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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2012 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
Require Import Rbase.
Require Import Rfunctions.
Require Import Ranalysis1.
Require Import Rtopology.
Local Open Scope R_scope.
(* The Mean Value Theorem *)
Theorem MVT :
forall (f g:R -> R) (a b:R) (pr1:forall c:R, a < c < b -> derivable_pt f c)
(pr2:forall c:R, a < c < b -> derivable_pt g c),
a < b ->
(forall c:R, a <= c <= b -> continuity_pt f c) ->
(forall c:R, a <= c <= b -> continuity_pt g c) ->
exists c : R,
(exists P : a < c < b,
(g b - g a) * derive_pt f c (pr1 c P) =
(f b - f a) * derive_pt g c (pr2 c P)).
Proof.
intros; assert (H2 := Rlt_le _ _ H).
set (h := fun y:R => (g b - g a) * f y - (f b - f a) * g y).
cut (forall c:R, a < c < b -> derivable_pt h c).
intro X; cut (forall c:R, a <= c <= b -> continuity_pt h c).
intro; assert (H4 := continuity_ab_maj h a b H2 H3).
assert (H5 := continuity_ab_min h a b H2 H3).
elim H4; intros Mx H6.
elim H5; intros mx H7.
cut (h a = h b).
intro; set (M := h Mx); set (m := h mx).
cut
(forall (c:R) (P:a < c < b),
derive_pt h c (X c P) =
(g b - g a) * derive_pt f c (pr1 c P) -
(f b - f a) * derive_pt g c (pr2 c P)).
intro; case (Req_dec (h a) M); intro.
case (Req_dec (h a) m); intro.
cut (forall c:R, a <= c <= b -> h c = M).
intro; cut (a < (a + b) / 2 < b).
(*** h constant ***)
intro; exists ((a + b) / 2).
exists H13.
apply Rminus_diag_uniq; rewrite <- H9; apply deriv_constant2 with a b.
elim H13; intros; assumption.
elim H13; intros; assumption.
intros; rewrite (H12 ((a + b) / 2)).
apply H12; split; left; assumption.
elim H13; intros; split; left; assumption.
split.
apply Rmult_lt_reg_l with 2.
prove_sup0.
unfold Rdiv; rewrite <- (Rmult_comm (/ 2)); rewrite <- Rmult_assoc;
rewrite <- Rinv_r_sym.
rewrite Rmult_1_l; rewrite double; apply Rplus_lt_compat_l; apply H.
discrR.
apply Rmult_lt_reg_l with 2.
prove_sup0.
unfold Rdiv; rewrite <- (Rmult_comm (/ 2)); rewrite <- Rmult_assoc;
rewrite <- Rinv_r_sym.
rewrite Rmult_1_l; rewrite Rplus_comm; rewrite double;
apply Rplus_lt_compat_l; apply H.
discrR.
intros; elim H6; intros H13 _.
elim H7; intros H14 _.
apply Rle_antisym.
apply H13; apply H12.
rewrite H10 in H11; rewrite H11; apply H14; apply H12.
cut (a < mx < b).
(*** h admet un minimum global sur [a,b] ***)
intro; exists mx.
exists H12.
apply Rminus_diag_uniq; rewrite <- H9; apply deriv_minimum with a b.
elim H12; intros; assumption.
elim H12; intros; assumption.
intros; elim H7; intros.
apply H15; split; left; assumption.
elim H7; intros _ H12; elim H12; intros; split.
inversion H13.
apply H15.
rewrite H15 in H11; elim H11; reflexivity.
inversion H14.
apply H15.
rewrite H8 in H11; rewrite <- H15 in H11; elim H11; reflexivity.
cut (a < Mx < b).
