Home(or GIF version for IE).
| Home |
Metamath Proof Explorer | < Previous Next > |
| Bad symbols?
Use Firefox (or GIF version for IE). |
| Color key: | Metamath Proof Explorer
(1-8743)
|
Hilbert Space Explorer
(8744-10676)
|
| Type | Label | Description | |
|---|---|---|---|
| Statement | |||
| Theorem | inf3lem6 4601 | Lemma for our Axiom of Infinity => standard Axiom of Infinity. See inf3 4603 for detailed description. | |
| Theorem | inf3lem7 4602 | Lemma for our Axiom of Infinity => standard Axiom of Infinity. See inf3 4603 for detailed description. In the proof, we invoke the Axiom of Replacement in the form of funrnex 3608. | |
| Theorem | inf3 4603 |
Our Axiom of Infinity ax-inf 4605 implies the standard Axiom of Infinity.
The hypothesis is a variant of our Axiom of Infinity provided by
inf2 4591, and the conclusion is the version of the
Axiom of Infinity
shown as Axiom 7 in [TakeutiZaring] p. 43. (Other standard
versions are
proved later as axinf2 4607 and zfinf 4609.) The main proof is provided by
inf3lema 4592 through inf3lem7 4602, and this final piece eliminates the
auxiliary hypothesis of inf3lem7 4602. This proof is due to
Ian Sutherland, Richard Heck, and Norman Megill and was posted
on Usenet as shown below. Although the result is not new, the authors
were unable to find a published proof.
| |
| ⊢ ∃x(x ≠ ∅ ⋀ x ⊆ ∪x) ⇒ ⊢ ω ∈ V | |||
| Theorem | infeq5 4604 | The statement "there exists a set that is a proper subset of its union" is equivalent to the Axiom of Infinity (shown on the right-hand side in the form of omex 4610.) The left-hand side provides us with a very short way to express of the Axiom of Infinity using only elementary symbols. This proof of equivalence does not depend on the Axiom of Infinity. | |
| ⊢ (∃x x ⊂ ∪x ↔ ω ∈ V) | |||
| ZF Set Theory - add the Axiom of Infinity | |||
| Introduce the Axiom of Infinity | |||
| Axiom | ax-inf 4605 |
Axiom of Infinity. An axiom of Zermelo-Fraenkel set theory. This axiom
is the gateway to "Cantor's paradise" (an expression coined by
Hilbert).
It asserts that given a starting set x, an infinite set y built
from it exists. Although our version is apparently not given in the
literature, it is similar to, but slightly shorter than, the Axiom of
Infinity in [FreydScedrov] p. 283
(see inf1 4590 and inf2 4591). More
standard versions, which essentially state that there exists a set
containing all the natural numbers, are shown as zfinf 4609 and omex 4610 and
are based on the (nontrivial) proof of inf3 4603.
Our version has the
advantage that when expanded to primitives, it has fewer symbols than
the standard version ax-inf2 4608. Theorem inf0 4589
shows the reverse
derivation of our axiom from a standard one. Theorem inf5 4611
shows a
very short way to state this axiom.
An interesting property of our version is that, unlike the standard version, it does not assert the independent existence of any set; it needs a starting set x. Since none of our other ZFC axioms assert the independent existence of any set, we would need to add an axiom of existence such as Axiom 0 of [Kunen] p. 10 if we were to use a "free logic" predicate calculus that (unlike ours) does not assert (as we do with ax-4 972 and ax-9 964) that at least one thing exists. The standard version of Infinity ax-inf2 4608 requires this axiom along with Regularity ax-reg 4576 for its derivation (as theorem axinf2 4607 below). In order to more easily identify the normal uses of Regularity, we will usually reference ax-inf2 4608 instead of this one. | |
| ⊢ ∃y(x ∈ y ⋀ ∀z(z ∈ y → ∃w(z ∈ w ⋀ w ∈ y))) | |||
| Theorem | axinf 4606 | Axiom of Infinity expressed with fewest number of different variables. | |
| ⊢ ∃x(y ∈ x ⋀ ∀y(y ∈ x → ∃z(y ∈ z ⋀ z ∈ x))) | |||
| Theorem | axinf2 4607 |
A standard version of Axiom of Infinity, expanded to primitives, derived
from our version of Infinity ax-inf 4605 and Regularity ax-reg 4576.
