(*
This file is a part of IsarMathLib -
a library of formalized mathematics for Isabelle/Isar.
Copyright (C) 2005, 2006 Slawomir Kolodynski
This program is free software; Redistribution and use in source and binary forms,
with or without modification, are permitted provided that the
following conditions are met:
1. Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice,
this list of conditions and the following disclaimer in the documentation and/or
other materials provided with the distribution.
3. The name of the author may not be used to endorse or promote products
derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*)
header {*\isaheader{Group\_ZF.thy}*}
theory Group_ZF imports func_ZF
begin;
text{*This theory file will cover basics of group theory.*}
section{*Monoids.*}
text{*Monoid is a set with an associative operation and a neutral element.
The operation is of course a function on $G\times G$ with values in $G$,
and therefore it is a subset of $(G\times G)\times G$.
Those who don't like that can go to HOL.
Monoid is like a group except that we don't require existence of
the inverse.*}
constdefs
"IsAmonoid(G,f) ≡
f {is associative on} G ∧
(∃e∈G. (∀ g∈G. ( (f`(<e,g>) = g) ∧ (f`(<g,e>) = g))))";
text{*We use locales to define notation. This allows to separate notation
and notion definitions. We would like to use additive notation for
monoid, but unfortunately + is already taken.*}
locale monoid0 =
fixes G and f
assumes monoidAsssum:"IsAmonoid(G,f)"
fixes monoper (infixl "⊕" 70)
defines monoper_def [simp]: "a ⊕ b ≡ f`<a,b>";
text{*The result of the monoid operation is in the monoid (carrier).*}
lemma (in monoid0) group0_1_L1:
assumes "a∈G" "b∈G" shows "a⊕b ∈ G";
using prems monoidAsssum IsAmonoid_def IsAssociative_def apply_funtype
by auto;
text{*There is only one neutral element in monoid.*}
lemma (in monoid0) group0_1_L2:
"∃!e. e∈G ∧ (∀ g∈G. ( (e⊕g = g) ∧ g⊕e = g))"
proof
fix e y
assume "e ∈ G ∧ (∀g∈G. e ⊕ g = g ∧ g ⊕ e = g)"
and "y ∈ G ∧ (∀g∈G. y ⊕ g = g ∧ g ⊕ y = g)"
then have "y⊕e = y" "y⊕e = e" by auto;
thus "e = y" by simp;
next from monoidAsssum show
"∃e. e∈ G ∧ (∀ g∈G. e⊕g = g ∧ g⊕e = g)"
using IsAmonoid_def by auto;
qed;
text{*We could put the definition of neutral element anywhere,
but it is only usable in conjuction
with the above lemma.*}
constdefs
"TheNeutralElement(G,f) ≡
( THE e. e∈G ∧ (∀ g∈G. f`<e,g> = g ∧ f`<g,e> = g))";
text{*The neutral element is neutral.*}
lemma (in monoid0) group0_1_L3:
assumes A1: "e = TheNeutralElement(G,f)"
shows "e ∈ G ∧ (∀g∈G. e ⊕ g = g ∧ g ⊕ e = g)"
proof -;
let ?n = "THE b. b∈ G ∧ (∀ g∈G. b⊕g = g ∧ g⊕b = g)";
have "∃!b. b∈ G ∧ (∀ g∈G. b⊕g = g ∧ g⊕b = g)"
using group0_1_L2 by simp;
hence "?n∈ G ∧ (∀ g∈G. ?n⊕g = g ∧ g⊕?n = g)"
by (rule theI);
with A1 show ?thesis
using TheNeutralElement_def by simp;
qed;
text{*The monoid carrier is not empty.*}
lemma (in monoid0) group0_1_L3A: "G≠0"
proof -;
have "TheNeutralElement(G,f) ∈ G" using group0_1_L3
by simp;
thus ?thesis by auto;
qed;
text{* The range of the monoid operation is the whole monoid carrier.*}
lemma (in monoid0) group0_1_L3B: "range(f) = G"
proof;
from monoidAsssum have T1:"f : G×G->G"
using IsAmonoid_def IsAssociative_def by simp;
then show "range(f) ⊆ G"
using func1_1_L5B by simp;
show "G ⊆ range(f)"
proof;
fix g assume A1:"g∈G"
let ?e = "TheNeutralElement(G,f)"
from A1 have "<?e,g> ∈ G×G" "g = f`<?e,g>"
using group0_1_L3 by auto;
with T1 show "g ∈ range(f)"
using func1_1_L5A by blast;
qed;
qed;
text{*In a monoid a neutral element is the neutral element.*}
lemma (in monoid0) group0_1_L4:
assumes A1: "e ∈ G ∧ (∀g∈G. e ⊕ g = g ∧ g ⊕ e = g)"
shows "e = TheNeutralElement(G,f)"
proof -
let ?n = "THE b. b∈ G ∧ (∀ g∈G. b⊕g = g ∧ g⊕b = g)";
have "∃!b. b∈ G ∧ (∀ g∈G. b⊕g = g ∧ g⊕b = g)"
using group0_1_L2 by simp;
moreover from A1 have
"e ∈ G ∧ (∀g∈G. e ⊕ g = g ∧ g ⊕ e = g)" .;
ultimately have "(?n) = e" by (rule the_equality2);
then show ?thesis using TheNeutralElement_def by simp;
qed;
text{*The next lemma shows that if the if we restrict the monoid operation to
a subset of $G$ that contains the neutral element, then the
neutral element of the monoid operation is also neutral with the
restricted operation. This is proven separately because it is
used more than once.
*}
lemma (in monoid0) group0_1_L5:
assumes A1: "∀x∈H.∀y∈H. x⊕y ∈ H"
and A2: "H⊆G"
and A3: "e = TheNeutralElement(G,f)"
and A4: "g = restrict(f,H×H)"
and A5: "e∈H"
and A6: "h∈H"
shows "g`<e,h> = h ∧ g`<h,e> = h";
proof -;
from A4 A6 A5 have
"g`<e,h> = e⊕h ∧ g`<h,e> = h⊕e"
using restrict_if by simp;
with A3 A4 A6 A2 show
"g`<e,h> = h ∧ g`<h,e> = h"
using group0_1_L3 by auto;
qed;
text{*The next theorem shows that if the monoid operation is closed
on a subset of $G$ then this set is a (sub)monoid.
(although we do not define this notion). This will be
useful when we study subgroups. *}
theorem (in monoid0) group0_1_T1:
assumes A1: "H {is closed under} f"
and A2: "H⊆G"
and A3: "TheNeutralElement(G,f) ∈ H"
shows "IsAmonoid(H,restrict(f,H×H))"
proof -;
let ?g = "restrict(f,H×H)"
let ?e = "TheNeutralElement(G,f)"
from monoidAsssum have "f ∈ G×G->G"
using IsAmonoid_def IsAssociative_def by simp;
moreover from A2 have "H×H ⊆ G×G" by auto;
moreover from A1 have "∀p ∈ H×H. f`(p) ∈ H"
using IsOpClosed_def by auto;
ultimately have "?g ∈ H×H->H";
using func1_2_L4 by simp;
moreover have "∀x∈H.∀y∈H.∀z∈H.
?g`⟨?g`<x,y>,z⟩ = ?g`⟨x,?g`<y,z>⟩"
proof -
from A1 have "∀x∈H.∀y∈H.∀z∈H.