(*** h admet un maximum global sur [a,b] ***)
intro; exists Mx.
exists H11.
apply Rminus_diag_uniq; rewrite <- H9; apply deriv_maximum with a b.
elim H11; intros; assumption.
elim H11; intros; assumption.
intros; elim H6; intros; apply H14.
split; left; assumption.
elim H6; intros _ H11; elim H11; intros; split.
inversion H12.
apply H14.
rewrite H14 in H10; elim H10; reflexivity.
inversion H13.
apply H14.
rewrite H8 in H10; rewrite <- H14 in H10; elim H10; reflexivity.
intros; unfold h;
replace
(derive_pt (fun y:R => (g b - g a) * f y - (f b - f a) * g y) c (X c P))
with
(derive_pt ((fct_cte (g b - g a) * f)%F - (fct_cte (f b - f a) * g)%F) c
(derivable_pt_minus _ _ _
(derivable_pt_mult _ _ _ (derivable_pt_const (g b - g a) c) (pr1 c P))
(derivable_pt_mult _ _ _ (derivable_pt_const (f b - f a) c) (pr2 c P))));
[ idtac | apply pr_nu ].
rewrite derive_pt_minus; do 2 rewrite derive_pt_mult;
do 2 rewrite derive_pt_const; do 2 rewrite Rmult_0_l;
do 2 rewrite Rplus_0_l; reflexivity.
unfold h; ring.
intros; unfold h;
change
(continuity_pt ((fct_cte (g b - g a) * f)%F - (fct_cte (f b - f a) * g)%F)
c).
apply continuity_pt_minus; apply continuity_pt_mult.
apply derivable_continuous_pt; apply derivable_const.
apply H0; apply H3.
apply derivable_continuous_pt; apply derivable_const.
apply H1; apply H3.
intros;
change
(derivable_pt ((fct_cte (g b - g a) * f)%F - (fct_cte (f b - f a) * g)%F)
c).
apply derivable_pt_minus; apply derivable_pt_mult.
apply derivable_pt_const.
apply (pr1 _ H3).
apply derivable_pt_const.
apply (pr2 _ H3).
Qed.
(* Corollaries ... *)
Lemma MVT_cor1 :
forall (f:R -> R) (a b:R) (pr:derivable f),
a < b ->
exists c : R, f b - f a = derive_pt f c (pr c) * (b - a) /\ a < c < b.
Proof.
intros f a b pr H; cut (forall c:R, a < c < b -> derivable_pt f c);
[ intro X | intros; apply pr ].
cut (forall c:R, a < c < b -> derivable_pt id c);
[ intro X0 | intros; apply derivable_pt_id ].
cut (forall c:R, a <= c <= b -> continuity_pt f c);
[ intro | intros; apply derivable_continuous_pt; apply pr ].
cut (forall c:R, a <= c <= b -> continuity_pt id c);
[ intro | intros; apply derivable_continuous_pt; apply derivable_id ].
assert (H2 := MVT f id a b X X0 H H0 H1).
elim H2; intros c H3; elim H3; intros.
exists c; split.
cut (derive_pt id c (X0 c x) = derive_pt id c (derivable_pt_id c));
[ intro | apply pr_nu ].
rewrite H5 in H4; rewrite (derive_pt_id c) in H4; rewrite Rmult_1_r in H4;
rewrite <- H4; replace (derive_pt f c (X c x)) with (derive_pt f c (pr c));
[ idtac | apply pr_nu ]; apply Rmult_comm.
apply x.
Qed.
Theorem MVT_cor2 :
forall (f f':R -> R) (a b:R),
a < b ->
(forall c:R, a <= c <= b -> derivable_pt_lim f c (f' c)) ->
exists c : R, f b - f a = f' c * (b - a) /\ a < c < b.
Proof.
intros f f' a b H H0; cut (forall c:R, a <= c <= b -> derivable_pt f c).
intro X; cut (forall c:R, a < c < b -> derivable_pt f c).
intro X0; cut (forall c:R, a <= c <= b -> continuity_pt f c).
intro; cut (forall c:R, a <= c <= b -> derivable_pt id c).
intro X1; cut (forall c:R, a < c < b -> derivable_pt id c).
intro X2; cut (forall c:R, a <= c <= b -> continuity_pt id c).
intro; elim (MVT f id a b X0 X2 H H1 H2); intros; elim H3; clear H3; intros;
exists x; split.
cut (derive_pt id x (X2 x x0) = 1).
cut (derive_pt f x (X0 x x0) = f' x).