This theorem should not be referenced in any proof. Instead, use ax-inf2 4608 below so that the ordinary uses of Regularity can be more easily identified. | |
| ⊢ ∃x(∃y(y ∈ x ⋀ ∀z ¬ z ∈ y) ⋀ ∀y(y ∈ x → ∃z(z ∈ x ⋀ ∀w(w ∈ z ↔ (w ∈ y ⋁ w = y))))) | |||
| Axiom | ax-inf2 4608 | A standard version of Axiom of Infinity of ZF set theory. In English, it says: there exists a set that contains the empty set and the successors of all of its members. Theorem zfinf 4609 shows it converted to abbreviations. This axiom was derived as theorem axinf2 4607 above, using our version of Infinity ax-inf 4605 and the Axiom of Regularity ax-reg 4576. We will reference ax-inf2 4608 instead of axinf2 4607 so that the ordinary uses of Regularity can be more easily identified. | |
| ⊢ ∃x(∃y(y ∈ x ⋀ ∀z ¬ z ∈ y) ⋀ ∀y(y ∈ x → ∃z(z ∈ x ⋀ ∀w(w ∈ z ↔ (w ∈ y ⋁ w = y))))) | |||
| Theorem | zfinf 4609 | A standard version of the Axiom of Infinity, using definitions to abbreviate. Axiom Inf of [BellMachover] p. 472. (See ax-inf2 4608 for the unabbreviated version.) | |
| ⊢ ∃x(∅ ∈ x ⋀ ∀y ∈ x suc y ∈ x) | |||
| Existence of omega (the set of natural numbers) | |||
| Theorem | omex 4610 |
The existence of omega (the class of natural numbers). Axiom 7 of
[TakeutiZaring] p. 43. This
theorem is proved assuming the Axiom of
Infinity and in fact is equivalent to it, as shown by the reverse
derivation inf0 4589.
A finitist (someone who doesn't believe in infinity) could, without contradiction, replace the Axiom of Infinity by its denial ¬ ω ∈ V; this would lead to ω = On (the proper class of ordinals) by omon 3139 and onprc 2985. The finitist could still develop natural number, integer, and rational number arithmetic but would be denied the real numbers (as well as much of the rest of mathematics). In deference to the finitist, much of our development is done, when possible, without invoking the Axiom of Infinity; an example is Peano's axioms peano1 3145 through peano5 3149 (which many textbooks prove more easily assuming Infinity). | |
| ⊢ ω ∈ V | |||
| Theorem | inf5 4611 | The statement "there exists a set that is a proper subset of its union" is equivalent to the Axiom of Infinity (see theorem infeq5 4604). This provides us with a very compact way to express of the Axiom of Infinity using only elementary symbols. | |
| ⊢ ∃x x ⊂ ∪x | |||
| Theorem | omelon 4612 | Omega is an ordinal number. | |
| ⊢ ω ∈ On | |||
| Theorem | dfom3 4613 | The class of natural numbers omega can be defined as the smallest "inductive set," which is valid provided we assume the Axiom of Infinity. Definition 6.3 of [Eisenberg] p. 82. | |
| ⊢ ω = ∩{x∣(∅ ∈ x ⋀ ∀y ∈ x suc y ∈ x)} | |||
| Theorem | elom3 4614 | A simplification of elom 3130 assuming the Axiom of Infinity. | |
| ⊢ (A ∈ ω ↔ ∀x(Lim x → A ∈ x)) | |||
| Theorem | dfom4 4615 | A simplification of df-om 3128 assuming the Axiom of Infinity. | |
| ⊢ ω = {x∣∀y(Lim y → x ∈ y)} | |||
| Theorem | oancom 4616 | Ordinal addition is not commutative. This theorem shows a counterexample. Remark in [TakeutiZaring] p. 60. | |
