| Theorem | orddif 3075 |
Ordinal derived from its successor.
|
| ⊢
(Ord A → A = (suc A
∖ {A})) |
| |
| Theorem | orduniss 3076 |
An ordinal class includes its union.
|
| ⊢
(Ord A → ∪A ⊆ A) |
| |
| Theorem | ordtri2or 3077 |
A trichotomy law for ordinal classes.
|
| ⊢
((Ord A ⋀ Ord B) → (A
∈ B ⋁ B ⊆ A)) |
| |
| Theorem | ordtri2or2 3078 |
A trichotomy law for ordinal classes.
|
| ⊢
((Ord A ⋀ Ord B) → (A
⊆ B ⋁ B ⊆ A)) |
| |
| Theorem | ordssun 3079 |
Property of a subclass of the maximum (i.e. union) of two ordinals.
|
| ⊢
((Ord B ⋀ Ord C) → (A
⊆ (B ∪ C) ↔ (A
⊆ B ⋁ A ⊆ C))) |
| |
| Theorem | ordequn 3080 |
The maximum (i.e. union) of two ordinals is either one or the other.
Similar to Exercise 14 of [TakeutiZaring] p. 40.
|
| ⊢
((Ord B ⋀ Ord C) → (A =
(B ∪ C) → (A =
B ⋁ A = C))) |
| |
| Theorem | ordun 3081 |
The maximum (i.e. union) of two ordinals is ordinal. Exercise 12 of
[TakeutiZaring] p. 40.
|
| ⊢
((Ord A ⋀ Ord B) → Ord (A ∪ B)) |
| |
| Theorem | ordsucun 3082 |
The successor of the maximum (i.e. union) of two ordinals is the
maximum of their successors.
|
| ⊢
((Ord A ⋀ Ord B) → suc (A ∪ B) =
(suc A ∪ suc B)) |
| |
| Theorem | ordunisssuc 3083 |
A subclass relationship for union and successor of ordinal classes.
|
| ⊢
((A ⊆ On ⋀ Ord B) → (∪A ⊆ B
↔ A ⊆ suc B)) |
| |
| Theorem | ordunel 3084 |
The maximum of two ordinals belongs to a third if each of them do.
|
| ⊢
((Ord A ⋀ B ∈ A
⋀ C ∈ A) → (B
∪ C) ∈ A) |
| |
| Theorem | onsucuni 3085 |
A class of ordinal numbers is a subclass of the successor of its
union. Similar to Proposition 7.26 of [TakeutiZaring] p. 41.
|
| ⊢
(A ⊆ On → A ⊆ suc ∪A) |
| |
| Theorem | ordsucuni 3086 |
An ordinal class is a subclass of the successor of its union.
|
| ⊢
(Ord A → A ⊆ suc ∪A) |
| |
| Theorem | orduniorsuc 3087 |
An ordinal class is either its union or the successor of its union.
|
| ⊢
(Ord A → (A = ∪A ⋁ A =
suc ∪A)) |
| |
| Theorem | unon 3088 |
The class of all ordinal numbers is its own union. Exercise 11 of
[TakeutiZaring] p. 40.
|
| ⊢
∪On = On |
| |
| Theorem | ordunisuc 3089 |
An ordinal class is equal to the union of its successor.
|
| ⊢
(Ord A → ∪suc A = A) |
| |
| Theorem | orduniss2 3090 |
The union of the ordinal subsets of an ordinal number is that number.
|
| ⊢
(Ord A → ∪{x ∈
On∣x ⊆ A} = A) |
| |
| Theorem | onsucuni2 3091 |
A successor ordinal is the successor of its union.
|
| ⊢
((A ∈ On ⋀ A = suc B)
→ suc ∪A =
A) |
| |
| Theorem | 0elsuc 3092 |
The successor of an ordinal class contains the empty set.
|
| ⊢
(Ord A → ∅ ∈ suc
A) |
| |
| Theorem | suc11 3093 |
The successor operation behaves like a one-to-one function. Compare
Exercise 16 of [Enderton] p. 194.
|
| ⊢
((A ∈ On ⋀ B ∈ On) → (suc A = suc B
↔ A = B)) |
| |
| Theorem | limon 3094 |
The class of ordinal numbers is a limit ordinal.
|
| ⊢
Lim On |
| |
| Theorem | onord 3095 |
An ordinal number is an ordinal class.
|
| ⊢
A ∈ On
⇒ ⊢ Ord A |
| |
| Theorem | ontrc 3096 |
An ordinal number is a transitive class.
|
| ⊢
A ∈ On
⇒ ⊢ Tr A |
| |
| Theorem | onirr 3097 |
An ordinal number is not a member of itself. Theorem 7M(c) of
[Enderton] p. 192.
|
| ⊢
A ∈ On
⇒ ⊢ ¬ A ∈ A |
| |
| Theorem | onel 3098 |
A member of an ordinal number is an ordinal number. Theorem 7M(a) of
[Enderton] p. 192.
|
| ⊢
A ∈ On
⇒ ⊢ (B ∈ A
→ B ∈ On) |
| |
| Theorem | onss 3099 |
An ordinal number is a subset of On.
|
| ⊢
A ∈ On
⇒ ⊢ A ⊆ On |
| |
| Theorem | onelss 3100 |
A member of an ordinal number is a subset of it.
|
| ⊢
A ∈ On
⇒ ⊢ (B ∈ A
→ B ⊆ A) |
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