intros; rewrite H4 in H3; rewrite H5 in H3; unfold id in H3;
rewrite Rmult_1_r in H3; rewrite Rmult_comm; symmetry ;
assumption.
apply derive_pt_eq_0; apply H0; elim x0; intros; split; left; assumption.
apply derive_pt_eq_0; apply derivable_pt_lim_id.
assumption.
intros; apply derivable_continuous_pt; apply X1; assumption.
intros; apply derivable_pt_id.
intros; apply derivable_pt_id.
intros; apply derivable_continuous_pt; apply X; assumption.
intros; elim H1; intros; apply X; split; left; assumption.
intros; unfold derivable_pt; exists (f' c); apply H0;
apply H1.
Qed.
Lemma MVT_cor3 :
forall (f f':R -> R) (a b:R),
a < b ->
(forall x:R, a <= x -> x <= b -> derivable_pt_lim f x (f' x)) ->
exists c : R, a <= c /\ c <= b /\ f b = f a + f' c * (b - a).
Proof.
intros f f' a b H H0;
assert (H1 : exists c : R, f b - f a = f' c * (b - a) /\ a < c < b);
[ apply MVT_cor2; [ apply H | intros; elim H1; intros; apply (H0 _ H2 H3) ]
| elim H1; intros; exists x; elim H2; intros; elim H4; intros; split;
[ left; assumption | split; [ left; assumption | rewrite <- H3; ring ] ] ].
Qed.
Lemma Rolle :
forall (f:R -> R) (a b:R) (pr:forall x:R, a < x < b -> derivable_pt f x),
(forall x:R, a <= x <= b -> continuity_pt f x) ->
a < b ->
f a = f b ->
exists c : R, (exists P : a < c < b, derive_pt f c (pr c P) = 0).
Proof.
intros; assert (H2 : forall x:R, a < x < b -> derivable_pt id x).
intros; apply derivable_pt_id.
assert (H3 := MVT f id a b pr H2 H0 H);
assert (H4 : forall x:R, a <= x <= b -> continuity_pt id x).
intros; apply derivable_continuous; apply derivable_id.
elim (H3 H4); intros; elim H5; intros; exists x; exists x0; rewrite H1 in H6;
unfold id in H6; unfold Rminus in H6; rewrite Rplus_opp_r in H6;
rewrite Rmult_0_l in H6; apply Rmult_eq_reg_l with (b - a);
[ rewrite Rmult_0_r; apply H6
| apply Rminus_eq_contra; red; intro; rewrite H7 in H0;
elim (Rlt_irrefl _ H0) ].
Qed.
(**********)
Lemma nonneg_derivative_1 :
forall (f:R -> R) (pr:derivable f),
(forall x:R, 0 <= derive_pt f x (pr x)) -> increasing f.
Proof.
intros.
unfold increasing.
intros.
case (total_order_T x y); intro.
elim s; intro.
apply Rplus_le_reg_l with (- f x).
rewrite Rplus_opp_l; rewrite Rplus_comm.
assert (H1 := MVT_cor1 f _ _ pr a).
elim H1; intros.
elim H2; intros.
unfold Rminus in H3.
rewrite H3.
apply Rmult_le_pos.
apply H.
apply Rplus_le_reg_l with x.
rewrite Rplus_0_r; replace (x + (y + - x)) with y; [ assumption | ring ].
rewrite b; right; reflexivity.
elim (Rlt_irrefl _ (Rle_lt_trans _ _ _ H0 r)).
Qed.
(**********)
Lemma nonpos_derivative_0 :
forall (f:R -> R) (pr:derivable f),
decreasing f -> forall x:R, derive_pt f x (pr x) <= 0.
