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Diffstat (limited to 'theories7/Reals/Rcomplete.v')
-rw-r--r-- | theories7/Reals/Rcomplete.v | 175 |
1 files changed, 0 insertions, 175 deletions
diff --git a/theories7/Reals/Rcomplete.v b/theories7/Reals/Rcomplete.v deleted file mode 100644 index 5985a382..00000000 --- a/theories7/Reals/Rcomplete.v +++ /dev/null @@ -1,175 +0,0 @@ -(************************************************************************) -(* v * The Coq Proof Assistant / The Coq Development Team *) -(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *) -(* \VV/ **************************************************************) -(* // * This file is distributed under the terms of the *) -(* * GNU Lesser General Public License Version 2.1 *) -(************************************************************************) - -(*i $Id: Rcomplete.v,v 1.1.2.1 2004/07/16 19:31:34 herbelin Exp $ i*) - -Require Rbase. -Require Rfunctions. -Require Rseries. -Require SeqProp. -Require Max. -V7only [ Import nat_scope. Import Z_scope. Import R_scope. ]. -Open Local Scope R_scope. - -(****************************************************) -(* R is complete : *) -(* Each sequence which satisfies *) -(* the Cauchy's criterion converges *) -(* *) -(* Proof with adjacent sequences (Vn and Wn) *) -(****************************************************) - -Theorem R_complete : (Un:nat->R) (Cauchy_crit Un) -> (sigTT R [l:R](Un_cv Un l)). -Intros. -Pose Vn := (sequence_minorant Un (cauchy_min Un H)). -Pose Wn := (sequence_majorant Un (cauchy_maj Un H)). -Assert H0 := (maj_cv Un H). -Fold Wn in H0. -Assert H1 := (min_cv Un H). -Fold Vn in H1. -Elim H0; Intros. -Elim H1; Intros. -Cut x==x0. -Intros. -Apply existTT with x. -Rewrite <- H2 in p0. -Unfold Un_cv. -Intros. -Unfold Un_cv in p; Unfold Un_cv in p0. -Cut ``0<eps/3``. -Intro. -Elim (p ``eps/3`` H4); Intros. -Elim (p0 ``eps/3`` H4); Intros. -Exists (max x1 x2). -Intros. -Unfold R_dist. -Apply Rle_lt_trans with ``(Rabsolu ((Un n)-(Vn n)))+(Rabsolu ((Vn n)-x))``. -Replace ``(Un n)-x`` with ``((Un n)-(Vn n))+((Vn n)-x)``; [Apply Rabsolu_triang | Ring]. -Apply Rle_lt_trans with ``(Rabsolu ((Wn n)-(Vn n)))+(Rabsolu ((Vn n)-x))``. -Do 2 Rewrite <- (Rplus_sym ``(Rabsolu ((Vn n)-x))``). -Apply Rle_compatibility. -Repeat Rewrite Rabsolu_right. -Unfold Rminus; Do 2 Rewrite <- (Rplus_sym ``-(Vn n)``); Apply Rle_compatibility. -Assert H8 := (Vn_Un_Wn_order Un (cauchy_maj Un H) (cauchy_min Un H)). -Fold Vn Wn in H8. -Elim (H8 n); Intros. -Assumption. -Apply Rle_sym1. -Unfold Rminus; Apply Rle_anti_compatibility with (Vn n). -Rewrite Rplus_Or. -Replace ``(Vn n)+((Wn n)+ -(Vn n))`` with (Wn n); [Idtac | Ring]. -Assert H8 := (Vn_Un_Wn_order Un (cauchy_maj Un H) (cauchy_min Un H)). -Fold Vn Wn in H8. -Elim (H8 n); Intros. -Apply Rle_trans with (Un n); Assumption. -Apply Rle_sym1. -Unfold Rminus; Apply Rle_anti_compatibility with (Vn n). -Rewrite Rplus_Or. -Replace ``(Vn n)+((Un n)+ -(Vn n))`` with (Un n); [Idtac | Ring]. -Assert H8 := (Vn_Un_Wn_order Un (cauchy_maj Un H) (cauchy_min Un H)). -Fold Vn Wn in H8. -Elim (H8 n); Intros. -Assumption. -Apply Rle_lt_trans with ``(Rabsolu ((Wn n)-x))+(Rabsolu (x-(Vn n)))+(Rabsolu ((Vn n)-x))``. -Do 2 Rewrite <- (Rplus_sym ``(Rabsolu ((Vn n)-x))``). -Apply Rle_compatibility. -Replace ``(Wn n)-(Vn n)`` with ``((Wn n)-x)+(x-(Vn n))``; [Apply Rabsolu_triang | Ring]. -Apply Rlt_le_trans with ``eps/3+eps/3+eps/3``. -Repeat