| ⊢ (1o +o ω) ≠ (ω +o 1o) | |||
| Theorem | isfinite 4617 | A set is strictly dominated by the class of natural numbers iff it is finite. Theorem 42 of [Suppes] p. 151. This theorem provides two equivalent ways to express "A is finite." The Axiom of Infinity is used for the reverse implication. | |
| ⊢ (A ≺ ω ↔ ∃x ∈ ω A ≈ x) | |||
| Theorem | nnsdom 4618 | A natural number is strictly dominated by the set of natural numbers. | |
| ⊢ (A ∈ ω → A ≺ ω) | |||
| Theorem | omenps 4619 | Omega is equinumerous to a proper subset of itself. Example 13.2(4) of [Eisenberg] p. 216. | |
| ⊢ ω ≈ (ω ∖ {∅}) | |||
| Theorem | omensuc 4620 | The set of natural numbers is equinumerous to its successor. | |
| ⊢ ω ≈ suc ω | |||
| Theorem | infensuc 4621 | Any infinite ordinal is equinumerous to its successor. Exercise 7 of [TakeutiZaring] p. 88. | |
| ⊢ ((A ∈ On ⋀ ω ⊆ A) → A ≈ suc A) | |||
| Theorem | unbnnt 4622 | Any unbounded subset of natural numbers is equinumerous to the set of all natural numbers. This version of unbnn 4530 eliminates its hypothesis by assuming the Axiom of Infinity. | |
| ⊢ ((A ⊆ ω ⋀ ∀x ∈ ω ∃y ∈ A x ∈ y) → A ≈ ω) | |||
| Theorem | noinfep 4623 | Using the Axiom of Regularity in the form zfregfr 4584, show that there are no infinite descending ∈ -chains. Proposition 7.34 of [TakeutiZaring] p. 44. | |
| ⊢ (F Fn ω → ∃x ∈ ω ¬ (F ‘suc x) ∈ (F ‘x)) | |||
| Rank | |||
| Syntax | cr1 4624 | Extend class definition to include the cumulative hierarchy of sets function. | |
| class R1 | |||
| Syntax | crnk 4625 | Extend class definition to include rank function. | |
| class rank | |||
| Definition | df-r1 4626 | Define the cumulative hierarchy of sets function, using Takeuti and Zaring's notation (R1). Starting with the empty set, this function builds up layers of sets where the next layer is the power set of the previous layer (and the union of previous layers when the argument is a limit ordinal). Using the Axiom of Regularity, we can show that any set whatsoever belongs to one of the layers of this hierarchy (see tz9.13 4646). Our definition expresses Definition 9.9 of [TakeutiZaring] p. 76 in a closed form, from which we derive the recursive definition as theorems r10 4634, r1suc 4635, and r1lim 4636. Theorem r1val1 4641 shows a recursive definition that works for all values, and theorems r1val2 4661 and r1val3 4662 show the value expressed in terms of rank. Other notations for this function are R with the argument as a subscript (Equation 3.1 of [BellMachover] p. 477), V with a a subscript (Definition of [Enderton] p. 202), M with a subscript (Definition 15.19 of [Monk1] p. 113), the capital Greek letter psi (Definition of [Mendelson] p. 281), and bold-face R (Definition 2.1 of [Kunen] p. 95). | |
| ⊢ R1 = rec({⟨x, y⟩∣y = ℘x}, ∅) | |||
