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(************************************************************************)
(*  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: Rsigma.v 5920 2004-07-16 20:01:26Z herbelin $ i*)

Require Import Rbase.
Require Import Rfunctions.
Require Import Rseries.
Require Import PartSum.
Open Local Scope R_scope.

Set Implicit Arguments.

Section Sigma.

Variable f : nat -> R.

Definition sigma (low high:nat) : R :=
  sum_f_R0 (fun k:nat => f (low + k)) (high - low).

Theorem sigma_split :
 forall low high k:nat,
   (low <= k)%nat ->
   (k < high)%nat -> sigma low high = sigma low k + sigma (S k) high.
intros; induction  k as [| k Hreck].
cut (low = 0%nat).
intro; rewrite H1; unfold sigma in |- *; rewrite <- minus_n_n;
 rewrite <- minus_n_O; simpl in |- *; replace (high - 1)%nat with (pred high).
apply (decomp_sum (fun k:nat => f k)).
assumption.
apply pred_of_minus.
inversion H; reflexivity.
cut ((low <= k)%nat \/ low = S k).
intro; elim H1; intro.
replace (sigma low (S k)) with (sigma low k + f (S k)).
rewrite Rplus_assoc;
 replace (f (S k) + sigma (S (S k)) high) with (sigma (S k) high).
apply Hreck.
assumption.
apply lt_trans with (S k); [ apply lt_n_Sn | assumption ].
unfold sigma in |- *; replace (high - S (S k))%nat with (pred (high - S k)).
pattern (S k) at 3 in |- *; replace (S k) with (S k + 0)%nat;
 [ idtac | ring ].
replace (sum_f_R0 (fun k0:nat => f (S (S k) + k0)) (pred (high - S k))) with
 (sum_f_R0 (fun k0:nat => f (S k + S k0)) (pred (high - S k))).
apply (decomp_sum (fun i:nat => f (S k + i))).
apply lt_minus_O_lt; assumption.
apply sum_eq; intros; replace (S k + S i)%nat with (S (S k) + i)%nat.
reflexivity.
apply INR_eq; do 2 rewrite plus_INR; do 3 rewrite S_INR; ring.
replace (high - S (S k))%nat with (high - S k - 1)%nat.
apply pred_of_minus.
apply INR_eq; repeat rewrite minus_INR.
do 4 rewrite S_INR; ring.
apply lt_le_S; assumption.
apply lt_le_weak; assumption.
apply lt_le_S; apply lt_minus_O_lt; assumption.
unfold sigma in |- *; replace (S k - low)%nat with (S (k - low)).
pattern (S k) at 1 in |- *; replace (S k) with (low + S (k - low))%nat.
symmetry  in |- *; apply (tech5 (fun i:nat => f (low + i))).
apply INR_eq; rewrite plus_INR; do 2 rewrite S_INR; rewrite minus_INR.
ring.
assumption.
apply minus_Sn_m; assumption.
rewrite <- H2; unfold sigma in |- *; rewrite <- minus_n_n; simpl in |- *;
 replace (high - S low)%nat with (pred (high - low)).
replace (sum_f_R0 (fun k0:nat => f (S (low + k0))) (pred (high - low))) with
 (sum_f_R0 (fun k0:nat => f (low + S k0)) (pred (high - low))).
apply (decomp_sum (fun k0:nat => f (low + k0))).
apply lt_minus_O_lt.
apply le_lt_trans with (S k); [ rewrite H2; apply le_n | assumption ].
apply sum_eq; intros; replace (S (low + i)) with (low + S i)%nat.
reflexivity.
apply INR_eq; rewrite plus_INR; do 2 rewrite S_INR; rewrite plus_INR; ring.
replace (high - S low)%nat with (high - low - 1)%nat.
apply pred_of_minus.
apply INR_eq; repeat rewrite minus_INR.
do 2 rewrite S_INR; ring.
apply lt_le_S; rewrite H2; assumption.
rewrite H2; apply lt_le_weak; assumption.
apply lt_le_S; apply lt_minus_O_lt; rewrite H2; assumption.
inversion H; [ right; reflexivity | left; assumption ].
Qed.

Theorem sigma_diff :
 forall low high k:nat,
   (low <= k)%nat ->
   (k < high)%nat -> sigma low high - sigma low k = sigma (S k) high.
intros low high k H1 H2; symmetry  in |- *; rewrite (sigma_split H1 H2); ring.
Qed.

Theorem sigma_diff_neg :
 forall low high k:nat,
   (low <= k)%nat ->
   (k < high)%nat -> sigma low k - sigma low high = - sigma (S k) high.
intros low high k H1 H2; rewrite (sigma_split H1 H2); ring.
Qed.

Theorem sigma_first :
 forall low high:nat,
   (low < high)%nat -> sigma low high = f low + sigma (S low) high.
intros low high H1; generalize (lt_le_S low high H1); intro H2;
 generalize (lt_le_weak low high H1); intro H3;
 replace (f low) with (sigma low low).
apply sigma_split.
apply le_n.
assumption.
unfold sigma in |- *; rewrite <- minus_n_n.
simpl in |- *.
replace (low + 0)%nat with low; [ reflexivity | ring ].
Qed.

Theorem sigma_last :
 forall low high:nat,
   (low < high)%nat -> sigma low high = f high + sigma low (pred high).
intros low high H1; generalize (lt_le_S low high H1); intro H2;
 generalize (lt_le_weak low high H1); intro H3;
 replace (f high) with (sigma high high).
rewrite Rplus_comm; cut (high = S (pred high)).
intro; pattern high at 3 in |- *; rewrite H.
apply sigma_split.
apply le_S_n; rewrite <- H; apply lt_le_S; assumption.
apply lt_pred_n_n; apply le_lt_trans with low; [ apply le_O_n | assumption ].
apply S_pred with 0%nat; apply le_lt_trans with low;
 [ apply le_O_n | assumption ].
unfold sigma in |- *; rewrite <- minus_n_n; simpl in |- *;
 replace (high + 0)%nat with high; [ reflexivity | ring ].
Qed.

Theorem sigma_eq_arg : forall low:nat, sigma low low = f low.
intro; unfold sigma in |- *; rewrite <- minus_n_n.
simpl in |- *; replace (low + 0)%nat with low; [ reflexivity | ring ].
Qed.

End Sigma.