(* Properties on negated basic relocation ***********************************)
-lemma nlift_lref_be_SO: â\88\80X,i. â\87§[i, 1] X ≡ #i → ⊥.
+lemma nlift_lref_be_SO: â\88\80X,i. â¬\86[i, 1] X ≡ #i → ⊥.
/2 width=7 by lift_inv_lref2_be/ qed-.
-lemma nlift_bind_sn: â\88\80W,d,e. (â\88\80V. â\87§[d, e] V ≡ W → ⊥) →
- â\88\80a,I,U. (â\88\80X. â\87§[d, e] X ≡ ⓑ{a,I}W.U → ⊥).
+lemma nlift_bind_sn: â\88\80W,d,e. (â\88\80V. â¬\86[d, e] V ≡ W → ⊥) →
+ â\88\80a,I,U. (â\88\80X. â¬\86[d, e] X ≡ ⓑ{a,I}W.U → ⊥).
#W #d #e #HW #a #I #U #X #H elim (lift_inv_bind2 … H) -H /2 width=2 by/
qed-.
-lemma nlift_bind_dx: â\88\80U,d,e. (â\88\80T. â\87§[d+1, e] T ≡ U → ⊥) →
- â\88\80a,I,W. (â\88\80X. â\87§[d, e] X ≡ ⓑ{a,I}W.U → ⊥).
+lemma nlift_bind_dx: â\88\80U,d,e. (â\88\80T. â¬\86[d+1, e] T ≡ U → ⊥) →
+ â\88\80a,I,W. (â\88\80X. â¬\86[d, e] X ≡ ⓑ{a,I}W.U → ⊥).
#U #d #e #HU #a #I #W #X #H elim (lift_inv_bind2 … H) -H /2 width=2 by/
qed-.
-lemma nlift_flat_sn: â\88\80W,d,e. (â\88\80V. â\87§[d, e] V ≡ W → ⊥) →
- â\88\80I,U. (â\88\80X. â\87§[d, e] X ≡ ⓕ{I}W.U → ⊥).
+lemma nlift_flat_sn: â\88\80W,d,e. (â\88\80V. â¬\86[d, e] V ≡ W → ⊥) →
+ â\88\80I,U. (â\88\80X. â¬\86[d, e] X ≡ ⓕ{I}W.U → ⊥).
#W #d #e #HW #I #U #X #H elim (lift_inv_flat2 … H) -H /2 width=2 by/
qed-.
-lemma nlift_flat_dx: â\88\80U,d,e. (â\88\80T. â\87§[d, e] T ≡ U → ⊥) →
- â\88\80I,W. (â\88\80X. â\87§[d, e] X ≡ ⓕ{I}W.U → ⊥).
+lemma nlift_flat_dx: â\88\80U,d,e. (â\88\80T. â¬\86[d, e] T ≡ U → ⊥) →
+ â\88\80I,W. (â\88\80X. â¬\86[d, e] X ≡ ⓕ{I}W.U → ⊥).
#U #d #e #HU #I #W #X #H elim (lift_inv_flat2 … H) -H /2 width=2 by/
qed-.
(* Inversion lemmas on negated basic relocation *****************************)
-lemma nlift_inv_lref_be_SO: â\88\80i,j. (â\88\80X. â\87§[i, 1] X ≡ #j → ⊥) → j = i.
+lemma nlift_inv_lref_be_SO: â\88\80i,j. (â\88\80X. â¬\86[i, 1] X ≡ #j → ⊥) → j = i.
#i #j elim (lt_or_eq_or_gt i j) // #Hij #H
[ elim (H (#(j-1))) -H /2 width=1 by lift_lref_ge_minus/
| elim (H (#j)) -H /2 width=1 by lift_lref_lt/
]
qed-.
-lemma nlift_inv_bind: â\88\80a,I,W,U,d,e. (â\88\80X. â\87§[d, e] X ≡ ⓑ{a,I}W.U → ⊥) →
- (â\88\80V. â\87§[d, e] V â\89¡ W â\86\92 â\8a¥) â\88¨ (â\88\80T. â\87§[d+1, e] T ≡ U → ⊥).
+lemma nlift_inv_bind: â\88\80a,I,W,U,d,e. (â\88\80X. â¬\86[d, e] X ≡ ⓑ{a,I}W.U → ⊥) →
+ (â\88\80V. â¬\86[d, e] V â\89¡ W â\86\92 â\8a¥) â\88¨ (â\88\80T. â¬\86[d+1, e] T ≡ U → ⊥).
#a #I #W #U #d #e #H elim (is_lift_dec W d e)
[ * /4 width=2 by lift_bind, or_intror/
| /4 width=2 by ex_intro, or_introl/
]
qed-.
-lemma nlift_inv_flat: â\88\80I,W,U,d,e. (â\88\80X. â\87§[d, e] X ≡ ⓕ{I}W.U → ⊥) →
- (â\88\80V. â\87§[d, e] V â\89¡ W â\86\92 â\8a¥) â\88¨ (â\88\80T. â\87§[d, e] T ≡ U → ⊥).
+lemma nlift_inv_flat: â\88\80I,W,U,d,e. (â\88\80X. â¬\86[d, e] X ≡ ⓕ{I}W.U → ⊥) →
+ (â\88\80V. â¬\86[d, e] V â\89¡ W â\86\92 â\8a¥) â\88¨ (â\88\80T. â¬\86[d, e] T ≡ U → ⊥).
#I #W #U #d #e #H elim (is_lift_dec W d e)
[ * /4 width=2 by lift_flat, or_intror/
| /4 width=2 by ex_intro, or_introl/