| Definition | df-rank 4627 | Define the rank function. See rankval 4651, rankval2 4653, rankval3 4664, or rankval4 4685 its value. The rank is a kind of "inverse" of the cumulative hierarchy of sets function R1: given a set, it returns an ordinal number telling us the smallest layer of the hierarchy to which the set belongs. Based on Definition 9.14 of [TakeutiZaring] p. 79. Theorem rankid 4655 illustrates the "inverse" concept. Another nice theorem showing the relationship is rankr1a 4660. | |
| ⊢ rank = {⟨x, y⟩∣y = ∩{z ∈ On∣x ∈ (R1 ‘suc z)}} | |||
| Theorem | trcl 4628 | For any set A, show the properties of its transitive closure C. Similar to Theorem 9.1 of [TakeutiZaring] p. 73 except that we show an explicit expression for the transitive closure rather than just its existence. See tz9.1 4629 for an abbreviated version showing existence. | |
| ⊢ A ∈ V & ⊢ F = (rec({⟨z, w⟩∣w = (z ∪ ∪z)}, A) ↾ ω) & ⊢ C = ∪y ∈ ω (F ‘y) ⇒ ⊢ (A ⊆ C ⋀ Tr C ⋀ ∀x((A ⊆ x ⋀ Tr x) → C ⊆ x)) | |||
| Theorem | tz9.1 4629 | Every set has a transitive closure (smallest transitive extension). Theorem 9.1 of [TakeutiZaring] p. 73. See trcl 4628 for an explicit expression for the transitive closure. | |
| ⊢ A ∈ V ⇒ ⊢ ∃x(A ⊆ x ⋀ Tr x ⋀ ∀y((A ⊆ y ⋀ Tr y) → x ⊆ y)) | |||
| Theorem | zfregs 4630 | The strong form of the Axiom of Regularity, which does not require that A be a set. Axiom 6' of [TakeutiZaring] p. 21. The proof makes use of a special case of Proposition 9.4 of [TakeutiZaring] p. 75. | |
| ⊢ (A ≠ ∅ → ∃x ∈ A (x ∩ A) = ∅) | |||
| Theorem | setind 4631 | Set (epsilon) induction. Theorem 5.22 of [TakeutiZaring] p. 21. | |
| ⊢ (∀x(x ⊆ A → x ∈ A) → A = V) | |||
| Theorem | setind2 4632 | Set (epsilon) induction, stated compactly. Given as a homework problem in 1992 by George Boolos (1940-1996). | |
| ⊢ (℘A ⊆ A → A = V) | |||
| Theorem | r1fnon 4633 | The cumulative hierarchy of sets function is a function on the class of ordinal numbers. | |
| ⊢ R1 Fn On | |||
| Theorem | r10 4634 | Value of the cumulative hierarchy of sets function at ∅. Part of Definition 9.9 of [TakeutiZaring] p. 76. | |
| ⊢ (R1 ‘∅) = ∅ | |||
| Theorem | r1suc 4635 | Value of the cumulative hierarchy of sets function at a successor ordinal. Part of Definition 9.9 of [TakeutiZaring] p. 76. | |
| ⊢ (A ∈ On → (R1 ‘suc A) = ℘(R1 ‘A)) | |||
| Theorem | r1lim 4636 | Value of the cumulative hierarchy of sets function at a limit ordinal. Part of Definition 9.9 of [TakeutiZaring] p. 76. | |
| ⊢ ((A ∈ B ⋀ Lim A) → (R1 ‘A) = ∪x ∈ A (R1 ‘x)) | |||
| Theorem | r1tr 4637 | The cumulative hierarchy of sets is transitive. Lemma 7T of [Enderton] p. 202. | |
| ⊢ Tr (R1 ‘A) | |||
| Theorem | r1ord 4638 | Ordering relation for the cumulative hierarchy of sets. Part of Proposition 9.10(2) of [TakeutiZaring] p. 77. | |
| ⊢ (B ∈ On → (A ∈ B → (R1 ‘A) ∈ (R1 ‘B))) | |||
| Theorem | r1ord2 4639 | Ordering relation for the cumulative hierarchy of sets. Part of Proposition 9.10(2) of [TakeutiZaring] p. 77. | |
| ⊢ (B ∈ On → (A ∈ B → (R1 ‘A) ⊆ (R1 ‘B))) | |||
| Theorem | r1ord3 4640 | Ordering relation for the cumulative hierarchy of sets. Part of Theorem 3.3(i) of [BellMachover] p. 478. | |
| ⊢ ((A ∈ On ⋀ B ∈ On) → (A ⊆ B → (R1 ‘A) ⊆ (R1 ‘B))) | |||
