Proof of Nuprl Lemma : fset-ac-le-distributive-constrained

Step * 1 3 1 1 1 of Lemma fset-ac-le-distributive-constrained

1. T : Type
2. eq : EqDecider(T)
3. P : fset(T) ⟶ 𝔹
4. ∀x,y:fset(T).  (y ⊆ x ⇒ (↑(P x)) ⇒ (↑(P y)))
5. a : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
6. b : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
7. c : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
8. fset-ac-le(eq;glb(P;a;c);glb(P;a;lub(P;b;c)))
9. x : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
10. ∀a1:fset(T). (a1 ∈ glb(P;a;b) ⇒ (¬({y ∈ x | deq-f-subset(eq) y a1} = {} ∈ fset(fset(T)))))
11. ∀a1:fset(T). (a1 ∈ glb(P;a;c) ⇒ (¬({y ∈ x | deq-f-subset(eq) y a1} = {} ∈ fset(fset(T)))))
12. x@0 : fset(T)
13. as : fset(T)
14. as ∈ a
15. x1 : fset(T)
16. x1 ∈ lub(P;b;c)
17. x@0 = as ⋃ x1 ∈ fset(T)
18. ↑(P x@0)
19. ∀[ys:fset(T)]
      ↑¬_bf-proper-subset-dec(eq;ys;x@0)
      supposing ys ∈ f-union(deq-fset(eq);deq-fset(eq);a;as.λbs.as ⋃ bs"(lub(P;b;c)) s.t. P)
20. {y ∈ x | deq-f-subset(eq) y x@0} = {} ∈ fset(fset(T))
⊢ False
BY
{ (RenameVar `xx' (-9)
   THEN (Assert ∀[ys:fset(T)]. ¬ys ⋃ x1 ⊆≠ xx supposing ys ∈ a ∧ (↑(P ys ⋃ x1)) BY
               (Auto
                THEN InstHyp [⌜ys ⋃ x1⌝] 19⋅
                THEN Auto
                THEN RW assert_pushdownC (-1)
                THEN Auto
                THEN BLemma `member-f-union`
                THEN Auto
                THEN D 0
                THEN With ⌜ys⌝ (D 0)⋅
                THEN Auto
                THEN BLemma `member-fset-constrained-image-iff`
                THEN Auto))
   ) }

1
1. T : Type
2. eq : EqDecider(T)
3. P : fset(T) ⟶ 𝔹
4. ∀x,y:fset(T).  (y ⊆ x ⇒ (↑(P x)) ⇒ (↑(P y)))
5. a : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
6. b : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
7. c : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
8. fset-ac-le(eq;glb(P;a;c);glb(P;a;lub(P;b;c)))
9. x : {ac:fset(fset(T))| (↑fset-antichain(eq;ac)) ∧ fset-all(ac;a.P[a])}
10. ∀a1:fset(T). (a1 ∈ glb(P;a;b) ⇒ (¬({y ∈ x | deq-f-subset(eq) y a1} = {} ∈ fset(fset(T)))))
11. ∀a1:fset(T). (a1 ∈ glb(P;a;c) ⇒ (¬({y ∈ x | deq-f-subset(eq) y a1} = {} ∈ fset(fset(T)))))
12. xx : fset(T)
13. as : fset(T)
14. as ∈ a
15. x1 : fset(T)
16. x1 ∈ lub(P;b;c)
17. xx = as ⋃ x1 ∈ fset(T)
18. ↑(P xx)
19. ∀[ys:fset(T)]
      ↑¬_bf-proper-subset-dec(eq;ys;xx)
      supposing ys ∈ f-union(deq-fset(eq);deq-fset(eq);a;as.λbs.as ⋃ bs"(lub(P;b;c)) s.t. P)
20. {y ∈ x | deq-f-subset(eq) y xx} = {} ∈ fset(fset(T))
21. ∀[ys:fset(T)]. ¬ys ⋃ x1 ⊆≠ xx supposing ys ∈ a ∧ (↑(P ys ⋃ x1))
⊢ False

Latex:

Latex:
1. T : Type 2. eq : EqDecider(T) 3. P : fset(T) {}\mrightarrow{} \mBbbB{} 4. \mforall{}x,y:fset(T). (y \msubseteq{} x {}\mRightarrow{} (\muparrow{}(P x)) {}\mRightarrow{} (\muparrow{}(P y))) 5. a : \{ac:fset(fset(T))| (\muparrow{}fset-antichain(eq;ac)) \mwedge{} fset-all(ac;a.P[a])\} 6. b : \{ac:fset(fset(T))| (\muparrow{}fset-antichain(eq;ac)) \mwedge{} fset-all(ac;a.P[a])\} 7. c : \{ac:fset(fset(T))| (\muparrow{}fset-antichain(eq;ac)) \mwedge{} fset-all(ac;a.P[a])\} 8. fset-ac-le(eq;glb(P;a;c);glb(P;a;lub(P;b;c))) 9. x : \{ac:fset(fset(T))| (\muparrow{}fset-antichain(eq;ac)) \mwedge{} fset-all(ac;a.P[a])\} 10. \mforall{}a1:fset(T). (a1 \mmember{} glb(P;a;b) {}\mRightarrow{} (\mneg{}(\{y \mmember{} x | deq-f-subset(eq) y a1\} = \{\}))) 11. \mforall{}a1:fset(T). (a1 \mmember{} glb(P;a;c) {}\mRightarrow{} (\mneg{}(\{y \mmember{} x | deq-f-subset(eq) y a1\} = \{\}))) 12. x@0 : fset(T) 13. as : fset(T) 14. as \mmember{} a 15. x1 : fset(T) 16. x1 \mmember{} lub(P;b;c) 17. x@0 = as \mcup{} x1 18. \muparrow{}(P x@0) 19. \mforall{}[ys:fset(T)] \muparrow{}\mneg{}\msubb{}f-proper-subset-dec(eq;ys;x@0) supposing ys \mmember{} f-union(deq-fset(eq);deq-fset(eq);a;as.\mlambda{}bs.as \mcup{} bs"(lub(P;b;c)) s.t. P) 20. \{y \mmember{} x | deq-f-subset(eq) y x@0\} = \{\} \mvdash{} False By Latex: (RenameVar `xx' (-9) THEN (Assert \mforall{}[ys:fset(T)]. \mneg{}ys \mcup{} x1 \msubseteq{}\mneq{} xx supposing ys \mmember{} a \mwedge{} (\muparrow{}(P ys \mcup{} x1)) BY (Auto THEN InstHyp [\mkleeneopen{}ys \mcup{} x1\mkleeneclose{}] 19\mcdot{} THEN Auto THEN RW assert\_pushdownC (-1) THEN Auto THEN BLemma `member-f-union` THEN Auto THEN D 0 THEN With \mkleeneopen{}ys\mkleeneclose{} (D 0)\mcdot{} THEN Auto THEN BLemma `member-fset-constrained-image-iff` THEN Auto)) ) Home Index