Proof.
intros f pr H x; assert (H0 := H); unfold decreasing in H0;
generalize (derivable_derive f x (pr x)); intro; elim H1;
intros l H2.
rewrite H2; case (Rtotal_order l 0); intro.
left; assumption.
elim H3; intro.
right; assumption.
generalize (derive_pt_eq_1 f x l (pr x) H2); intros; cut (0 < l / 2).
intro; elim (H5 (l / 2) H6); intros delta H7;
cut (delta / 2 <> 0 /\ 0 < delta / 2 /\ Rabs (delta / 2) < delta).
intro; decompose [and] H8; intros; generalize (H7 (delta / 2) H9 H12);
cut ((f (x + delta / 2) - f x) / (delta / 2) <= 0).
intro; cut (0 < - ((f (x + delta / 2) - f x) / (delta / 2) - l)).
intro; unfold Rabs;
case (Rcase_abs ((f (x + delta / 2) - f x) / (delta / 2) - l)).
intros;
generalize
(Rplus_lt_compat_r (- l) (- ((f (x + delta / 2) - f x) / (delta / 2) - l))
(l / 2) H14); unfold Rminus.
replace (l / 2 + - l) with (- (l / 2)).
replace (- ((f (x + delta / 2) + - f x) / (delta / 2) + - l) + - l) with
(- ((f (x + delta / 2) + - f x) / (delta / 2))).
intro.
generalize
(Ropp_lt_gt_contravar (- ((f (x + delta / 2) + - f x) / (delta / 2)))
(- (l / 2)) H15).
repeat rewrite Ropp_involutive.
intro.
generalize
(Rlt_trans 0 (l / 2) ((f (x + delta / 2) - f x) / (delta / 2)) H6 H16);
intro.
elim
(Rlt_irrefl 0
(Rlt_le_trans 0 ((f (x + delta / 2) - f x) / (delta / 2)) 0 H17 H10)).
ring.
pattern l at 3; rewrite double_var.
ring.
intros.
generalize
(Ropp_ge_le_contravar ((f (x + delta / 2) - f x) / (delta / 2) - l) 0 r).
rewrite Ropp_0.
intro.
elim
(Rlt_irrefl 0
(Rlt_le_trans 0 (- ((f (x + delta / 2) - f x) / (delta / 2) - l)) 0 H13
H15)).
replace (- ((f (x + delta / 2) - f x) / (delta / 2) - l)) with
((f x - f (x + delta / 2)) / (delta / 2) + l).
unfold Rminus.
apply Rplus_le_lt_0_compat.
unfold Rdiv; apply Rmult_le_pos.
cut (x <= x + delta * / 2).
intro; generalize (H0 x (x + delta * / 2) H13); intro;
generalize
(Rplus_le_compat_l (- f (x + delta / 2)) (f (x + delta / 2)) (f x) H14);
rewrite Rplus_opp_l; rewrite Rplus_comm; intro; assumption.
pattern x at 1; rewrite <- (Rplus_0_r x); apply Rplus_le_compat_l;
left; assumption.
left; apply Rinv_0_lt_compat; assumption.
assumption.
rewrite Ropp_minus_distr.
unfold Rminus.
rewrite (Rplus_comm l).
unfold Rdiv.
rewrite <- Ropp_mult_distr_l_reverse.
rewrite Ropp_plus_distr.
rewrite Ropp_involutive.
rewrite (Rplus_comm (f x)).
reflexivity.
replace ((f (x + delta / 2) - f x) / (delta / 2)) with
(- ((f x - f (x + delta / 2)) / (delta / 2))).
rewrite <- Ropp_0.
apply Ropp_ge_le_contravar.
apply Rle_ge.
unfold Rdiv; apply Rmult_le_pos.
cut (x <= x + delta * / 2).
intro; generalize (H0 x (x + delta * / 2) H10); intro.
generalize
(Rplus_le_compat_l (- f (x + delta / 2)) (f (x + delta / 2)) (f x) H13);
rewrite Rplus_opp_l; rewrite Rplus_comm; intro; assumption.
pattern x at 1; rewrite <- (Rplus_0_r x); apply Rplus_le_compat_l;
left; assumption.
left; apply Rinv_0_lt_compat; assumption.
unfold Rdiv; rewrite <- Ropp_mult_distr_l_reverse.
rewrite Ropp_minus_distr.
reflexivity.
split.
unfold Rdiv; apply prod_neq_R0.
generalize (cond_pos delta); intro; red; intro H9; rewrite H9 in H8;
elim (Rlt_irrefl 0 H8).
apply Rinv_neq_0_compat; discrR.
split.