Apply Rplus_lt. -Unfold R_dist in H5. -Apply H5. -Unfold ge; Apply le_trans with (max x1 x2). -Apply le_max_l. -Assumption. -Rewrite <- Rabsolu_Ropp. -Replace ``-(x-(Vn n))`` with ``(Vn n)-x``; [Idtac | Ring]. -Unfold R_dist in H6. -Apply H6. -Unfold ge; Apply le_trans with (max x1 x2). -Apply le_max_r. -Assumption. -Unfold R_dist in H6. -Apply H6. -Unfold ge; Apply le_trans with (max x1 x2). -Apply le_max_r. -Assumption. -Right. -Pattern 4 eps; Replace ``eps`` with ``3*eps/3``. -Ring. -Unfold Rdiv; Rewrite <- Rmult_assoc; Apply Rinv_r_simpl_m; DiscrR. -Unfold Rdiv; Apply Rmult_lt_pos; [Assumption | Apply Rlt_Rinv; Sup0]. -Apply cond_eq. -Intros. -Cut ``0<eps/5``. -Intro. -Unfold Un_cv in p; Unfold Un_cv in p0. -Unfold R_dist in p; Unfold R_dist in p0. -Elim (p ``eps/5`` H3); Intros N1 H4. -Elim (p0 ``eps/5`` H3); Intros N2 H5. -Unfold Cauchy_crit in H. -Unfold R_dist in H. -Elim (H ``eps/5`` H3); Intros N3 H6. -Pose N := (max (max N1 N2) N3). -Apply Rle_lt_trans with ``(Rabsolu (x-(Wn N)))+(Rabsolu ((Wn N)-x0))``. -Replace ``x-x0`` with ``(x-(Wn N))+((Wn N)-x0)``; [Apply Rabsolu_triang | Ring]. -Apply Rle_lt_trans with ``(Rabsolu (x-(Wn N)))+(Rabsolu ((Wn N)-(Vn N)))+(Rabsolu (((Vn N)-x0)))``. -Rewrite Rplus_assoc. -Apply Rle_compatibility. -Replace ``(Wn N)-x0`` with ``((Wn N)-(Vn N))+((Vn N)-x0)``; [Apply Rabsolu_triang | Ring]. -Replace ``eps`` with ``eps/5+3*eps/5+eps/5``. -Repeat Apply Rplus_lt. -Rewrite <- Rabsolu_Ropp. -Replace ``-(x-(Wn N))`` with ``(Wn N)-x``; [Apply H4 | Ring]. -Unfold ge N. -Apply le_trans with (max N1 N2); Apply le_max_l. -Unfold Wn Vn. -Unfold sequence_majorant sequence_minorant. -Assert H7 := (approx_maj [k:nat](Un (plus N k)) (maj_ss Un N (cauchy_maj Un H))). -Assert H8 := (approx_min [k:nat](Un (plus N k)) (min_ss Un N (cauchy_min Un H))). -Cut (Wn N)==(majorant ([k:nat](Un (plus N k))) (maj_ss Un N (cauchy_maj Un H))). -Cut (Vn N)==(minorant ([k:nat](Un (plus N k))) (min_ss Un N (cauchy_min Un H))). -Intros. -Rewrite <- H9; Rewrite <- H10. -Rewrite <- H9 in H8. -Rewrite <- H10 in H7. -Elim (H7 ``eps/5`` H3); Intros k2 H11. -Elim (H8 ``eps/5`` H3); Intros k1 H12. -Apply Rle_lt_trans with ``(Rabsolu ((Wn N)-(Un (plus N k2))))+(Rabsolu ((Un (plus N k2))-(Vn N)))``. -Replace ``(Wn N)-(Vn N)`` with ``((Wn N)-(Un (plus N k2)))+((Un (plus N k2))-(Vn N))``; [Apply Rabsolu_triang | Ring]. -Apply Rle_lt_trans with ``(Rabsolu ((Wn N)-(Un (plus N k2))))+(Rabsolu ((Un (plus N k2))-(Un (plus N k1))))+(Rabsolu ((Un (plus N k1))-(Vn N)))``. -Rewrite Rplus_assoc. -Apply Rle_compatibility. -Replace ``(Un (plus N k2))-(Vn N)`` with ``((Un (plus N k2))-(Un (plus N k1)))+((Un (plus N k1))-(Vn N))``; [Apply Rabsolu_triang | Ring]. -Replace ``3*eps/5`` with ``eps/5+eps/5+eps/5``; [Repeat Apply Rplus_lt | Ring]. -Assumption. -Apply H6. -Unfold ge. -Apply le_trans with N. -Unfold N; Apply le_max_r. -Apply le_plus_l. -Unfold ge. -Apply le_trans with N. -Unfold N; Apply le_max_r. -Apply le_plus_l. -Rewrite <- Rabsolu_Ropp. -Replace ``-((Un (plus N k1))-(Vn N))`` with ``(Vn N)-(Un (plus N k1))``; [Assumption | Ring]. -Reflexivity. -Reflexivity. -Apply H5. -Unfold ge; Apply le_trans with (max N1 N2). -Apply le_max_r. -Unfold N; Apply le_max_l. -Pattern 4 eps; Replace ``eps`` with ``5*eps/5``. -Ring. -Unfold Rdiv; Rewrite <- Rmult_assoc; Apply Rinv_r_simpl_m. -DiscrR. -Unfold Rdiv; Apply Rmult_lt_pos. -Assumption. -Apply Rlt_Rinv. -Sup0; Try Apply lt_O_Sn. -Qed. |