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
(1-8729)
|
Hilbert Space Explorer
(8730-10658)
|
| Type | Label | Description |
|---|---|---|
| Statement | ||
| Theorem | ssne0 2301 | A class with a nonempty subclass is nonempty. |
| ⊢ ((A ⊆ B ⋀ A ≠ ∅) → B ≠ ∅) | ||
| Theorem | un00 2302 | Two classes are empty iff their union is empty. |
| ⊢ ((A = ∅ ⋀ B = ∅) ↔ (A ∪ B) = ∅) | ||
| Theorem | vss 2303 | Only the universal class has the universal class as a subclass. |
| ⊢ (V ⊆ A ↔ A = V) | ||
| Theorem | 0pss 2304 | The null set is a proper subset of any non-empty set. |
| ⊢ (∅ ⊂ A ↔ A ≠ ∅) | ||
| Theorem | npss0 2305 | No set is a proper subset of the empty set. |
| ⊢ ¬ A ⊂ ∅ | ||
| Theorem | pssv 2306 | Any non-universal class is a proper subclass of the universal class. |
| ⊢ (A ⊂ V ↔ ¬ A = V) | ||
| Theorem | disj 2307 | Two ways of saying that two classes are disjoint (have no members in common). |
| ⊢ ((A ∩ B) = ∅ ↔ ∀x ∈ A ¬ x ∈ B) | ||
| Theorem | disj1 2308 | Two ways of saying that two classes are disjoint (have no members in common). |
| ⊢ ((A ∩ B) = ∅ ↔ ∀x(x ∈ A → ¬ x ∈ B)) | ||
| Theorem | reldisj 2309 | Two ways of saying that two classes are disjoint, using the complement of B relative to a universe C. |
| ⊢ (A ⊆ C → ((A ∩ B) = ∅ ↔ A ⊆ (C ∖ B))) | ||
| Theorem | disj3 2310 | Two ways of saying that two classes are disjoint. |
| ⊢ ((A ∩ B) = ∅ ↔ A = (A ∖ B)) | ||
| Theorem | disjne 2311 | Members of disjoint sets are not equal. |
| ⊢ (((A ∩ B) = ∅ ⋀ C ∈ A ⋀ D ∈ B) → C ≠ D) | ||
| Theorem | disj2 2312 | Two ways of saying that two classes are disjoint. |
| ⊢ ((A ∩ B) = ∅ ↔ A ⊆ (V ∖ B)) | ||
| Theorem | disj4 2313 | Two ways of saying that two classes are disjoint. |
| ⊢ ((A ∩ B) = ∅ ↔ ¬ (A ∖ B) ⊂ A) | ||
| Theorem | ssdisj 2314 | Intersection with a subclass of a disjoint class. (Contributed by FL, 24-Jan-2007.) |
| ⊢ ((A ⊆ B ⋀ (B ∩ C) = ∅) → (A ∩ C) = ∅) | ||
| Theorem | disjpss 2315 | A class is a proper subset of its union with a disjoint nonempty class. |
| ⊢ (((A ∩ B) = ∅ ⋀ B ≠ ∅) → A ⊂ (A ∪ B)) | ||
| Theorem | undisj1 2316 | The union of disjoint classes is disjoint. |
| ⊢ (((A ∩ C) = ∅ ⋀ (B ∩ C) = ∅) ↔ ((A ∪ B) ∩ C) = ∅) | ||
| Theorem | undisj2 2317 | The union of disjoint classes is disjoint. |
| ⊢ (((A ∩ B) = ∅ ⋀ (A ∩ C) = ∅) ↔ (A ∩ (B ∪ C)) = ∅) | ||
| Theorem | ssindif0 2318 | Subclass expressed in terms of intersection with difference from the universal class. |
| ⊢ (A ⊆ B ↔ (A ∩ (V ∖ B)) = ∅) | ||
| Theorem | inelcm 2319 | The intersection of classes with a common member is nonempty. |
| ⊢ ((A ∈ B ⋀ A ∈ C) → (B ∩ C) ≠ ∅) | ||
| Theorem | minel 2320 | A minimum element of a class has no elements in common with the class. |
| ⊢ ((A ∈ B ⋀ (C ∩ B) = ∅) → ¬ A ∈ C) | ||
| Theorem | undif4 2321 | Distribute union over difference. |