unfold Rdiv; apply Rmult_lt_0_compat;
[ apply (cond_pos delta) | apply Rinv_0_lt_compat; prove_sup0 ].
rewrite Rabs_right.
unfold Rdiv; apply Rmult_lt_reg_l with 2.
prove_sup0.
rewrite <- (Rmult_comm (/ 2)); rewrite <- Rmult_assoc; rewrite <- Rinv_r_sym.
rewrite Rmult_1_l; rewrite double; pattern (pos delta) at 1;
rewrite <- Rplus_0_r.
apply Rplus_lt_compat_l; apply (cond_pos delta).
discrR.
apply Rle_ge; unfold Rdiv; left; apply Rmult_lt_0_compat.
apply (cond_pos delta).
apply Rinv_0_lt_compat; prove_sup0.
unfold Rdiv; apply Rmult_lt_0_compat;
[ apply H4 | apply Rinv_0_lt_compat; prove_sup0 ].
Qed.
(**********)
Lemma increasing_decreasing_opp :
forall f:R -> R, increasing f -> decreasing (- f)%F.
Proof.
unfold increasing, decreasing, opp_fct; intros; generalize (H x y H0);
intro; apply Ropp_ge_le_contravar; apply Rle_ge; assumption.
Qed.
(**********)
Lemma nonpos_derivative_1 :
forall (f:R -> R) (pr:derivable f),
(forall x:R, derive_pt f x (pr x) <= 0) -> decreasing f.
Proof.
intros.
cut (forall h:R, - - f h = f h).
intro.
generalize (increasing_decreasing_opp (- f)%F).
unfold decreasing.
unfold opp_fct.
intros.
rewrite <- (H0 x); rewrite <- (H0 y).
apply H1.
cut (forall x:R, 0 <= derive_pt (- f) x (derivable_opp f pr x)).
intros.
replace (fun x:R => - f x) with (- f)%F; [ idtac | reflexivity ].
apply (nonneg_derivative_1 (- f)%F (derivable_opp f pr) H3).
intro.
assert (H3 := derive_pt_opp f x0 (pr x0)).
cut
(derive_pt (- f) x0 (derivable_pt_opp f x0 (pr x0)) =
derive_pt (- f) x0 (derivable_opp f pr x0)).
intro.
rewrite <- H4.
rewrite H3.
rewrite <- Ropp_0; apply Ropp_ge_le_contravar; apply Rle_ge; apply (H x0).
apply pr_nu.
assumption.
intro; ring.
Qed.
(**********)
Lemma positive_derivative :
forall (f:R -> R) (pr:derivable f),
(forall x:R, 0 < derive_pt f x (pr x)) -> strict_increasing f.
Proof.
intros.
unfold strict_increasing.
intros.
apply Rplus_lt_reg_r with (- f x).
rewrite Rplus_opp_l; rewrite Rplus_comm.
assert (H1 := MVT_cor1 f _ _ pr H0).
elim H1; intros.
elim H2; intros.
unfold Rminus in H3.
rewrite H3.
apply Rmult_lt_0_compat.
apply H.
apply Rplus_lt_reg_r with x.
rewrite Rplus_0_r; replace (x + (y + - x)) with y; [ assumption | ring ].
Qed.
(**********)
Lemma strictincreasing_strictdecreasing_opp :
forall f:R -> R, strict_increasing f -> strict_decreasing (- f)%F.
Proof.
unfold strict_increasing, strict_decreasing, opp_fct; intros;
generalize (H x y H0); intro; apply Ropp_lt_gt_contravar;
assumption.
Qed.
(**********)
Lemma negative_derivative :
forall (f:R -> R) (pr:derivable f),
(forall x:R, derive_pt f x (pr x) < 0) -> strict_decreasing f.
