(* *)
(**************************************************************************)
-set "baseuri" "cic:/matita/ordered_group/".
+
include "group.ma".
record pogroup_ : Type ≝ {
og_abelian_group_: abelian_group;
- og_excedence:> excedence;
- og_with: carr og_abelian_group_ = apart_of_excedence og_excedence
+ og_excess:> excess;
+ og_with: carr og_abelian_group_ = apart_of_excess og_excess
}.
lemma og_abelian_group: pogroup_ → abelian_group.
record pogroup : Type ≝ {
og_carr:> pogroup_;
- canc_plusr_exc: ∀f,g,h:og_carr. f+h ≰ g+h → f ≰ g
+ plus_cancr_exc: ∀f,g,h:og_carr. f+h ≰ g+h → f ≰ g
}.
lemma fexc_plusr:
∀G:pogroup.∀x,y,z:G. x ≰ y → x+z ≰ y + z.
-intros 5 (G x y z L); apply (canc_plusr_exc ??? (-z));
+intros 5 (G x y z L); apply (plus_cancr_exc ??? (-z));
apply (Ex≪ (x + (z + -z)) (plus_assoc ????));
apply (Ex≪ (x + (-z + z)) (plus_comm ??z));
apply (Ex≪ (x+0) (opp_inverse ??));
coercion cic:/matita/ordered_group/fexc_plusr.con nocomposites.
-lemma canc_plusl_exc: ∀G:pogroup.∀f,g,h:G. h+f ≰ h+g → f ≰ g.
-intros 5 (G x y z L); apply (canc_plusr_exc ??? z);
+lemma plus_cancl_exc: ∀G:pogroup.∀f,g,h:G. h+f ≰ h+g → f ≰ g.
+intros 5 (G x y z L); apply (plus_cancr_exc ??? z);
apply (exc_rewl ??? (z+x) (plus_comm ???));
apply (exc_rewr ??? (z+y) (plus_comm ???) L);
qed.
lemma fexc_plusl:
∀G:pogroup.∀x,y,z:G. x ≰ y → z+x ≰ z+y.
-intros 5 (G x y z L); apply (canc_plusl_exc ??? (-z));
+intros 5 (G x y z L); apply (plus_cancl_exc ??? (-z));
apply (exc_rewl ???? (plus_assoc ??z x));
apply (exc_rewr ???? (plus_assoc ??z y));
apply (exc_rewl ??? (0+x) (opp_inverse ??));
apply (le_rewr ??? (y+(-z+z)) (opp_inverse ??));
apply (le_rewr ??? (y+(z+ -z)) (plus_comm ??z));
apply (le_rewr ??? (y+z+ -z) (plus_assoc ????));
-intro H; apply L; clear L; apply (canc_plusr_exc ??? (-z) H);
+intro H; apply L; clear L; apply (plus_cancr_exc ??? (-z) H);
qed.
lemma fle_plusl: ∀G:pogroup. ∀f,g,h:G. f≤g → h+f≤h+g.
lemma exc_opp_x_zero_to_exc_zero_x:
∀G:pogroup.∀x:G.-x ≰ 0 → 0 ≰ x.
-intros (G x H); apply (canc_plusr_exc ??? (-x));
+intros (G x H); apply (plus_cancr_exc ??? (-x));
apply (exc_rewr ???? (plus_comm ???));
apply (exc_rewr ???? (opp_inverse ??));
apply (exc_rewl ???? (zero_neutral ??) H);
lemma exc_zero_opp_x_to_exc_x_zero:
∀G:pogroup.∀x:G. 0 ≰ -x → x ≰ 0.
-intros (G x H); apply (canc_plusl_exc ??? (-x));
+intros (G x H); apply (plus_cancl_exc ??? (-x));
apply (exc_rewr ???? (plus_comm ???));
apply (exc_rewl ???? (opp_inverse ??));
apply (exc_rewr ???? (zero_neutral ??) H);
assumption;
qed.
+lemma lt_opp_x_zero_to_lt_zero_x:
+ ∀G:pogroup.∀x:G. -x < 0 → 0 < x.