| ⊢ ((A ∩ C) = ∅ → (A ∪ (B ∖ C)) = ((A ∪ B) ∖ C)) | ||
| Theorem | disjssun 2322 | Subset relation for disjoint classes. |
| ⊢ ((A ∩ B) = ∅ → (A ⊆ (B ∪ C) ↔ A ⊆ C)) | ||
| Theorem | ssdif0 2323 | Subclass expressed in terms of difference. Exercise 7 of [TakeutiZaring] p. 22. |
| ⊢ (A ⊆ B ↔ (A ∖ B) = ∅) | ||
| Theorem | vdif0 2324 | Universal class equality in terms of empty difference. |
| ⊢ (A = V ↔ (V ∖ A) = ∅) | ||
| Theorem | pssdifn0 2325 | A proper subclass has a nonempty difference. |
| ⊢ ((A ⊆ B ⋀ A ≠ B) → (B ∖ A) ≠ ∅) | ||
| Theorem | ssnelpss 2326 | A subclass missing a member is a proper subclass. |
| ⊢ (A ⊆ B → ((C ∈ B ⋀ ¬ C ∈ A) → A ⊂ B)) | ||
| Theorem | pssnel 2327 | A proper subclass has a member in one argument that's not in both. |
| ⊢ (A ⊂ B → ∃x(x ∈ B ⋀ ¬ x ∈ A)) | ||
| Theorem | difin0ss 2328 | Difference, intersection, and subclass relationship. |
| ⊢ (((A ∖ B) ∩ C) = ∅ → (C ⊆ A → C ⊆ B)) | ||
| Theorem | inssdif0 2329 | Intersection, subclass, and difference relationship. |
| ⊢ ((A ∩ B) ⊆ C ↔ (A ∩ (B ∖ C)) = ∅) | ||
| Theorem | difid 2330 | The difference between a class and itself is the empty set. Proposition 5.15 of [TakeutiZaring] p. 20. Also Theorem 32 of [Suppes] p. 28. |
| ⊢ (A ∖ A) = ∅ | ||
| Theorem | dif0 2331 | The difference between a class and the empty set. Part of Exercise 4.4 of [Stoll] p. 16. |
| ⊢ (A ∖ ∅) = A | ||
| Theorem | 0dif 2332 | The difference between the empty set and a class. Part of Exercise 4.4 of [Stoll] p. 16. |
| ⊢ (∅ ∖ A) = ∅ | ||
| Theorem | difdisj 2333 | A class and its relative complement are disjoint. Theorem 38 of [Suppes] p. 29. |
| ⊢ (A ∩ (B ∖ A)) = ∅ | ||
| Theorem | difin0 2334 | The difference of a class from its intersection is empty. Theorem 37 of [Suppes] p. 29. |
| ⊢ ((A ∩ B) ∖ B) = ∅ | ||
| Theorem | undifv 2335 | The union of a class and its complement is the universe. Theorem 5.1(5) of [Stoll] p. 17. |
| ⊢ (A ∪ (V ∖ A)) = V | ||
| Theorem | undif1 2336 | Absorption of difference by union. This decomposes a union into two disjoint classes (see difdisj 2333). Theorem 35 of [Suppes] p. 29. |
| ⊢ ((A ∖ B) ∪ B) = (A ∪ B) | ||
| Theorem | undif2 2337 | Absorption of difference by union. This decomposes a union into two disjoint classes (see difdisj 2333). Part of proof of Corollary 6K of [Enderton] p. 144. |
| ⊢ (A ∪ (B ∖ A)) = (A ∪ B) | ||
| Theorem | difun2 2338 | Absorption of union by difference. Theorem 36 of [Suppes] p. 29. |
| ⊢ ((A ∪ B) ∖ B) = (A ∖ B) | ||
| Theorem | undif 2339 | Union of complementary parts into whole. |
| ⊢ (A ⊆ B ↔ (A ∪ (B ∖ A)) = B) | ||
| Theorem | ssundif 2340 | A condition equivalent to inclusion in the union of two classes. |
| ⊢ (A ⊆ (B ∪ C) ↔ (A ∖ B) ⊆ C) | ||
| Theorem | difcom 2341 | Swap the arguments of a class difference. |