?g`⟨?g`<x,y>,z⟩ = x⊕y⊕z"
using IsOpClosed_def restrict_if by simp;
moreover have "∀x∈H.∀y∈H.∀z∈H. x⊕y⊕z = x⊕(y⊕z)"
proof -;
from monoidAsssum have
"∀x∈G.∀y∈G.∀z∈G. x⊕y⊕z = x⊕(y⊕z)"
using IsAmonoid_def IsAssociative_def
by simp;
with A2 show ?thesis by auto;
qed;
moreover from A1 have
"∀x∈H.∀y∈H.∀z∈H. x⊕(y⊕z) = ?g`⟨ x,?g`<y,z>⟩"
using IsOpClosed_def restrict_if by simp;
ultimately show ?thesis by simp;
qed;
moreover have
"∃n∈H. (∀h∈H. ?g`<n,h> = h ∧ ?g`<h,n> = h)"
proof -;
from A1 have "∀x∈H.∀y∈H. x⊕y ∈ H"
using IsOpClosed_def by simp;
with A2 A3 have
"∀ h∈H. ?g`<?e,h> = h ∧ ?g`<h,?e> = h"
using group0_1_L5 by blast;
with A3 show ?thesis by auto;
qed;
ultimately show ?thesis using IsAmonoid_def IsAssociative_def
by simp;
qed;
text{*Under the assumptions of @{text " group0_1_T1"}
the neutral element of a
submonoid is the same as that of the monoid.*}
lemma group0_1_L6:
assumes A1: "IsAmonoid(G,f)"
and A2: "H {is closed under} f"
and A3: "H⊆G"
and A4: "TheNeutralElement(G,f) ∈ H"
shows "TheNeutralElement(H,restrict(f,H×H)) = TheNeutralElement(G,f)"
proof -
def D1: e ≡ "TheNeutralElement(G,f)"
def D2: g ≡ "restrict(f,H×H)"
with A1 A2 A3 A4 have "monoid0(H,g)";
using monoid0_def monoid0.group0_1_T1
by simp;
moreover have
"e ∈ H ∧ (∀h∈H. g`<e,h> = h ∧ g`<h,e> = h)"
proof -;
from A1 A2 have "monoid0(G,f)" "∀x∈H.∀y∈H. f`<x,y> ∈ H"
using monoid0_def IsOpClosed_def by auto;
with A3 D1 D2 A4 show ?thesis
using monoid0.group0_1_L5 by blast;
qed;
ultimately have "e = TheNeutralElement(H,g)"
using monoid0.group0_1_L4 by auto;
with D1 D2 show ?thesis by simp;
qed;
section{*Basic definitions and results for groups*}
text{*To define a group we take a monoid and add a requirement
that the right inverse needs to exist for every element of the group.
We also define the group inverse as a relation on the group carrier.
Later we will show that this relation is a function.
The @{text "GroupInv"} below is really the right inverse, understood as a function,
that is a subset of $G\times G$.*}
constdefs
"IsAgroup(G,f) ≡
(IsAmonoid(G,f) ∧ (∀g∈G. ∃b∈G. f`<g,b> = TheNeutralElement(G,f)))"
"GroupInv(G,f) ≡ {<x,y> ∈ G×G. f`<x,y> = TheNeutralElement(G,f)}"
text{*We will use the miltiplicative notation for groups.*}
locale group0 =
fixes G and f
assumes groupAssum: "IsAgroup(G,f)"
fixes neut ("\<one>")
defines neut_def[simp]: "\<one> ≡ TheNeutralElement(G,f)"
fixes groper (infixl "·" 70)
defines groper_def [simp]: "a · b ≡ f`<a,b>"
fixes inv ("_¯ " [90] 91)
defines inv_def[simp]: "x¯ ≡ GroupInv(G,f)`(x)"
text{*First we show a lemma that says that we can use theorems proven in
the @{text "monoid0"} context (locale).*}
lemma (in group0) group0_2_L1: "monoid0(G,f)"
using groupAssum IsAgroup_def monoid0_def by simp;
text{*In some strange cases Isabelle has difficulties with applying
the definition of a group. The next lemma defines a rule to be applied
in such cases.*}
lemma definition_of_group: assumes "IsAmonoid(G,f)"
and "∀g∈G. ∃b∈G. f`⟨g,b⟩ = TheNeutralElement(G,f)"
shows "IsAgroup(G,f)"
using prems IsAgroup_def by simp;
text{*Technical lemma that allows to use $1$ as the neutral element of
the group without referencing a list of lemmas and definitions.*}
lemma (in group0) group0_2_L2:
shows "\<one>∈G ∧ (∀g∈G.(\<one>·g = g ∧ g·\<one> = g))"
using group0_2_L1 monoid0.group0_1_L3 by simp;
text{*The group is closed under the group operation. Used all the time,
useful to have handy.*}
lemma (in group0) group_op_closed: assumes "a∈G" "b∈G"
shows "a·b ∈ G" using prems group0_2_L1 monoid0.group0_1_L1
by simp;
text{*The group operation is associative. This is another technical lemma
that allows to shorten the list of referenced lemmas in some proofs.*}
lemma (in group0) group_oper_assoc:
assumes "a∈G" "b∈G" "c∈G" shows "a·(b·c) = a·b·c"
using groupAssum prems IsAgroup_def IsAmonoid_def
IsAssociative_def group_op_closed by simp;
text{*The group operation maps $G\times G$ into $G$. It is conveniet to have
this fact easily accessible in the group0 context.*}
lemma (in group0) group_oper_assocA: shows "f : G×G->G"
using groupAssum IsAgroup_def IsAmonoid_def IsAssociative_def
by simp;
text{*The definition of group requires the existence of the right inverse.