| Theorem | r1val1 4641 | The value of the cumulative hierarchy of sets function expressed recursively. Theorem 7Q of [Enderton] p. 202. | |
| ⊢ (A ∈ On → (R1 ‘A) = ∪x ∈ A ℘(R1 ‘x)) | |||
| Theorem | tz9.12lem1 4642 | Lemma for tz9.12 4645. | |
| Theorem | tz9.12lem2 4643 | Lemma for tz9.12 4645. | |
| Theorem | tz9.12lem3 4644 | Lemma for tz9.12 4645. | |
| Theorem | tz9.12 4645 | A set is well-founded if all of its elements are well-founded. Proposition 9.12 of [TakeutiZaring] p. 78. The main proof consists of tz9.12lem1 4642 through tz9.12lem3 4644. | |
| ⊢ A ∈ V ⇒ ⊢ (∀x ∈ A ∃y ∈ On x ∈ (R1 ‘y) → ∃y ∈ On A ∈ (R1 ‘y)) | |||
| Theorem | tz9.13 4646 | Every set is well-founded, assuming the Axiom of Regularity. In other words, every set belongs to a layer of the cumulative hierarchy of sets. Proposition 9.13 of [TakeutiZaring] p. 78. | |
| ⊢ A ∈ V ⇒ ⊢ ∃x ∈ On A ∈ (R1 ‘x) | |||
| Theorem | tz9.13g 4647 | Every set is well-founded, assuming the Axiom of Regularity. Proposition 9.13 of [TakeutiZaring] p. 78. This variant of tz9.13 4646 expresses the class existence requirement as an antecedent. | |
| ⊢ (A ∈ B → ∃x ∈ On A ∈ (R1 ‘x)) | |||
| Theorem | rankwflem 4648 | Every set is well-founded, assuming the Axiom of Regularity. Proposition 9.13 of [TakeutiZaring] p. 78. This variant of tz9.13g 4647 is useful in proofs of theorems about the rank function. | |
| ⊢ (A ∈ B → ∃x ∈ On A ∈ (R1 ‘suc x)) | |||
| Theorem | jech9.3 4649 | Every set belongs to some value of the cumulative hierarchy of sets function R1, i.e. the indexed union of all values of R1 is the universe. Lemma 9.3 of [Jech] p. 71. | |
| ⊢ ∪x ∈ On (R1 ‘x) = V | |||
| Theorem | unir1 4650 | The cumulative hierarchy of sets covers the universe. Proposition 4.45 (b) to (a) of [Mendelson] p. 281. | |
| ⊢ ∪(R1 “ On) = V | |||
| Theorem | rankval 4651 | Value of the rank function. Definition 9.14 of [TakeutiZaring] p. 79 (proved as a theorem from our definition). | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘A) = ∩{x ∈ On∣A ∈ (R1 ‘suc x)} | |||
| Theorem | rankvalg 4652 | Value of the rank function. Definition 9.14 of [TakeutiZaring] p. 79 (proved as a theorem from our definition). This variant of rankval 4651 expresses the class existence requirement as an antecedent instead of a hypothesis. | |
| ⊢ (A ∈ B → (rank ‘A) = ∩{x ∈ On∣A ∈ (R1 ‘suc x)}) | |||
| Theorem | rankval2 4653 | Value of an alternate definition of the rank function. Definition of [BellMachover] p. 478. | |
| ⊢ (A ∈ B → (rank ‘A) = ∩{x ∈ On∣A ⊆ (R1 ‘x)}) | |||
| Theorem | rankon 4654 | The rank of a set is an ordinal number. Proposition 9.15(1) of [TakeutiZaring] p. 79. | |
| ⊢ (rank ‘A) ∈ On | |||
| Theorem | rankid 4655 | Identity law for the rank function. | |
| ⊢ A ∈ V ⇒ ⊢ A ∈ (R1 ‘suc (rank ‘A)) | |||
| Theorem | rankr1lem 4656 | Lemma for rankr1 4657. | |
| Theorem | rankr1 4657 | A relationship between the rank function and the cumulative hierarchy of sets function R1. Proposition 9.15(2) of [TakeutiZaring] p. 79. | |
| ⊢ A ∈ V ⇒ ⊢ (B = (rank ‘A) ↔ (¬ A ∈ (R1 ‘B) ⋀ A ∈ (R1 ‘suc B))) | |||