| ⊢ ((A ∖ B) ⊆ C ↔ (A ∖ C) ⊆ B) | ||
| Theorem | difdifdir 2342 | Distributive law for class difference. Exercise 4.8 of [Stoll] p. 16. |
| ⊢ ((A ∖ B) ∖ C) = ((A ∖ C) ∖ (B ∖ C)) | ||
| Theorem | r19.2z 2343 | Theorem 19.2 of [Margaris] p. 89 with restricted quantifiers (compare 19.2 1028). The restricted version is valid only when the domain of quantification is not empty. |
| ⊢ ((A ≠ ∅ ⋀ ∀x ∈ A φ) → ∃x ∈ A φ) | ||
| Theorem | r19.3rzv 2344 | Restricted quantification of wff not containing quantified variable. |
| ⊢ (A ≠ ∅ → (φ ↔ ∀x ∈ A φ)) | ||
| Theorem | r19.9rzv 2345 | Restricted quantification of wff not containing quantified variable. |
| ⊢ (A ≠ ∅ → (φ ↔ ∃x ∈ A φ)) | ||
| Theorem | r19.28zv 2346 | Restricted quantifier version of Theorem 19.28 of [Margaris] p. 90. It is valid only when the domain of quantification is not empty. |
| ⊢ (A ≠ ∅ → (∀x ∈ A (φ ⋀ ψ) ↔ (φ ⋀ ∀x ∈ A ψ))) | ||
| Theorem | r19.37zv 2347 | Restricted quantifier version of Theorem 19.37 of [Margaris] p. 90. It is valid only when the domain of quantification is not empty. (Contributed by Paul Chapman, 8-Oct-2007.) |
| ⊢ (A ≠ ∅ → (∃x ∈ A (φ → ψ) ↔ (φ → ∃x ∈ A ψ))) | ||
| Theorem | r19.45zv 2348 | Restricted version of Theorem 19.45 of [Margaris] p. 90. |
| ⊢ (A ≠ ∅ → (∃x ∈ A (φ ⋁ ψ) ↔ (φ ⋁ ∃x ∈ A ψ))) | ||
| Theorem | r19.27zv 2349 | Restricted quantifier version of Theorem 19.27 of [Margaris] p. 90. It is valid only when the domain of quantification is not empty. |
| ⊢ (A ≠ ∅ → (∀x ∈ A (φ ⋀ ψ) ↔ (∀x ∈ A φ ⋀ ψ))) | ||
| Theorem | r19.36zv 2350 | Restricted quantifier version of Theorem 19.36 of [Margaris] p. 90. It is valid only when the domain of quantification is not empty. |
| ⊢ (A ≠ ∅ → (∃x ∈ A (φ → ψ) ↔ (∀x ∈ A φ → ψ))) | ||
| Theorem | rzal 2351 | Vacuous quantification is always true. |
| ⊢ (A = ∅ → ∀x ∈ A φ) | ||
| Theorem | rexn0 2352 | Restricted existential quantification implies its restriction is nonempty. (Contributed by Szymon Jaroszewicz, 3-Apr-2007.) |
| ⊢ (∃x ∈ A φ → A ≠ ∅) | ||
| Theorem | ralidm 2353 | Idempotent law for restricted quantifier. |
| ⊢ (∀x ∈ A ∀x ∈ A φ ↔ ∀x ∈ A φ) | ||
| Theorem | ral0 2354 | Vacuous universal quantification is always true. |
| ⊢ ∀x ∈ ∅ φ | ||
| Theorem | ralf0 2355 | The quantification of a falsehood is vacuous when true. |
| ⊢ ¬ φ ⇒ ⊢ (∀x ∈ A φ ↔ A = ∅) | ||
| Theorem | raaan 2356 | Rearrange restricted quantifiers. |
| ⊢ (∀x ∈ A ∀y ∈ A (φ ⋀ ψ) ↔ (∀x ∈ A φ ⋀ ∀y ∈ A ψ)) | ||
| "Weak deduction theorem" for set theory | ||
| Syntax | cif 2357 | Extend class notation to include the conditional operator. See df-if 2358 for a description. (In older databases this was denoted "ded".) |
| class if(φ, A, B) | ||
| Definition | df-if 2358 |
Define the conditional operator. Read if(φ, A,
B) as "if
φ then A else B."