Proof.
intros.
cut (forall h:R, - - f h = f h).
intros.
generalize (strictincreasing_strictdecreasing_opp (- f)%F).
unfold strict_decreasing, opp_fct.
intros.
rewrite <- (H0 x).
rewrite <- (H0 y).
apply H1; [ idtac | assumption ].
cut (forall x:R, 0 < derive_pt (- f) x (derivable_opp f pr x)).
intros; eapply positive_derivative; apply H3.
intro.
assert (H3 := derive_pt_opp f x0 (pr x0)).
cut
(derive_pt (- f) x0 (derivable_pt_opp f x0 (pr x0)) =
derive_pt (- f) x0 (derivable_opp f pr x0)).
intro.
rewrite <- H4; rewrite H3.
rewrite <- Ropp_0; apply Ropp_lt_gt_contravar; apply (H x0).
apply pr_nu.
intro; ring.
Qed.
(**********)
Lemma null_derivative_0 :
forall (f:R -> R) (pr:derivable f),
constant f -> forall x:R, derive_pt f x (pr x) = 0.
Proof.
intros.
unfold constant in H.
apply derive_pt_eq_0.
intros; exists (mkposreal 1 Rlt_0_1); simpl; intros.
rewrite (H x (x + h)); unfold Rminus; unfold Rdiv;
rewrite Rplus_opp_r; rewrite Rmult_0_l; rewrite Rplus_opp_r;
rewrite Rabs_R0; assumption.
Qed.
(**********)
Lemma increasing_decreasing :
forall f:R -> R, increasing f -> decreasing f -> constant f.
Proof.
unfold increasing, decreasing, constant; intros;
case (Rtotal_order x y); intro.
generalize (Rlt_le x y H1); intro;
apply (Rle_antisym (f x) (f y) (H x y H2) (H0 x y H2)).
elim H1; intro.
rewrite H2; reflexivity.
generalize (Rlt_le y x H2); intro; symmetry ;
apply (Rle_antisym (f y) (f x) (H y x H3) (H0 y x H3)).
Qed.
(**********)
Lemma null_derivative_1 :
forall (f:R -> R) (pr:derivable f),
(forall x:R, derive_pt f x (pr x) = 0) -> constant f.
Proof.
intros.
cut (forall x:R, derive_pt f x (pr x) <= 0).
cut (forall x:R, 0 <= derive_pt f x (pr x)).
intros.
assert (H2 := nonneg_derivative_1 f pr H0).
assert (H3 := nonpos_derivative_1 f pr H1).
apply increasing_decreasing; assumption.
intro; right; symmetry ; apply (H x).
intro; right; apply (H x).
Qed.
(**********)
Lemma derive_increasing_interv_ax :
forall (a b:R) (f:R -> R) (pr:derivable f),
a < b ->
((forall t:R, a < t < b -> 0 < derive_pt f t (pr t)) ->
forall x y:R, a <= x <= b -> a <= y <= b -> x < y -> f x < f y) /\
((forall t:R, a < t < b -> 0 <= derive_pt f t (pr t)) ->
forall x y:R, a <= x <= b -> a <= y <= b -> x < y -> f x <= f y).
Proof.
intros.
split; intros.
apply Rplus_lt_reg_r with (- f x).
rewrite Rplus_opp_l; rewrite Rplus_comm.
assert (H4 := MVT_cor1 f _ _ pr H3).
elim H4; intros.
elim H5; intros.
unfold Rminus in H6.
rewrite H6.
apply Rmult_lt_0_compat.
apply H0.
elim H7; intros.
split.
elim H1; intros.
apply Rle_lt_trans with x; assumption.
elim H2; intros.
apply Rlt_le_trans with y; assumption.
apply Rplus_lt_reg_r with x.
rewrite Rplus_0_r; replace (x + (y + - x)) with y; [ assumption | ring ].
apply Rplus_le_reg_l with (- f x).
rewrite Rplus_opp_l; rewrite Rplus_comm.
assert (H4 := MVT_cor1 f _ _ pr H3).
elim H4; intros.
elim H5; intros.
unfold Rminus in H6.
rewrite H6.
apply Rmult_le_pos.
apply H0.
elim H7; intros.
split.
elim H1; intros.
apply Rle_lt_trans with x; assumption.
elim H2; intros.
apply Rlt_le_trans with y; assumption.
apply Rplus_le_reg_l with x.
rewrite Rplus_0_r; replace (x + (y + - x)) with y;
[ left; assumption | ring ].
Qed.