| Theorem | rankr1g 4658 | A relationship between the rank function and the cumulative hierarchy of sets function R1. Proposition 9.15(2) of [TakeutiZaring] p. 79. | |
| ⊢ (A ∈ C → (B = (rank ‘A) ↔ (¬ A ∈ (R1 ‘B) ⋀ A ∈ (R1 ‘suc B)))) | |||
| Theorem | ssrankr1 4659 | A relationship between an ordinal number less than or equal to a rank, and the cumulative hierarchy of sets R1. Proposition 9.15(3) of [TakeutiZaring] p. 79. | |
| ⊢ A ∈ V ⇒ ⊢ (B ∈ On → (B ⊆ (rank ‘A) ↔ ¬ A ∈ (R1 ‘B))) | |||
| Theorem | rankr1a 4660 | A relationship between rank and R1, clearly equivalent to ssrankr1 4659 and friends through trichotomy, but in Raph's opinion considerably more intuitive. See rankr1b 4682 for the subset verion. (Contributed by Raph Levien, 29-May-2004.) | |
| ⊢ A ∈ V ⇒ ⊢ (B ∈ On → (A ∈ (R1 ‘B) ↔ (rank ‘A) ∈ B)) | |||
| Theorem | r1val2 4661 | The value of the cumulative hierarchy of sets function expressed in terms of rank. Definition 15.19 of [Monk1] p. 113. | |
| ⊢ (A ∈ On → (R1 ‘A) = {x∣(rank ‘x) ∈ A}) | |||
| Theorem | r1val3 4662 | The value of the cumulative hierarchy of sets function expressed in terms of rank. Theorem 15.18 of [Monk1] p. 113. | |
| ⊢ (A ∈ On → (R1 ‘A) = ∪x ∈ A ℘{y∣(rank ‘y) ∈ x}) | |||
| Theorem | rankel 4663 | The membership relation is inherited by the rank function. Proposition 9.16 of [TakeutiZaring] p. 79. | |
| ⊢ B ∈ V ⇒ ⊢ (A ∈ B → (rank ‘A) ∈ (rank ‘B)) | |||
| Theorem | rankval3 4664 | The value of the rank function expressed recursively: the rank of a set is the smallest ordinal number containing the ranks of all members of the set. Proposition 9.17 of [TakeutiZaring] p. 79. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘A) = ∩{x ∈ On∣∀y ∈ A (rank ‘y) ∈ x} | |||
| Theorem | bndrank 4665 | Any class whose elements have bounded rank is a set. Proposition 9.19 of [TakeutiZaring] p. 80. | |
| ⊢ (∃x ∈ On ∀y ∈ A (rank ‘y) ⊆ x → A ∈ V) | |||
| Theorem | unbndrank 4666 | The elements of a proper class have unbounded rank. Exercise 2 of [TakeutiZaring] p. 80. | |
| ⊢ (¬ A ∈ V → ∀x ∈ On ∃y ∈ A x ∈ (rank ‘y)) | |||
| Theorem | rankpw 4667 | The rank of a power set. Part of Exercise 30 of [Enderton] p. 207. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘℘A) = suc (rank ‘A) | |||
| Theorem | ranklim 4668 | The rank of a set belongs to a limit ordinal iff the rank of its power set does. | |
| ⊢ (Lim B → ((rank ‘A) ∈ B ↔ (rank ‘℘A) ∈ B)) | |||
| Theorem | r1pw 4669 | A stronger property of R1 than rankpw 4667. The latter merely proves that R1 of the successor is a power set, but here we prove that if A is in the cumulative hierarchy, then ℘A is in the cumulative hierarchy of the successor. (Contributed by Raph Levien, 29-May-2004.) | |
| ⊢ (B ∈ On → (A ∈ (R1 ‘B) ↔ ℘A ∈ (R1 ‘suc B))) | |||
| Theorem | r1pwcl 4670 | The cumulative hierarchy of a limit ordinal is closed under power set. (Contributed by Raph Levien, 29-May-2004.) | |
| ⊢ (Lim B → (A ∈ (R1 ‘B) ↔ ℘A ∈ (R1 ‘B))) | |||
| Theorem | rankss 4671 | The subset relation is inherited by the rank function. Exercise 1 of [TakeutiZaring] p. 80. | |