See iftrue 2362 and iffalse 2363 for its
values. In mathematical literature, this operator is rarely defined
formally but is implicit in informal definitions such as "let
f(x)=0 if
x=0 and 1/x otherwise." (In older versions of this database, this
operator was denoted "ded" and called the "deduction
class.")
An important use for us is in conjunction with the weak deduction theorem, which converts a hypothesis into an antecedent. In that role, A is a class variable in the hypothesis and B is a class (usually a constant) that makes the hypothesis true when it is substituted for A. See dedth 2379 for the main part of the weak deduction theorem, elimhyp 2386 to eliminate a hypothesis, and keephyp 2392 to keep a hypothesis. See the Deduction Theorem link on the Metamath Proof Explorer Home Page for a description of the weak deduction theorem. |
| ⊢ if(φ, A, B) = {x∣((x ∈ A ⋀ φ) ⋁ (x ∈ B ⋀ ¬ φ))} | ||
| Theorem | dfif2 2359 | An alternate definition of the conditional operator df-if 2358 with one fewer connectives (but probably less intuitive to understand). |
| ⊢ if(φ, A, B) = {x∣((x ∈ B → φ) → (x ∈ A ⋀ φ))} | ||
| Theorem | ifeq1 2360 | Equality theorem for conditional operator. |
| ⊢ (A = B → if(φ, A, C) = if(φ, B, C)) | ||
| Theorem | ifeq2 2361 | Equality theorem for conditional operator. |
| ⊢ (A = B → if(φ, C, A) = if(φ, C, B)) | ||
| Theorem | iftrue 2362 | Value of the conditional operator when its first argument is true. |
| ⊢ (φ → if(φ, A, B) = A) | ||
| Theorem | iffalse 2363 | Value of the conditional operator when its first argument is false. |
| ⊢ (¬ φ → if(φ, A, B) = B) | ||
| Theorem | ifeq12 2364 | Equality theorem for conditional operators. |
| ⊢ ((A = B ⋀ C = D) → if(φ, A, C) = if(φ, B, D)) | ||
| Theorem | ifeq1d 2365 | Equality deduction for conditional operator. |
| ⊢ (φ → A = B) ⇒ ⊢ (φ → if(ψ, A, C) = if(ψ, B, C)) | ||
| Theorem | ifeq2d 2366 | Equality deduction for conditional operator. |
| ⊢ (φ → A = B) ⇒ ⊢ (φ → if(ψ, C, A) = if(ψ, C, B)) | ||
| Theorem | ifbi 2367 | Equivalence theorem for conditional operators. (Contributed by Raph Levien, 15-Jan-2004.) |
| ⊢ ((φ ↔ ψ) → if(φ, A, B) = if(ψ, A, B)) | ||
| Theorem | ifbid 2368 | Equivalence deduction for conditional operators. |
| ⊢ (φ → (ψ ↔ χ)) ⇒ ⊢ (φ → if(ψ, A, B) = if(χ, A, B)) | ||
| Theorem | hbif 2369 | Bound-variable hypothesis builder for a conditional operator. |