(**********)
Lemma derive_increasing_interv :
forall (a b:R) (f:R -> R) (pr:derivable f),
a < b ->
(forall t:R, a < t < b -> 0 < derive_pt f t (pr t)) ->
forall x y:R, a <= x <= b -> a <= y <= b -> x < y -> f x < f y.
Proof.
intros.
generalize (derive_increasing_interv_ax a b f pr H); intro.
elim H4; intros H5 _; apply (H5 H0 x y H1 H2 H3).
Qed.
(**********)
Lemma derive_increasing_interv_var :
forall (a b:R) (f:R -> R) (pr:derivable f),
a < b ->
(forall t:R, a < t < b -> 0 <= derive_pt f t (pr t)) ->
forall x y:R, a <= x <= b -> a <= y <= b -> x < y -> f x <= f y.
Proof.
intros a b f pr H H0 x y H1 H2 H3;
generalize (derive_increasing_interv_ax a b f pr H);
intro; elim H4; intros _ H5; apply (H5 H0 x y H1 H2 H3).
Qed.
(**********)
(**********)
Theorem IAF :
forall (f:R -> R) (a b k:R) (pr:derivable f),
a <= b ->
(forall c:R, a <= c <= b -> derive_pt f c (pr c) <= k) ->
f b - f a <= k * (b - a).
Proof.
intros.
case (total_order_T a b); intro.
elim s; intro.
assert (H1 := MVT_cor1 f _ _ pr a0).
elim H1; intros.
elim H2; intros.
rewrite H3.
do 2 rewrite <- (Rmult_comm (b - a)).
apply Rmult_le_compat_l.
apply Rplus_le_reg_l with a; rewrite Rplus_0_r.
replace (a + (b - a)) with b; [ assumption | ring ].
apply H0.
elim H4; intros.
split; left; assumption.
rewrite b0.
unfold Rminus; do 2 rewrite Rplus_opp_r.
rewrite Rmult_0_r; right; reflexivity.
elim (Rlt_irrefl _ (Rle_lt_trans _ _ _ H r)).
Qed.
Lemma IAF_var :
forall (f g:R -> R) (a b:R) (pr1:derivable f) (pr2:derivable g),
a <= b ->
(forall c:R, a <= c <= b -> derive_pt g c (pr2 c) <= derive_pt f c (pr1 c)) ->
g b - g a <= f b - f a.
Proof.
intros.
cut (derivable (g - f)).
intro X.
cut (forall c:R, a <= c <= b -> derive_pt (g - f) c (X c) <= 0).
intro.
assert (H2 := IAF (g - f)%F a b 0 X H H1).
rewrite Rmult_0_l in H2; unfold minus_fct in H2.
apply Rplus_le_reg_l with (- f b + f a).
replace (- f b + f a + (f b - f a)) with 0; [ idtac | ring ].
replace (- f b + f a + (g b - g a)) with (g b - f b - (g a - f a));
[ apply H2 | ring ].
intros.
cut
(derive_pt (g - f) c (X c) =
derive_pt (g - f) c (derivable_pt_minus _ _ _ (pr2 c) (pr1 c))).
intro.
rewrite H2.
rewrite derive_pt_minus.
apply Rplus_le_reg_l with (derive_pt f c (pr1 c)).
rewrite Rplus_0_r.
replace
(derive_pt f c (pr1 c) + (derive_pt g c (pr2 c) - derive_pt f c (pr1 c)))
with (derive_pt g c (pr2 c)); [ idtac | ring ].
apply H0; assumption.
apply pr_nu.
apply derivable_minus; assumption.
Qed.
(* If f has a null derivative in ]a,b[ and is continue in [a,b], *)
(* then f is constant on [a,b] *)
Lemma null_derivative_loc :
forall (f:R -> R) (a b:R) (pr:forall x:R, a < x < b -> derivable_pt f x),
(forall x:R, a <= x <= b -> continuity_pt f x) ->
(forall (x:R) (P:a < x < b), derive_pt f x (pr x P) = 0) ->
constant_D_eq f (fun x:R => a <= x <= b) (f a).