| ⊢ B ∈ V ⇒ ⊢ (A ⊆ B → (rank ‘A) ⊆ (rank ‘B)) | |||
| Theorem | ranksn 4672 | The rank of a singleton. Theorem 15.17(v) of [Monk1] p. 112. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘{A}) = suc (rank ‘A) | |||
| Theorem | rankuni2 4673 | The rank of a union. Part of Theorem 15.17(iv) of [Monk1] p. 112. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘∪A) = ∪x ∈ A (rank ‘x) | |||
| Theorem | rankun 4674 | The rank of the union of two sets. Theorem 15.17(iii) of [Monk1] p. 112. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (rank ‘(A ∪ B)) = ((rank ‘A) ∪ (rank ‘B)) | |||
| Theorem | rankpr 4675 | The rank of an unordered pair. Part of Exercise 30 of [Enderton] p. 207. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (rank ‘{A, B}) = suc ((rank ‘A) ∪ (rank ‘B)) | |||
| Theorem | rankop 4676 | The rank of an ordered pair. Part of Exercise 4 of [Kunen] p. 107. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (rank ‘⟨A, B⟩) = suc suc ((rank ‘A) ∪ (rank ‘B)) | |||
| Theorem | r1rankid 4677 | Any set is a subset of the hierarchy of its rank. | |
| ⊢ (A ∈ B → A ⊆ (R1 ‘(rank ‘A))) | |||
| Theorem | rankonid 4678 | The rank of an ordinal number is itself. Proposition 9.18 of [TakeutiZaring] p. 79 and its converse. | |
| ⊢ (A ∈ On ↔ (rank ‘A) = A) | |||
| Theorem | rankeq0 4679 | A set is empty iff its rank is empty. | |
| ⊢ A ∈ V ⇒ ⊢ (A = ∅ ↔ (rank ‘A) = ∅) | |||
| Theorem | rankr1id 4680 | The rank of the hierarchy of an ordinal number is itself. | |
| ⊢ (A ∈ On ↔ (rank ‘(R1 ‘A)) = A) | |||
| Theorem | rankuni 4681 | The rank of a union. Part of Exercise 4 of [Kunen] p. 107. | |
| ⊢ (rank ‘∪A) = ∪(rank ‘A) | |||
| Theorem | rankr1b 4682 | A relationship between rank and R1. See rankr1a 4660 for the membership version. | |
| ⊢ A ∈ V ⇒ ⊢ (B ∈ On → (A ⊆ (R1 ‘B) ↔ (rank ‘A) ⊆ B)) | |||
| Theorem | ranksuc 4683 | The rank of a successor. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘suc A) = suc (rank ‘A) | |||
| Theorem | rankuniss 4684 | Upper bound of the rank of a union. Part of Exercise 30 of [Enderton] p. 207. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘∪A) ⊆ (rank ‘A) | |||
| Theorem | rankval4 4685 | The rank of a set is the supremum of the successors of the ranks of its members. Exercise 9.1 of [Jech] p. 72. Also a special case of Theorem 7V(b) of [Enderton] p. 204. | |
| ⊢ A ∈ V ⇒ ⊢ (rank ‘A) = ∪x ∈ A suc (rank ‘x) | |||
| Theorem | rankbnd 4686 | The rank of a set is bounded by a bound for the successor of its members. | |
| ⊢ A ∈ V ⇒ ⊢ (∀x ∈ A suc (rank ‘x) ⊆ B ↔ (rank ‘A) ⊆ B) | |||
| Theorem | rankbnd2 4687 | The rank of a set is bounded by the successor of a bound for its members. | |
| ⊢ A ∈ V ⇒ ⊢ (B ∈ On → (∀x ∈ A (rank ‘x) ⊆ B ↔ (rank ‘A) ⊆ suc B)) | |||
| Theorem | rankc1 4688 | A relationship that can be used for computation of rank. | |
| ⊢ A ∈ V ⇒ ⊢ (∀x ∈ A (rank ‘x) ∈ (rank ‘∪A) ↔ (rank ‘A) = (rank ‘∪A)) | |||
| Theorem | rankc2 4689 | A relationship that can be used for computation of rank. | |