| ⊢ (φ → ∀xφ) & ⊢ (y ∈ A → ∀x y ∈ A) & ⊢ (y ∈ B → ∀x y ∈ B) ⇒ ⊢ (y ∈ if(φ, A, B) → ∀x y ∈ if(φ, A, B)) | ||
| Theorem | elimif 2370 | Elimination of a conditional operator contained in a wff ψ. |
| ⊢ ( if(φ, A, B) = A → (ψ ↔ χ)) & ⊢ ( if(φ, A, B) = B → (ψ ↔ θ)) ⇒ ⊢ (ψ ↔ ((φ ⋀ χ) ⋁ (¬ φ ⋀ θ))) | ||
| Theorem | ifboth 2371 | A wff θ containing a conditional operator is true when both of its cases are true. |
| ⊢ (A = if(φ, A, B) → (ψ ↔ θ)) & ⊢ (B = if(φ, A, B) → (χ ↔ θ)) ⇒ ⊢ ((ψ ⋀ χ) → θ) | ||
| Theorem | ifid 2372 | Identical true and false arguments in the conditional operator. |
| ⊢ if(φ, A, A) = A | ||
| Theorem | eqif 2373 | Expansion of an equality with a conditional operator. |
| ⊢ (A = if(φ, B, C) ↔ ((φ ⋀ A = B) ⋁ (¬ φ ⋀ A = C))) | ||
| Theorem | elif 2374 | Membership in a conditional operator. |
| ⊢ (A ∈ if(φ, B, C) ↔ ((φ ⋀ A ∈ B) ⋁ (¬ φ ⋀ A ∈ C))) | ||
| Theorem | ifel 2375 | Membership of a conditional operator. |
| ⊢ ( if(φ, A, B) ∈ C ↔ ((φ ⋀ A ∈ C) ⋁ (¬ φ ⋀ B ∈ C))) | ||
| Theorem | ifcl 2376 | Membership (closure) of a conditional operator. |
| ⊢ ((A ∈ C ⋀ B ∈ C) → if(φ, A, B) ∈ C) | ||
| Theorem | ifor 2377 | The possible values of a conditional operator. |
| ⊢ ( if(φ, A, B) = A ⋁ if(φ, A, B) = B) | ||
| Theorem | ifswap 2378 | Negating the first argument swaps the last two arguments of a conditional operator. |
| ⊢ if(¬ φ, A, B) = if(φ, B, A) | ||
| Theorem | dedth 2379 | Weak deduction theorem that eliminates a hypothesis φ, making it become an antecedent. We assume that a proof exists for φ when the class variable A is replaced with a specific class B. The hypothesis χ should be assigned to the inference, and the inference's hypothesis eliminated with elimhyp 2386. If the inference has other hypotheses with class variable A, these can be kept by assigning keephyp 2392 to them. For more information, see the Deduction Theorem http://us.metamath.org/mpegif/mmdeduction.html. |
| ⊢ (A = if(φ, A, B) → (ψ ↔ χ)) & ⊢ χ ⇒ ⊢ (φ → ψ) | ||
| Theorem | dedth2v 2380 | Weak deduction theorem for eliminating a hypothesis with 2 class variables. Note: if the hypothesis can be separated into two hypotheses, each with one class variable, then dedth2h 2383 is simpler to use. See also comments in dedth 2379. |
| ⊢ (A = if(φ, A, C) → (ψ ↔ χ)) & ⊢ (B = if(φ, B, D) → (χ ↔ θ)) & ⊢ θ ⇒ ⊢ (φ → ψ) | ||