We show that this is also the left inverse.*}
theorem (in group0) group0_2_T1:
assumes A1: "g∈G" and A2: "b∈G" and A3: "g·b = \<one>"
shows "b·g = \<one>";
proof -
from A2 groupAssum obtain c where I: "c ∈ G ∧ b·c = \<one>"
using IsAgroup_def by auto;
then have T1: "c∈G" by simp;
have T2: "\<one>∈G" using group0_2_L2 by simp;
from A1 A2 T2 I have "b·g = b·(g·(b·c))"
using group_op_closed group0_2_L2 group_oper_assoc
by simp;
also from A1 A2 T1 have "b·(g·(b·c)) = b·(g·b·c)"
using group_oper_assoc by simp;
also from A3 A2 I have "b·(g·b·c)= \<one>" using group0_2_L2 by simp;
finally show "b·g = \<one>" by simp;
qed;
text{*For every element of a group there is only one inverse.*}
lemma (in group0) group0_2_L4:
assumes A1:"x∈G" shows "∃!y. y∈G ∧ x·y = \<one>"
proof;
from A1 groupAssum show "∃y. y∈G ∧ x·y = \<one>"
using IsAgroup_def by auto;
fix y n
assume A2:"y∈G ∧ x·y = \<one>" and A3:"n∈G ∧ x·n = \<one>" show "y=n"
proof -
from A1 A2 have T1:"y·x = \<one>"
using group0_2_T1 by simp;
from A2 A3 have "y = y·(x·n)"
using group0_2_L2 by simp;
also from A1 A2 A3 have "… = (y·x)·n"
using group_oper_assoc by blast;
also from T1 A3 have "… = n"
using group0_2_L2 by simp;
finally show "y=n" by simp;
qed;
qed;
text{*The group inverse is a function that maps G into G.*}
theorem group0_2_T2:
assumes A1: "IsAgroup(G,f)" shows "GroupInv(G,f) : G->G"
proof -;
have "GroupInv(G,f) ⊆ G×G" using GroupInv_def by auto;
moreover from A1 have
"∀x∈G. ∃!y. y∈ G ∧ <x,y> ∈ GroupInv(G,f)"
using group0_def group0.group0_2_L4 GroupInv_def by simp;
ultimately show ?thesis using func1_1_L11 by simp;
qed;
text{*We can think about the group inverse (the function)
as the inverse image of the neutral element.*}
theorem (in group0) group0_2_T3: shows "f-``{\<one>} = GroupInv(G,f)"
proof -;
from groupAssum have "f : G×G -> G"
using IsAgroup_def IsAmonoid_def IsAssociative_def
by simp;
then show "f-``{\<one>} = GroupInv(G,f)"
using func1_1_L14 GroupInv_def by auto;
qed;
text{*The inverse is in the group.*}
lemma (in group0) inverse_in_group: assumes A1: "x∈G" shows "x¯∈G"
proof -
from groupAssum have "GroupInv(G,f) : G->G" using group0_2_T2 by simp;
with A1 show ?thesis using apply_type by simp;
qed;
text{*The notation for the inverse means what it is supposed to mean.*}
lemma (in group0) group0_2_L6:
assumes A1: "x∈G" shows "x·x¯ = \<one> ∧ x¯·x = \<one>"
proof;
from groupAssum have "GroupInv(G,f) : G->G"
using group0_2_T2 by simp;
with A1 have "<x,x¯> ∈ GroupInv(G,f)"
using apply_Pair by simp;
then show "x·x¯ = \<one>" using GroupInv_def by simp;
with A1 show "x¯·x = \<one>" using inverse_in_group group0_2_T1 by blast;
qed;
text{*The next two lemmas state that unless we multiply by
the neutral element, the result is always
different than any of the operands.*}
lemma (in group0) group0_2_L7:
assumes A1: "a∈G" and A2: "b∈G" and A3: "a·b = a"
shows "b=\<one>"
proof -;
from A3 have "a¯ · (a·b) = a¯·a" by simp;
with A1 A2 show ?thesis using
inverse_in_group group_oper_assoc group0_2_L6 group0_2_L2
by simp;
qed;
lemma (in group0) group0_2_L8:
assumes A1: "a∈G" and A2: "b∈G" and A3:"a·b = b"
shows "a=\<one>"
proof -;
from A3 have "(a·b)·b¯ = b·b¯" by simp;
with A1 A2 have "a·(b·b¯) = b·b¯" using
inverse_in_group group_oper_assoc by simp;
with A1 A2 show ?thesis
using group0_2_L6 group0_2_L2 by simp;
qed;
text{*The inverse of the neutral element is the neutral element.*}
lemma (in group0) group_inv_of_one: shows "\<one>¯=\<one>"
using group0_2_L2 inverse_in_group group0_2_L6 group0_2_L7 by blast;
text{*if $a^{-1} = 1$, then $a=1$. *}
lemma (in group0) group0_2_L8A:
assumes A1: "a∈G" and A2: "a¯ = \<one>"
shows "a = \<one>"
proof -
from A1 have "a·a¯ = \<one>" using group0_2_L6 by simp
with A1 A2 show "a = \<one>" using group0_2_L2 by simp
qed;
text{*If $a$ is not a unit, then its inverse is not either.*}
lemma (in group0) group0_2_L8B:
assumes "a∈G" and "a ≠ \<one>"
shows "a¯ ≠ \<one>" using prems group0_2_L8A by auto;
text{*If $a^{-1}$ is not a unit, then a is not either.*}
lemma (in group0) group0_2_L8C:
assumes "a∈G" and "a¯ ≠ \<one>"
shows "a≠\<one>"
using prems group0_2_L8A group_inv_of_one by auto;
text{*If a product of two elements of a group is equal to the neutral
element then they are inverses of each other. *}
lemma (in group0) group0_2_L9:
assumes A1: "a∈G" and A2: "b∈G" and A3: "a·b = \<one>"
shows "a = b¯" "b = a¯"
proof -;
from A3 have "a·b·b¯ = \<one>·b¯" by simp;
with A1 A2 have "a·(b·b¯) = \<one>·b¯" using
inverse_in_group group_oper_assoc by simp;
with A1 A2 show "a = b¯" using
group0_2_L6 inverse_in_group group0_2_L2 by simp;
from A3 have "a¯·(a·b) = a¯·\<one>" by simp;
with A1 A2 show "b = a¯" using
inverse_in_group group_oper_assoc group0_2_L6 group0_2_L2
by simp;
qed;
text{*It happens quite often that we know what is (have a meta-function for)
the right inverse in a group. The next lemma shows that the value
of the group inverse (function) is equal to the right inverse
(meta-function).*}
lemma (in group0) group0_2_L9A:
assumes A1: "∀g∈G. b(g) ∈ G ∧ g·b(g) = \<one>"
shows "∀g∈G. b(g) = g¯"
proof;
fix g assume A2: "g∈G"
moreover from A2 A1 have "b(g) ∈ G" by simp;
moreover from A1 A2 have "g·b(g) = \<one>" by simp;
ultimately show "b(g) = g¯" by (rule group0_2_L9);
qed;
text{*What is the inverse of a product?*}
lemma (in group0) group_inv_of_two:
assumes A1: "a∈G" and A2: "b∈G"
shows " b¯·a¯ = (a·b)¯"
proof -;
from A1 A2 have