| ⊢ A ∈ V ⇒ ⊢ (∃x ∈ A (rank ‘x) = (rank ‘∪A) → (rank ‘A) = suc (rank ‘∪A)) | |||
| Theorem | rankelun 4690 | Rank membership is inherited by union. | |
| ⊢ A ∈ V & ⊢ B ∈ V & ⊢ C ∈ V & ⊢ D ∈ V ⇒ ⊢ (((rank ‘A) ∈ (rank ‘C) ⋀ (rank ‘B) ∈ (rank ‘D)) → (rank ‘(A ∪ B)) ∈ (rank ‘(C ∪ D))) | |||
| Theorem | rankelpr 4691 | Rank membership is inherited by unordered pairs. | |
| ⊢ A ∈ V & ⊢ B ∈ V & ⊢ C ∈ V & ⊢ D ∈ V ⇒ ⊢ (((rank ‘A) ∈ (rank ‘C) ⋀ (rank ‘B) ∈ (rank ‘D)) → (rank ‘{A, B}) ∈ (rank ‘{C, D})) | |||
| Theorem | rankelop 4692 | Rank membership is inherited by ordered pairs. | |
| ⊢ A ∈ V & ⊢ B ∈ V & ⊢ C ∈ V & ⊢ D ∈ V ⇒ ⊢ (((rank ‘A) ∈ (rank ‘C) ⋀ (rank ‘B) ∈ (rank ‘D)) → (rank ‘⟨A, B⟩) ∈ (rank ‘⟨C, D⟩)) | |||
| Theorem | rankxpl 4693 | A lower bound on the rank of a cross product. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ ((A × B) ≠ ∅ → (rank ‘(A ∪ B)) ⊆ (rank ‘(A × B))) | |||
| Theorem | rankxpu 4694 | An upper bound on the rank of a cross product. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (rank ‘(A × B)) ⊆ suc suc (rank ‘(A ∪ B)) | |||
| Theorem | rankxplim 4695 | The rank of a cross product when the rank of the union of its arguments is a limit ordinal. Part of Exercise 4 of [Kunen] p. 107. See rankxpsuc 4698 for the successor case. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ ((Lim (rank ‘(A ∪ B)) ⋀ (A × B) ≠ ∅) → (rank ‘(A × B)) = (rank ‘(A ∪ B))) | |||
| Theorem | rankxplim2 4696 | If the rank of a cross product is a limit ordinal, so is the rank of the union of its arguments. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (Lim (rank ‘(A × B)) → Lim (rank ‘(A ∪ B))) | |||
| Theorem | rankxplim3 4697 | The rank of a cross product is a limit ordinal iff its union is. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (Lim (rank ‘(A × B)) ↔ Lim ∪(rank ‘(A × B))) | |||
| Theorem | rankxpsuc 4698 | The rank of a cross product when the rank of the union of its arguments is a successor ordinal. Part of Exercise 4 of [Kunen] p. 107. See rankxplim 4695 for the limit ordinal case. | |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ (((rank ‘(A ∪ B)) = suc C ⋀ (A × B) ≠ ∅) → (rank ‘(A × B)) = suc suc (rank ‘(A ∪ B))) | |||
| Scott's trick; collection principle; Hilbert's epsilon | |||
| Theorem | scottex 4699 | Scott's trick collects all sets that have a certain property and are of smallest possible rank. This theorem shows that the resulting collection, expressed as in Equation 9.3 of [Jech] p. 72, is a set. | |
| ⊢ {x ∈ A∣∀y ∈ A (rank ‘x) ⊆ (rank ‘y)} ∈ V | |||
| Theorem | scott0 4700 | Scott's trick collects all sets that have a certain property and are of smallest possible rank. This theorem shows that the resulting collection, expressed as in Equation 9.3 of [Jech] p. 72, contains at least one representative with the property, if there is one. In other words, the collection is empty iff no set has the property (i.e. A is empty). | |
| ⊢ (A = ∅ ↔ {x ∈ A∣∀y ∈ A (rank ‘x) ⊆ (rank ‘y)} = ∅) | |||
| MPE Home Contents | Copyright terms: Public domain | < Previous Next > |