+intros (G x Lx0); apply (plus_cancr_lt ??? (-x));
+apply (lt_rewl ??? (-x) (zero_neutral ??));
+apply (lt_rewr ??? (-x+x) (plus_comm ???));
+apply (lt_rewr ??? 0 (opp_inverse ??));
+assumption;
+qed.
lemma lt0plus_orlt:
∀G:pogroup. ∀x,y:G. 0 ≤ x → 0 ≤ y → 0 < x + y → 0 < x ∨ 0 < y.
lemma lexxyy_lexy: ∀G:togroup. ∀x,y:G. x+x ≤ y+y → x ≤ y.
intros (G x y H); intro H1; lapply (tog_total ??? H1) as H2;
-lapply (ltxy_ltyyxx ??? H2) as H3; lapply (lt_to_excede ??? H3) as H4;
+lapply (ltxy_ltyyxx ??? H2) as H3; lapply (lt_to_excess ??? H3) as H4;
cases (H H4);
qed.
apply lexxyy_lexy; assumption;
qed.
-lemma bar: ∀G:abelian_group. ∀x,y:G. 0 # x + y → 0 #x ∨ 0#y.
+lemma applus_orap: ∀G:abelian_group. ∀x,y:G. 0 # x + y → 0 #x ∨ 0#y.
intros; cases (ap_cotransitive ??? y a); [right; assumption]
left; apply (plus_cancr_ap ??? y); apply (ap_rewl ???y (zero_neutral ??));
assumption;
qed.
-lemma pippo: ∀G:pogroup.∀a,b,c,d:G. a < b → c < d → a+c < b + d.
+lemma ltplus: ∀G:pogroup.∀a,b,c,d:G. a < b → c < d → a+c < b + d.
intros (G a b c d H1 H2);
lapply (flt_plusr ??? c H1) as H3;
apply (lt_transitive ???? H3);
apply flt_plusl; assumption;
qed.
-lemma pippo2: ∀G:pogroup.∀a,b,c,d:G. a+c ≰ b + d → a ≰ b ∨ c ≰ d.
+lemma excplus_orexc: ∀G:pogroup.∀a,b,c,d:G. a+c ≰ b + d → a ≰ b ∨ c ≰ d.
intros (G a b c d H1 H2);
cases (exc_cotransitive ??? (a + d) H1); [
- right; apply (canc_plusl_exc ??? a); assumption]
-left; apply (canc_plusr_exc ??? d); assumption;
+ right; apply (plus_cancl_exc ??? a); assumption]
+left; apply (plus_cancr_exc ??? d); assumption;
qed.
-lemma pippo3: ∀G:pogroup.∀a,b,c,d:G. a ≤ b → c ≤ d → a+c ≤ b + d.
-intros (G a b c d H1 H2); intro H3; cases (pippo2 ????? H3);
+lemma leplus: ∀G:pogroup.∀a,b,c,d:G. a ≤ b → c ≤ d → a+c ≤ b + d.
+intros (G a b c d H1 H2); intro H3; cases (excplus_orexc ????? H3);
[apply H1|apply H2] assumption;
qed.
-lemma foo: ∀G:togroup.∀x,y:G. 0 ≤ x + y → x < 0 → 0 ≤ y.
-intros; intro; apply H; lapply (lt_to_excede ??? l);
+lemma leplus_lt_le: ∀G:togroup.∀x,y:G. 0 ≤ x + y → x < 0 → 0 ≤ y.
+intros; intro; apply H; lapply (lt_to_excess ??? l);
lapply (tog_total ??? e);
lapply (tog_total ??? Hletin);
-lapply (pippo ????? Hletin2 Hletin1);
+lapply (ltplus ????? Hletin2 Hletin1);
apply (exc_rewl ??? (0+0)); [apply eq_sym; apply zero_neutral]
-apply lt_to_excede; assumption;
+apply lt_to_excess; assumption;
qed.
-lemma pippo4: ∀G:togroup.∀a,b,c,d:G. a+c < b + d → a < b ∨ c < d.
-intros (G a b c d H1 H2); lapply (lt_to_excede ??? H1);
-cases (pippo2 ????? Hletin); [left|right] apply tog_total; assumption;
+lemma ltplus_orlt: ∀G:togroup.∀a,b,c,d:G. a+c < b + d → a < b ∨ c < d.
+intros (G a b c d H1 H2); lapply (lt_to_excess ??? H1);
+cases (excplus_orexc ????? Hletin); [left|right] apply tog_total; assumption;
+qed.
+
+lemma excplus: ∀G:togroup.∀a,b,c,d:G.a ≰ b → c ≰ d → a + c ≰ b + d.
+intros (G a b c d L1 L2);
+lapply (fexc_plusr ??? (c) L1) as L3;
+elim (exc_cotransitive ??? (b+d) L3); [assumption]
+lapply (plus_cancl_exc ???? t); lapply (tog_total ??? Hletin);
+cases Hletin1; cases (H L2);
qed.
projects / helm.git / blobdiff