T1: "b¯∈G" and T2: "a¯∈G" and T3: "a·b∈G" and T4: "b¯·a¯ ∈ G"
using inverse_in_group group_op_closed
by auto;
from A1 A2 T4 have "a·b·(b¯·a¯) = a·(b·(b¯·a¯))"
using group_oper_assoc by simp;
moreover from A2 T1 T2 have "b·(b¯·a¯) = b·b¯·a¯"
using group_oper_assoc by simp;
moreover from A2 T2 have "b·b¯·a¯ = a¯"
using group0_2_L6 group0_2_L2 by simp;
ultimately have "a·b·(b¯·a¯) = a·a¯"
by simp;
with A1 have "a·b·(b¯·a¯) = \<one>"
using group0_2_L6 by simp;
with T3 T4 show "b¯·a¯ = (a·b)¯"
using group0_2_L9 by simp;
qed;
text{*What is the inverse of a product of three elements?*}
lemma (in group0) group_inv_of_three:
assumes A1: "a∈G" "b∈G" "c∈G"
shows
"(a·b·c)¯ = c¯·(a·b)¯"
"(a·b·c)¯ = c¯·(b¯·a¯)"
"(a·b·c)¯ = c¯·b¯·a¯"
proof -
from A1 have T:
"a·b ∈ G" "a¯ ∈ G" "b¯ ∈ G" "c¯ ∈ G"
using group_op_closed inverse_in_group by auto;
with A1 show
"(a·b·c)¯ = c¯·(a·b)¯" and "(a·b·c)¯ = c¯·(b¯·a¯)"
using group_inv_of_two by auto;
with T show "(a·b·c)¯ = c¯·b¯·a¯" using group_oper_assoc
by simp;
qed;
text{*The inverse of the inverse is the element.*}
lemma (in group0) group_inv_of_inv:
assumes "a∈G" shows "a = (a¯)¯"
using prems inverse_in_group group0_2_L6 group0_2_L9
by simp;
text{*If $a^{-1}\cdot b=1$, then $a=b$.*}
lemma (in group0) group0_2_L11:
assumes A1: "a∈G" "b∈G" and A2: "a¯·b = \<one>"
shows "a=b"
proof -
from A1 A2 have "a¯ ∈ G" "b∈G" "a¯·b = \<one>"
using inverse_in_group by auto;
then have "b = (a¯)¯" by (rule group0_2_L9);
with A1 show "a=b" using group_inv_of_inv by simp;
qed;
text{*If $a\cdot b^{-1}=1$, then $a=b$.*}
lemma (in group0) group0_2_L11A:
assumes A1: "a∈G" "b∈G" and A2: "a·b¯ = \<one>"
shows "a=b"
proof -
from A1 A2 have "a ∈ G" "b¯∈G" "a·b¯ = \<one>"
using inverse_in_group by auto
then have "a = (b¯)¯" by (rule group0_2_L9)
with A1 show "a=b" using group_inv_of_inv by simp
qed;
text{*If if the inverse of $b$ is different than $a$, then the
inverse of $a$ is different than $b$.*}
lemma (in group0) group0_2_L11B:
assumes A1: "a∈G" and A2: "b¯ ≠ a"
shows "a¯ ≠ b"
proof -
{ assume "a¯ = b"
then have "(a¯)¯ = b¯" by simp
with A1 A2 have False using group_inv_of_inv
by simp;
} then show "a¯ ≠ b" by auto;
qed;
text{*What is the inverse of $ab^{-1}$ ?*}
lemma (in group0) group0_2_L12:
assumes A1: "a∈G" "b∈G"
shows
"(a·b¯)¯ = b·a¯"
"(a¯·b)¯ = b¯·a"
proof -
from A1 have
"(a·b¯)¯ = (b¯)¯· a¯" "(a¯·b)¯ = b¯·(a¯)¯"
using inverse_in_group group_inv_of_two by auto;
with A1 show "(a·b¯)¯ = b·a¯" "(a¯·b)¯ = b¯·a"
using group_inv_of_inv by auto
qed;
(*text{*What is the inverse of a product of three elements?*}
lemma (in group0) group_inv_of_three:
assumes A1: "a∈G" "b∈G" "c∈G"
shows "(a·b·c)¯ = c¯·b¯·a¯"
proof -
from A1 have T: "a·b ∈ G" "a¯ ∈ G" "b¯ ∈ G" "c¯ ∈ G"
using group_op_closed inverse_in_group by auto;
with A1 have
"(a·b·c)¯ = c¯·(b¯·a¯)"
using group_inv_of_two by auto;
also from T have "… = c¯·b¯·a¯"
using group_oper_assoc by simp
finally show "(a·b·c)¯ = c¯·b¯·a¯" by simp;
qed;*)
text{*A couple useful rearrangements with three elements:
we can insert a $b\cdot b^{-1}$
between two group elements (another version) and one about a product of
an element and inverse of a product, and two others.*}
lemma (in group0) group0_2_L14A:
assumes A1: "a∈G" "b∈G" "c∈G"
shows
"a·c¯= (a·b¯)·(b·c¯)"
"a¯·c = (a¯·b)·(b¯·c)"
"a·(b·c)¯ = a·c¯·b¯"
"a·(b·c¯) = a·b·c¯"
"(a·b¯·c¯)¯ = c·b·a¯"
"a·b·c¯·(c·b¯) = a"
"a·(b·c)·c¯ = a·b"
proof -
from A1 have T:
"a¯ ∈ G" "b¯∈G" "c¯∈G"
"a¯·b ∈ G" "a·b¯ ∈ G" "a·b ∈ G"
"c·b¯ ∈ G" "b·c ∈ G"
using inverse_in_group group_op_closed
by auto;
from A1 T have
"a·c¯ = a·(b¯·b)·c¯"
"a¯·c = a¯·(b·b¯)·c"
using group0_2_L2 group0_2_L6 by auto;
with A1 T show
"a·c¯= (a·b¯)·(b·c¯)"
"a¯·c = (a¯·b)·(b¯·c)"
using group_oper_assoc by auto;
from A1 have "a·(b·c)¯ = a·(c¯·b¯)"
using group_inv_of_two by simp;
with A1 T show "a·(b·c)¯ =a·c¯·b¯"
using group_oper_assoc by simp;
from A1 T show "a·(b·c¯) = a·b·c¯"
using group_oper_assoc by simp
from A1 T show "(a·b¯·c¯)¯ = c·b·a¯"
using group_inv_of_three group_inv_of_inv
by simp;
from T have "a·b·c¯·(c·b¯) = a·b·(c¯·(c·b¯))"
using group_oper_assoc by simp;
also from A1 T have "… = a·b·b¯"
using group_oper_assoc group0_2_L6 group0_2_L2
by simp;
also from A1 T have "… = a·(b·b¯)"
using group_oper_assoc by simp;
also from A1 have "… = a"
using group0_2_L6 group0_2_L2 by simp;
finally show "a·b·c¯·(c·b¯) = a" by simp;
from A1 T have "a·(b·c)·c¯ = a·(b·(c·c¯))"
using group_oper_assoc by simp;
also from A1 T have "… = a·b"
using group0_2_L6 group0_2_L2 by simp;
finally show "a·(b·c)·c¯ = a·b"
by simp;
qed;
text{*Another lemma about rearranging a product.*}
lemma (in group0) group0_2_L15:
assumes A1: "a∈G" "b∈G" "c∈G" "d∈G"
shows "(a·b)·(c·d)¯ = a·(b·d¯)·a¯·(a·c¯)"
proof -
from A1 have T1:
"d¯∈G" "c¯∈G" "a·b∈G" "a·(b·d¯)∈G"
using inverse_in_group group_op_closed
by auto;
with A1 have "(a·b)·(c·d)¯ = (a·b)·(d¯·c¯)"
using group_inv_of_two by simp;
also from A1 T1 have "… = a·(b·d¯)·c¯"
using group_oper_assoc by simp;
also from A1 T1 have "… = a·(b·d¯)·a¯·(a·c¯)"
using group0_2_L14A by blast;
finally show ?thesis by simp;
qed;
text{*We can cancel an element with its inverse that is written next to it.*}
lemma (in group0) group0_2_L16:
assumes A1: "a∈G" "b∈G"
shows
"a·b¯·b = a"
"a·b·b¯ = a"
"a¯·(a·b) = b"
"a·(a¯·b) = b"
proof -
from A1 have
"a·b¯·b = a·(b¯·b)" "a·b·b¯ = a·(b·b¯)"
"a¯·(a·b) = a¯·a·b" "a·(a¯·b) = a·a¯·b"
using inverse_in_group group_oper_assoc by auto;