| Theorem | dedth3v 2381 | Weak deduction theorem for eliminating a hypothesis with 3 class variables. See comments in dedth2v 2380. |
| ⊢ (A = if(φ, A, D) → (ψ ↔ χ)) & ⊢ (B = if(φ, B, R) → (χ ↔ θ)) & ⊢ (C = if(φ, C, S) → (θ ↔ τ)) & ⊢ τ ⇒ ⊢ (φ → ψ) | ||
| Theorem | dedth4v 2382 | Weak deduction theorem for eliminating a hypothesis with 4 class variables. See comments in dedth2v 2380. |
| ⊢ (A = if(φ, A, R) → (ψ ↔ χ)) & ⊢ (B = if(φ, B, S) → (χ ↔ θ)) & ⊢ (C = if(φ, C, T) → (θ ↔ τ)) & ⊢ (D = if(φ, D, U) → (τ ↔ η)) & ⊢ η ⇒ ⊢ (φ → ψ) | ||
| Theorem | dedth2h 2383 | Weak deduction theorem eliminating two hypotheses. This theorem is simpler to use than dedth2v 2380 but requires that each hypothesis has exactly one class variable. See also comments in dedth 2379. |
| ⊢ (A = if(φ, A, C) → (χ ↔ θ)) & ⊢ (B = if(ψ, B, D) → (θ ↔ τ)) & ⊢ τ ⇒ ⊢ ((φ ⋀ ψ) → χ) | ||
| Theorem | dedth3h 2384 | Weak deduction theorem eliminating three hypotheses. See comments in dedth2h 2383. |
| ⊢ (A = if(φ, A, D) → (θ ↔ τ)) & ⊢ (B = if(ψ, B, R) → (τ ↔ η)) & ⊢ (C = if(χ, C, S) → (η ↔ ζ)) & ⊢ ζ ⇒ ⊢ ((φ ⋀ ψ ⋀ χ) → θ) | ||
| Theorem | dedth4h 2385 | Weak deduction theorem eliminating four hypotheses. See comments in dedth2h 2383. |
| ⊢ (A = if(φ, A, R) → (τ ↔ η)) & ⊢ (B = if(ψ, B, S) → (η ↔ ζ)) & ⊢ (C = if(χ, C, F) → (ζ ↔ σ)) & ⊢ (D = if(θ, D, G) → (σ ↔ ρ)) & ⊢ ρ ⇒ ⊢ (((φ ⋀ ψ) ⋀ (χ ⋀ θ)) → τ) | ||
| Theorem | elimhyp 2386 | Eliminate a hypothesis containing class variable A when it is known for a specific class B. For more information, see comments in dedth 2379. |
| ⊢ (A = if(φ, A, B) → (φ ↔ ψ)) & ⊢ (B = if(φ, A, B) → (χ ↔ ψ)) & ⊢ χ ⇒ ⊢ ψ | ||
| Theorem | elimhyp2v 2387 | Eliminate a hypothesis containing 2 class variables. |
| ⊢ (A = if(φ, A, C) → (φ ↔ χ)) & ⊢ (B = if(φ, B, D) → (χ ↔ θ)) & ⊢ (C = if(φ, A, C) → (τ ↔ η)) & ⊢ (D = if(φ, B, D) → (η ↔ θ)) & ⊢ τ ⇒ ⊢ θ | ||
| Theorem | elimhyp3v 2388 | Eliminate a hypothesis containing 3 class variables. |
| ⊢ (A = if(φ, A, D) → (φ ↔ χ)) & ⊢ (B = if(φ, B, R) → (χ ↔ θ)) & ⊢ (C = if(φ, C, S) → (θ ↔ τ)) & ⊢ (D = if(φ, A, D) → (η ↔ ζ)) & ⊢ (R = if(φ, B, R) → (ζ ↔ σ)) & ⊢ (S = if(φ, C, S) → (σ ↔ τ)) & ⊢ η ⇒ ⊢ τ | ||
| Theorem | elimhyp4v 2389 | Eliminate a hypothesis containing 4 class variables (for use with the weak deduction theorem dedth 2379). |
| ⊢ (A = if(φ, A, D) → (φ ↔ χ)) & ⊢ (B = if(φ, B, R) → (χ ↔ θ)) & ⊢ (C = if(φ, C, S) → (θ ↔ τ)) & ⊢ (F = if(φ, F, G) → (τ ↔ ψ)) & ⊢ (D = if(φ, A, D) → (η ↔ ζ)) & ⊢ (R = if(φ, B, R) → (ζ ↔ σ)) & ⊢ (S = if(φ, C, S) → (σ ↔ ρ)) & ⊢ (G = if(φ, F, G) → (ρ ↔ ψ)) & ⊢ η ⇒ ⊢ ψ | ||