Proof.
intros; unfold constant_D_eq; intros; case (total_order_T a b); intro.
elim s; intro.
assert (H2 : forall y:R, a < y < x -> derivable_pt id y).
intros; apply derivable_pt_id.
assert (H3 : forall y:R, a <= y <= x -> continuity_pt id y).
intros; apply derivable_continuous; apply derivable_id.
assert (H4 : forall y:R, a < y < x -> derivable_pt f y).
intros; apply pr; elim H4; intros; split.
assumption.
elim H1; intros; apply Rlt_le_trans with x; assumption.
assert (H5 : forall y:R, a <= y <= x -> continuity_pt f y).
intros; apply H; elim H5; intros; split.
assumption.
elim H1; intros; apply Rle_trans with x; assumption.
elim H1; clear H1; intros; elim H1; clear H1; intro.
assert (H7 := MVT f id a x H4 H2 H1 H5 H3).
elim H7; intros; elim H8; intros; assert (H10 : a < x0 < b).
elim x1; intros; split.
assumption.
apply Rlt_le_trans with x; assumption.
assert (H11 : derive_pt f x0 (H4 x0 x1) = 0).
replace (derive_pt f x0 (H4 x0 x1)) with (derive_pt f x0 (pr x0 H10));
[ apply H0 | apply pr_nu ].
assert (H12 : derive_pt id x0 (H2 x0 x1) = 1).
apply derive_pt_eq_0; apply derivable_pt_lim_id.
rewrite H11 in H9; rewrite H12 in H9; rewrite Rmult_0_r in H9;
rewrite Rmult_1_r in H9; apply Rminus_diag_uniq; symmetry ;
assumption.
rewrite H1; reflexivity.
assert (H2 : x = a).
rewrite <- b0 in H1; elim H1; intros; apply Rle_antisym; assumption.
rewrite H2; reflexivity.
elim H1; intros;
elim (Rlt_irrefl _ (Rle_lt_trans _ _ _ (Rle_trans _ _ _ H2 H3) r)).
Qed.
(* Unicity of the antiderivative *)
Lemma antiderivative_Ucte :
forall (f g1 g2:R -> R) (a b:R),
antiderivative f g1 a b ->
antiderivative f g2 a b ->
exists c : R, (forall x:R, a <= x <= b -> g1 x = g2 x + c).
Proof.
unfold antiderivative; intros; elim H; clear H; intros; elim H0;
clear H0; intros H0 _; exists (g1 a - g2 a); intros;
assert (H3 : forall x:R, a <= x <= b -> derivable_pt g1 x).
intros; unfold derivable_pt; exists (f x0); elim (H x0 H3);
intros; eapply derive_pt_eq_1; symmetry ;
apply H4.
assert (H4 : forall x:R, a <= x <= b -> derivable_pt g2 x).
intros; unfold derivable_pt; exists (f x0);
elim (H0 x0 H4); intros; eapply derive_pt_eq_1; symmetry ;
apply H5.
assert (H5 : forall x:R, a < x < b -> derivable_pt (g1 - g2) x).
intros; elim H5; intros; apply derivable_pt_minus;
[ apply H3; split; left; assumption | apply H4; split; left; assumption ].
assert (H6 : forall x:R, a <= x <= b -> continuity_pt (g1 - g2) x).
intros; apply derivable_continuous_pt; apply derivable_pt_minus;
[ apply H3 | apply H4 ]; assumption.
assert (H7 : forall (x:R) (P:a < x < b), derive_pt (g1 - g2) x (H5 x P) = 0).
intros; elim P; intros; apply derive_pt_eq_0; replace 0 with (f x0 - f x0);
[ idtac | ring ].
assert (H9 : a <= x0 <= b).
split; left; assumption.
apply derivable_pt_lim_minus; [ elim (H _ H9) | elim (H0 _ H9) ]; intros;
eapply derive_pt_eq_1; symmetry ; apply H10.
assert (H8 := null_derivative_loc (g1 - g2)%F a b H5 H6 H7);
unfold constant_D_eq in H8; assert (H9 := H8 _ H2);
unfold minus_fct in H9; rewrite <- H9; ring.
Qed.
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