with A1 show
"a·b¯·b = a"
"a·b·b¯ = a"
"a¯·(a·b) = b"
"a·(a¯·b) = b"
using group0_2_L6 group0_2_L2 by auto;
qed;
text{*Another lemma about cancelling with two group elements.*}
lemma (in group0) group0_2_L16A:
assumes A1: "a∈G" "b∈G"
shows "a·(b·a)¯ = b¯"
proof -
from A1 have "(b·a)¯ = a¯·b¯" "b¯ ∈ G"
using group_inv_of_two inverse_in_group by auto;
with A1 show "a·(b·a)¯ = b¯" using group0_2_L16
by simp;
qed;
text{*A hard to clasify fact: adding a neutral element to a set that is
closed under the group operation results in a set that is closed under the
group operation.*}
lemma (in group0) group0_2_L17:
assumes A1: "H⊆G"
and A2: "H {is closed under} f"
shows "(H ∪ {\<one>}) {is closed under} f"
proof -;
{ fix a b assume A3: "a ∈ H ∪ {\<one>}" "b ∈ H ∪ {\<one>}"
have "a·b ∈ H ∪ {\<one>}"
proof (cases "a∈H")
assume A4: "a∈H" show "a·b ∈ H ∪ {\<one>}"
proof (cases "b∈H")
assume "b∈H"
with A2 A4 show "a·b ∈ H ∪ {\<one>}" using IsOpClosed_def
by simp;
next assume "b∉H"
with A1 A3 A4 show "a·b ∈ H ∪ {\<one>}"
using group0_2_L2 by auto;
qed;
next assume "a∉H"
with A1 A3 show "a·b ∈ H ∪ {\<one>}"
using group0_2_L2 by auto;
qed
} then show "(H ∪ {\<one>}) {is closed under} f"
using IsOpClosed_def by auto;
qed;
text{*We can put an element on the other side of an equation.*}
lemma (in group0) group0_2_L18:
assumes A1: "a∈G" "b∈G" "c∈G"
and A2: "c = a·b"
shows "c·b¯ = a" "a¯·c = b"
proof-;
from A2 A1 have "c·b¯ = a·(b·b¯)" "a¯·c = (a¯·a)·b"
using inverse_in_group group_oper_assoc by auto;
moreover from A1 have "a·(b·b¯) = a" "(a¯·a)·b = b"
using group0_2_L6 group0_2_L2 by auto;
ultimately show "c·b¯ = a" "a¯·c = b"
by auto;
qed;
text{*Multiplying different group elements by the same factor results
in different group elements.*}
lemma (in group0) group0_2_L19:
assumes A1: "a∈G" "b∈G" "c∈G" and A2: "a≠b"
shows
"a·c ≠ b·c"
"c·a ≠ c·b"
proof -
{ assume "a·c = b·c ∨ c·a =c·b"
then have "a·c·c¯ = b·c·c¯ ∨ c¯·(c·a) = c¯·(c·b)"
by auto;
with A1 A2 have False using group0_2_L16 by simp;
} then show "a·c ≠ b·c" and "c·a ≠ c·b" by auto;
qed;
section{*Subgroups*}
text{*There are two common ways to define subgroups. One requires that the
group operations are closed in the subgroup. The second one defines subgroup
as a subset of a group which is itself a group under the group operations.
We use the second approach because it results in shorter definition.
We do not
require $H$ to be a subset of $G$ as this can be inferred from our
definition.
The rest of this section is devoted to proving the equivalence of these two
definitions of the notion of a subgroup.
*}
constdefs
"IsAsubgroup(H,f) ≡ IsAgroup(H, restrict(f,H×H))"
text{*Formally the group operation in a subgroup is different than in the
group as they have different domains. Of course we want to use the original
operation with the associated notation in the subgroup. The next couple of
lemmas will allow for that.*}
text{*The neutral element of the subgroup is in the subgroup and it is
both right and left neutral there. The notation is very ugly because
we don't want to introduce a separate notation for the subgroup operation.
*}
lemma group0_3_L1:
assumes A1:"IsAsubgroup(H,f)"
and A2: "n = TheNeutralElement(H,restrict(f,H×H))"
shows "n ∈ H"
"∀h∈H. restrict(f,H×H)`<n,h > = h"
"∀h∈H. restrict(f,H×H)`<h,n > = h"
proof -;
let ?b = "restrict(f,H×H)"
let ?e = "TheNeutralElement(H,restrict(f,H×H))"
from A1 have "group0(H,?b)"
using IsAsubgroup_def group0_def by simp;
then have T1:
"?e ∈ H ∧ (∀h∈H. (?b`<?e,h > = h ∧ ?b`<h,?e > = h))"
by (rule group0.group0_2_L2);
with A2 show "n ∈ H" by simp;
from T1 A2 show "∀h∈H. ?b`<n,h > = h" "∀h∈H. ?b`<h,n> = h"
by auto;
qed;
text{*Subgroup is contained in the group.*}
lemma (in group0) group0_3_L2:
assumes A1:"IsAsubgroup(H,f)"
shows "H⊆G"
proof;
fix h assume A2:"h∈H";
let ?b = "restrict(f,H×H)"
let ?n = "TheNeutralElement(H,restrict(f,H×H))"
from A1 have "?b ∈ H×H->H"
using IsAsubgroup_def IsAgroup_def
IsAmonoid_def IsAssociative_def by simp;
moreover from A2 A1 have "<?n,h> ∈ H×H"
using group0_3_L1 by simp;
moreover from A1 A2 have "h = ?b`<?n,h >"
using group0_3_L1 by simp;
ultimately have "⟨<?n,h>,h⟩ ∈ ?b"
using func1_1_L5A by blast;
then have "⟨<?n,h>,h⟩ ∈ f" using restrict_subset by auto
moreover from groupAssum have "f:G×G->G"
using IsAgroup_def IsAmonoid_def IsAssociative_def
by simp;
ultimately show "h∈G" using func1_1_L5
by blast;
qed;
text{*The group neutral element (denoted $1$ in the group0 context)
is a neutral element for the subgroup with respect to the froup action.*}
lemma (in group0) group0_3_L3:
assumes A1:"IsAsubgroup(H,f)"
shows "∀h∈H. \<one>·h = h ∧ h·\<one> = h"
proof;
fix h assume "h∈H"
with groupAssum A1 show "\<one>·h = h ∧ h·\<one> = h"
using group0_3_L2 group0_2_L2 by auto;
qed;
text{*The neutral element of a subgroup is the same as that of the group.*}
lemma (in group0) group0_3_L4: assumes A1:"IsAsubgroup(H,f)"
shows "TheNeutralElement(H,restrict(f,H×H)) = \<one>"
proof -;
let ?n = "TheNeutralElement(H,restrict(f,H×H))"
from A1 have T1:"?n ∈ H" using group0_3_L1 by simp;
with groupAssum A1 have "?n∈G" using group0_3_L2 by auto;
with A1 T1 show ?thesis using
group0_3_L1 restrict_if group0_2_L7 by simp;
qed;
text{*The neutral element of the group (denoted $1$ in the group0 context)
belongs to every subgroup.*}
lemma (in group0) group0_3_L5: assumes A1: "IsAsubgroup(H,f)"
shows "\<one>∈H"
proof -;