| Theorem | elimel 2390 | Eliminate a membership hypothesis for weak deduction theorem, when special case B ∈ C is provable. |
| ⊢ B ∈ C ⇒ ⊢ if(A ∈ C, A, B) ∈ C | ||
| Theorem | elimdhyp 2391 | Version of elimhyp 2386 where the hypothesis is deduced from the final antecedent. See ghomgrplem 10328 for an example of its use. (Contributed by Paul Chapman, 25-Mar-2008.) |
| ⊢ (φ → ψ) & ⊢ (A = if(φ, A, B) → (ψ ↔ χ)) & ⊢ (B = if(φ, A, B) → (θ ↔ χ)) & ⊢ θ ⇒ ⊢ χ | ||
| Theorem | keephyp 2392 | Transform a hypothesis ψ that we want to keep (but contains the same class variable A used in the eliminated hypothesis) for use with the weak deduction theorem. |
| ⊢ (A = if(φ, A, B) → (ψ ↔ θ)) & ⊢ (B = if(φ, A, B) → (χ ↔ θ)) & ⊢ ψ & ⊢ χ ⇒ ⊢ θ | ||
| Theorem | keephyp2v 2393 | Keep a hypothesis containing 2 class variables (for use with the weak deduction theorem dedth 2379). |
| ⊢ (A = if(φ, A, C) → (ψ ↔ χ)) & ⊢ (B = if(φ, B, D) → (χ ↔ θ)) & ⊢ (C = if(φ, A, C) → (τ ↔ η)) & ⊢ (D = if(φ, B, D) → (η ↔ θ)) & ⊢ ψ & ⊢ τ ⇒ ⊢ θ | ||
| Theorem | keephyp3v 2394 | Keep a hypothesis containing 3 class variables. |
| ⊢ (A = if(φ, A, D) → (ρ ↔ χ)) & ⊢ (B = if(φ, B, R) → (χ ↔ θ)) & ⊢ (C = if(φ, C, S) → (θ ↔ τ)) & ⊢ (D = if(φ, A, D) → (η ↔ ζ)) & ⊢ (R = if(φ, B, R) → (ζ ↔ σ)) & ⊢ (S = if(φ, C, S) → (σ ↔ τ)) & ⊢ ρ & ⊢ η ⇒ ⊢ τ | ||
| Theorem | keepel 2395 | Keep a membership hypothesis for weak deduction theorem, when special case B ∈ C is provable. |
| ⊢ A ∈ C & ⊢ B ∈ C ⇒ ⊢ if(φ, A, B) ∈ C | ||
| Theorem | ifex 2396 | Conditional operator existence. |
| ⊢ A ∈ V & ⊢ B ∈ V ⇒ ⊢ if(φ, A, B) ∈ V | ||
| Power classes | ||
| Syntax | cpw 2397 | Extend class notation to include power class. (The tilde in the Metamath token is meant to suggest the calligraphic font of the P.) |
| class ℘A | ||
| Definition | df-pw 2398 | Define power class. Definition 5.10 of [TakeutiZaring] p. 17, but we also let it apply to proper classes, i.e. those that are not members of V. |
| ⊢ ℘A = {x∣x ⊆ A} | ||
| Theorem | pweq 2399 | Equality theorem for the power class. |
| ⊢ (A = B → ℘A = ℘B) | ||
| Theorem | elpw 2400 | Membership in a power class. Theorem 86 of [Suppes] p. 47. |
| ⊢ A ∈ V ⇒ ⊢ (A ∈ ℘B ↔ A ⊆ B) | ||
| MPE Home Contents | Copyright terms: Public domain | < Previous Next > |