from A1 show "\<one>∈H" using group0_3_L1 group0_3_L4
by fast;
qed;
text{*Subgroups are closed with respect to the group operation.*}
lemma (in group0) group0_3_L6: assumes A1:"IsAsubgroup(H,f)"
and A2:"a∈H" "b∈H"
shows "a·b ∈ H"
proof -;
let ?b = "restrict(f,H×H)"
from A1 have "monoid0(H,?b)" using
IsAsubgroup_def IsAgroup_def monoid0_def by simp;
with A2 have "?b` (<a,b>) ∈ H" using monoid0.group0_1_L1
by blast;
with A2 show "a·b ∈ H" using restrict_if by simp;
qed;
text{*A preliminary lemma that we need to show that taking the inverse
in the subgroup is the same as taking the inverse
in the group.*}
lemma group0_3_L7A:
assumes A1:"IsAgroup(G,f)"
and A2:"IsAsubgroup(H,f)" and A3:"g=restrict(f,H×H)"
shows "GroupInv(G,f) ∩ H×H = GroupInv(H,g)"
proof -
def D1: e ≡ "TheNeutralElement(G,f)"
def D2: e1 ≡ "TheNeutralElement(H,g)"
from A1 have T1:"group0(G,f)" using group0_def by simp;
from A2 A3 have T2:"group0(H,g)"
using IsAsubgroup_def group0_def by simp
from T1 A2 A3 D1 D2 have "e1 = e"
using group0.group0_3_L4 by simp;
with T1 D1 have "GroupInv(G,f) = f-``{e1}"
using group0.group0_2_T3 by simp;
moreover have "g-``{e1} = f-``{e1} ∩ H×H"
proof -;
from A1 have "f ∈ G×G->G"
using IsAgroup_def IsAmonoid_def IsAssociative_def
by simp;
moreover from T1 A2 have "H×H ⊆ G×G"
using group0.group0_3_L2 by auto;
ultimately show "g-``{e1} = f-``{e1} ∩ H×H"
using A3 func1_2_L1 by simp;
qed;
moreover from T2 A3 D2 have "GroupInv(H,g) = g-``{e1}"
using group0.group0_2_T3 by simp;
ultimately show ?thesis by simp;
qed;
text{*Using the lemma above we can show the actual statement:
taking the inverse in the subgroup is the same as taking the inverse
in the group.*}
theorem (in group0) group0_3_T1:
assumes A1: "IsAsubgroup(H,f)"
and A2:"g=restrict(f,H×H)"
shows "GroupInv(H,g) = restrict(GroupInv(G,f),H)"
proof -;
from groupAssum have "GroupInv(G,f) : G->G"
using group0_2_T2 by simp;
moreover from A1 A2 have "GroupInv(H,g) : H->H"
using IsAsubgroup_def group0_2_T2 by simp;
moreover from A1 have "H⊆G"
using group0_3_L2 by simp;
moreover from groupAssum A1 A2 have
"GroupInv(G,f) ∩ H×H = GroupInv(H,g)"
using group0_3_L7A by simp;
ultimately show ?thesis
using func1_2_L3 by simp;
qed;
text{*A sligtly weaker, but more convenient in applications,
reformulation of the above theorem.*}
theorem (in group0) group0_3_T2:
assumes "IsAsubgroup(H,f)"
and "g=restrict(f,H×H)"
shows "∀h∈H. GroupInv(H,g)`(h) = h¯"
using prems group0_3_T1 restrict_if by simp;
text{*Subgroups are closed with respect to taking the group inverse.
Again, I was unable to apply @{text "inverse_in_group"} directly to the group
$H$. This problem is worked around by repeating the (short) proof of
@{text "inverse_in_group"} in the proof below.*}
theorem (in group0) group0_3_T3A:
assumes A1:"IsAsubgroup(H,f)" and A2:"h∈H"
shows "h¯∈ H"
proof -
def D1: g ≡ "restrict(f,H×H)";
with A1 have "GroupInv(H,g) ∈ H->H"
using IsAsubgroup_def group0_2_T2 by simp;
with A2 have "GroupInv(H,g)`(h) ∈ H"
using apply_type by simp;
with A1 D1 A2 show "h¯∈ H" using group0_3_T2 by simp;
qed;
text{*The next theorem states that a nonempty subset of
of a group $G$ that is closed under the group operation and
taking the inverse is a subgroup of the group.*}
theorem (in group0) group0_3_T3:
assumes A1: "H≠0"
and A2: "H⊆G"
and A3: "H {is closed under} f"
and A4: "∀x∈H. x¯ ∈ H"
shows "IsAsubgroup(H,f)"
proof -;
let ?g = "restrict(f,H×H)"
let ?n = "TheNeutralElement(H,?g)"
from A3 have T0:"∀x∈H.∀y∈H. x·y ∈ H"
using IsOpClosed_def by simp;
from A1 obtain x where "x∈H" by auto;
with A4 T0 A2 have T1:"\<one>∈H"
using group0_2_L6 by blast;
with A3 A2 have T2:"IsAmonoid(H,?g)"
using group0_2_L1 monoid0.group0_1_T1
by simp;
moreover have "∀h∈H.∃b∈H. ?g`<h,b> = ?n"
proof;
fix h assume A5:"h∈H"
with A4 A2 have "h·h¯ = \<one>"
using group0_2_L6 by auto;
moreover from groupAssum A3 A2 T1 have "\<one> = ?n"
using IsAgroup_def group0_1_L6 by auto;
moreover from A5 A4 have "?g`<h,h¯> = h·h¯"
using restrict_if by simp;
ultimately have "?g`<h,h¯> = ?n" by simp;
with A5 A4 show "∃b∈H. ?g`<h,b> = ?n" by auto;
qed;
ultimately show "IsAsubgroup(H,f)" using
IsAsubgroup_def IsAgroup_def by simp;
qed;
text{*Intersection of subgroups is a subgroup of each factor.*}
lemma group0_3_L7:
assumes A1:"IsAgroup(G,f)"
and A2:"IsAsubgroup(H1,f)"
and A3:"IsAsubgroup(H2,f)"
shows "IsAsubgroup(H1∩H2,restrict(f,H1×H1))"
proof -;
let ?e = "TheNeutralElement(G,f)"
let ?g = "restrict(f,H1×H1)"
from A1 have T1: "group0(G,f)"
using group0_def by simp;
from A2 have "group0(H1,?g)"
using IsAsubgroup_def group0_def by simp;
moreover have "H1∩H2 ≠ 0"
proof -
from A1 A2 A3 have "?e ∈ H1∩H2"
using group0_def group0.group0_3_L5 by simp;
thus ?thesis by auto;
qed;
moreover have T2:"H1∩H2 ⊆ H1" by auto;
moreover from T1 T2 A2 A3 have
"H1∩H2 {is closed under} ?g"
using group0.group0_3_L6 IsOpClosed_def
func_ZF_4_L7 func_ZF_4_L5 by simp;
moreover from T1 A2 A3 have
"∀x ∈ H1∩H2. GroupInv(H1,?g)`(x) ∈ H1∩H2"
using group0.group0_3_T2 group0.group0_3_T3A
by simp;
ultimately show ?thesis
using group0.group0_3_T3 by simp;
qed;
section{*Abelian groups*}
text{*Here we will prove some facts specific to abelian groups. *}
text{*Proving the facts about associative and commutative operations is
quite tedious in formalized mathematics. To a human the thing is simple:
we can arrange the elements in any order and put parantheses wherever we
want, it is all the same. However, formalizing this statement would be
rather difficult (I think). The next lemma attempts a quasi-algorithmic
approach to this type of problem. To prove that two expressions are equal,
we first strip one from parantheses, then rearrange the elements in proper
order, then put the parantheses where we want them to be. The algorithm for
rearrangement is easy to describe: we keep putting the first element
(from the right) that is in the wrong place at the left-most position
until we get the proper arrangement. For the parantheses simp does it
very well.*}
lemma (in group0) group0_4_L2:
assumes A1:"f {is commutative on} G"
and A2:"a∈G" "b∈G" "c∈G" "d∈G" "E∈G" "F∈G"
shows "(a·b)·(c·d)·(E·F) = (a·(d·F))·(b·(c·E))"
proof -;
from A2 have "(a·b)·(c·d)·(E·F) = a·b·c·d·E·F"
using group_op_closed group_oper_assoc
by simp;
also have "a·b·c·d·E·F = a·d·F·b·c·E"
proof -
from A1 A2 have "a·b·c·d·E·F = F·(a·b·c·d·E)"
using IsCommutative_def group_op_closed
by simp;
also from A2 have "F·(a·b·c·d·E) = F·a·b·c·d·E"
using group_op_closed group_oper_assoc
by simp;
also from A1 A2 have "F·a·b·c·d·E = d·(F·a·b·c)·E"
using IsCommutative_def group_op_closed
by simp;
also from A2 have "d·(F·a·b·c)·E = d·F·a·b·c·E"
using group_op_closed group_oper_assoc
by simp;
also from A1 A2 have " d·F·a·b·c·E = a·(d·F)·b·c·E"
using IsCommutative_def group_op_closed
by simp;
also from A2 have "a·(d·F)·b·c·E = a·d·F·b·c·E"
using group_op_closed group_oper_assoc
by simp;
finally show ?thesis by simp;
qed;
also from A2 have "a·d·F·b·c·E = (a·(d·F))·(b·(c·E))"
using group_op_closed group_oper_assoc
by simp;
finally show ?thesis by simp;
qed;
text{*Another useful rearrangement.*}
lemma (in group0) group0_4_L3:
assumes A1:"f {is commutative on} G"
and A2: "a∈G" "b∈G" and A3: "c∈G" "d∈G" "E∈G" "F∈G"
shows "a·b·((c·d)¯·(E·F)¯) = (a·(E·c)¯)·(b·(F·d)¯)"
proof -;
from A3 have T1:
"c¯∈G" "d¯∈G" "E¯∈G" "F¯∈G" "(c·d)¯∈G" "(E·F)¯∈G"
using inverse_in_group group_op_closed
by auto;
from A2 T1 have
"a·b·((c·d)¯·(E·F)¯) = a·b·(c·d)¯·(E·F)¯"
using group_op_closed group_oper_assoc
by simp;
also from A2 A3 have
"a·b·(c·d)¯·(E·F)¯ = (a·b)·(d¯·c¯)·(F¯·E¯)"
using group_inv_of_two by simp;
also from A1 A2 T1 have
"(a·b)·(d¯·c¯)·(F¯·E¯) = (a·(c¯·E¯))·(b·(d¯·F¯))"
using group0_4_L2 by simp;
also from A2 A3 have
"(a·(c¯·E¯))·(b·(d¯·F¯)) = (a·(E·c)¯)·(b·(F·d)¯)"
using group_inv_of_two by simp;
finally show ?thesis by simp;
qed;
text{*Some useful rearrangements for two elements of a group.*}
lemma (in group0) group0_4_L4:
assumes A1:"f {is commutative on} G"
and A2: "a∈G" "b∈G"
shows
"b¯·a¯ = a¯·b¯"
"(a·b)¯ = a¯·b¯"
"(a·b¯)¯ = a¯·b"
proof -;
from A2 have T1: "b¯∈G" "a¯∈G" using inverse_in_group by auto;
with A1 show "b¯·a¯ = a¯·b¯" using IsCommutative_def by simp;
with A2 show "(a·b)¯ = a¯·b¯" using group_inv_of_two by simp;
from A2 T1 have "(a·b¯)¯ = (b¯)¯·a¯" using group_inv_of_two by simp;
with A1 A2 T1 show "(a·b¯)¯ = a¯·b"
using group_inv_of_inv IsCommutative_def by simp;
qed;
text{*Another bunch of useful rearrangements with three elements.*}
lemma (in group0) group0_4_L4A:
assumes A1:"f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
shows
"a·b·c = c·a·b"
"a¯·(b¯·c¯)¯ = (a·(b·c)¯)¯"
"a·(b·c)¯ = a·b¯·c¯"
"a·(b·c¯)¯ = a·b¯·c"
"a·b¯·c¯ = a·c¯·b¯"
proof -
from A1 A2 have "a·b·c = c·(a·b)"
using IsCommutative_def group_op_closed
by simp;
with A2 show "a·b·c = c·a·b" using
group_op_closed group_oper_assoc
by simp
from A2 have T:
"b¯∈G" "c¯∈G" "b¯·c¯ ∈ G" "a·b ∈ G"
using inverse_in_group group_op_closed
by auto;
with A1 A2 show "a¯·(b¯·c¯)¯ = (a·(b·c)¯)¯"
using group_inv_of_two IsCommutative_def
by simp;
from A1 A2 T have "a·(b·c)¯ = a·(b¯·c¯)"
using group_inv_of_two IsCommutative_def by simp;
with A2 T show "a·(b·c)¯ = a·b¯·c¯"
using group_oper_assoc by simp;
from A1 A2 T have "a·(b·c¯)¯ = a·(b¯·(c¯)¯)"
using group_inv_of_two IsCommutative_def by simp;
with A2 T show "a·(b·c¯)¯ = a·b¯·c"
using group_oper_assoc group_inv_of_inv by simp;
from A1 A2 T have "a·b¯·c¯ = a·(c¯·b¯)"
using group_oper_assoc IsCommutative_def by simp;
with A2 T show "a·b¯·c¯ = a·c¯·b¯"
using group_oper_assoc by simp
qed;
text{*Another useful rearrangement.*}
lemma (in group0) group0_4_L4B:
assumes "f {is commutative on} G"
and "a∈G" "b∈G" "c∈G"
shows "a·b¯·(b·c¯) = a·c¯"
using prems inverse_in_group group_op_closed
group0_4_L4 group_oper_assoc group0_2_L16 by simp;
text{*A couple of permutations of order for three alements.*}
lemma (in group0) group0_4_L4C:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
shows
"a·b·c = c·a·b"
"a·b·c = a·(c·b)"
"a·b·c = c·(a·b)"
"a·b·c = c·b·a"
proof -
from A1 A2 show I: "a·b·c = c·a·b"
using group0_4_L4A by simp
also from A1 A2 have "c·a·b = a·c·b"
using IsCommutative_def by simp;
also from A2 have "a·c·b = a·(c·b)"
using group_oper_assoc by simp;
finally show "a·b·c = a·(c·b)" by simp;
from A2 I show "a·b·c = c·(a·b)"
using group_oper_assoc by simp;
also from A1 A2 have "c·(a·b) = c·(b·a)"
using IsCommutative_def by simp;
also from A2 have "c·(b·a) = c·b·a"
using group_oper_assoc by simp;
finally show "a·b·c = c·b·a" by simp;
qed;
text{*Some rearangement with three elements and inverse.*}
lemma (in group0) group0_4_L4D:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
shows
"a¯·b¯·c = c·a¯·b¯"
"b¯·a¯·c = c·a¯·b¯"
"(a¯·b·c)¯ = a·b¯·c¯"
proof -
from A2 have T:
"a¯ ∈ G" "b¯ ∈ G" "c¯∈G"
using inverse_in_group by auto;
with A1 A2 show
"a¯·b¯·c = c·a¯·b¯"
"b¯·a¯·c = c·a¯·b¯"
using group0_4_L4A by auto
from A1 A2 T show "(a¯·b·c)¯ = a·b¯·c¯"
using group_inv_of_three group_inv_of_inv group0_4_L4C
by simp;
qed;
text{*Another rearrangement lemma with three elements and equation.*}
lemma (in group0) group0_4_L5: assumes A1:"f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
and A3: "c = a·b¯"
shows "a = b·c"
proof -;
from A2 A3 have "c·(b¯)¯ = a"
using inverse_in_group group0_2_L18
by simp;
with A1 A2 show ?thesis using
group_inv_of_inv IsCommutative_def by simp;
qed;
text{*In abelian groups we can cancel an element with its inverse
even if separated by another element.*}
lemma (in group0) group0_4_L6A: assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G"
shows
"a·b·a¯ = b"
"a¯·b·a = b"
"a¯·(b·a) = b"
"a·(b·a¯) = b"
proof -;
from A1 A2 have
"a·b·a¯ = a¯·a·b"
using inverse_in_group group0_4_L4A by blast
also from A2 have "… = b"
using group0_2_L6 group0_2_L2 by simp;
finally show "a·b·a¯ = b" by simp;
from A1 A2 have
"a¯·b·a = a·a¯·b"
using inverse_in_group group0_4_L4A by blast;
also from A2 have "… = b"
using group0_2_L6 group0_2_L2 by simp;
finally show "a¯·b·a = b" by simp
moreover from A2 have "a¯·b·a = a¯·(b·a)"
using inverse_in_group group_oper_assoc by simp;
ultimately show "a¯·(b·a) = b" by simp;
from A1 A2 show "a·(b·a¯) = b"
using inverse_in_group IsCommutative_def group0_2_L16
by simp;
qed;
text{*Another lemma about cancelling with two elements.*}
lemma (in group0) group0_4_L6AA:
assumes A1: "f {is commutative on} G" and A2: "a∈G" "b∈G"
shows
"a·b¯·a¯ = b¯"
using prems inverse_in_group group0_4_L6A
by auto;
text{*Another lemma about cancelling with two elements.*}
lemma (in group0) group0_4_L6AB:
assumes A1: "f {is commutative on} G" and A2: "a∈G" "b∈G"
shows
"a·(a·b)¯ = b¯"
"a·(b·a¯) = b"
proof -
from A2 have "a·(a·b)¯ = a·(b¯·a¯)"
using group_inv_of_two by simp
also from A2 have "… = a·b¯·a¯"
using inverse_in_group group_oper_assoc by simp;
also from A1 A2 have "… = b¯"
using group0_4_L6AA by simp;
finally show "a·(a·b)¯ = b¯" by simp;
from A1 A2 have "a·(b·a¯) = a·(a¯·b)"
using inverse_in_group IsCommutative_def by simp;
also from A2 have "… = b"
using inverse_in_group group_oper_assoc group0_2_L6 group0_2_L2
by simp;
finally show "a·(b·a¯) = b" by simp;
qed;
text{*Another lemma about cancelling with two elements.*}
lemma (in group0) group0_4_L6AC:
assumes "f {is commutative on} G" and "a∈G" "b∈G"
shows "a·(a·b¯)¯ = b"
using prems inverse_in_group group0_4_L6AB group_inv_of_inv
by simp;
text{*In abelian groups we can cancel an element with its inverse
even if separated by two other elements.*}
lemma (in group0) group0_4_L6B: assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
shows
"a·b·c·a¯ = b·c"
"a¯·b·c·a = b·c"
proof -
from A2 have
"a·b·c·a¯ = a·(b·c)·a¯"
"a¯·b·c·a = a¯·(b·c)·a"
using group_op_closed group_oper_assoc inverse_in_group
by auto;
with A1 A2 show
"a·b·c·a¯ = b·c"
"a¯·b·c·a = b·c"
using group_op_closed group0_4_L6A
by auto;
qed;
text{*In abelian groups we can cancel an element with its inverse
even if separated by three other elements.*}
lemma (in group0) group0_4_L6C: assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
shows "a·b·c·d·a¯ = b·c·d"
proof -
from A2 have "a·b·c·d·a¯ = a·(b·c·d)·a¯"
using group_op_closed group_oper_assoc
by simp;
with A1 A2 show ?thesis
using group_op_closed group0_4_L6A
by simp;
qed;
text{*Another couple of useful rearrangements of three elements
and cancelling.*}
lemma (in group0) group0_4_L6D:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
shows
"a·b¯·(a·c¯)¯ = c·b¯"
"(a·c)¯·(b·c) = a¯·b"
"a·(b·(c·a¯·b¯)) = c"
"a·b·c¯·(c·a¯) = b"
proof -
from A2 have T:
"a¯ ∈ G" "b¯ ∈ G" "c¯ ∈ G"
"a·b ∈ G" "a·b¯ ∈ G" "c¯·a¯ ∈ G" "c·a¯ ∈ G"
using inverse_in_group group_op_closed by auto;
with A1 A2 show "a·b¯·(a·c¯)¯ = c·b¯"
using group0_2_L12 group_oper_assoc group0_4_L6B
IsCommutative_def by simp;
from A2 T have "(a·c)¯·(b·c) = c¯·a¯·b·c"
using group_inv_of_two group_oper_assoc by simp;
also from A1 A2 T have "… = a¯·b"
using group0_4_L6B by simp;
finally show "(a·c)¯·(b·c) = a¯·b"
by simp;
from A1 A2 T show "a·(b·(c·a¯·b¯)) = c"
using group_oper_assoc group0_4_L6B group0_4_L6A
by simp;
from T have "a·b·c¯·(c·a¯) = a·b·(c¯·(c·a¯))"
using group_oper_assoc by simp;
also from A1 A2 T have "… = b"
using group_oper_assoc group0_2_L6 group0_2_L2 group0_4_L6A
by simp;
finally show "a·b·c¯·(c·a¯) = b" by simp;
qed;
text{*Another useful rearrangement of three elements
and cancelling.*}
lemma (in group0) group0_4_L6E:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G"
shows
"a·b·(a·c)¯ = b·c¯"
proof -
from A2 have T: "b¯ ∈ G" "c¯ ∈ G"
using inverse_in_group by auto;
with A1 A2 have
"a·(b¯)¯·(a·(c¯)¯)¯ = c¯·(b¯)¯"
using group0_4_L6D by simp;
with A1 A2 T show "a·b·(a·c)¯ = b·c¯"
using group_inv_of_inv IsCommutative_def
by simp;
qed;
text{*A rearrangement with two elements and canceelling,
special case of @{text "group0_4_L6D"} when $c=b^{-1}$.*}
lemma (in group0) group0_4_L6F:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G"
shows "a·b¯·(a·b)¯ = b¯·b¯"
proof -
from A2 have "b¯ ∈ G"
using inverse_in_group by simp
with A1 A2 have "a·b¯·(a·(b¯)¯)¯ = b¯·b¯"
using group0_4_L6D by simp;
with A2 show "a·b¯·(a·b)¯ = b¯·b¯"
using group_inv_of_inv by simp;
qed;
text{*Some other rearrangements with four elements.
The algorithm for proof as in @{text "group0_4_L2"}
works very well here.*}
lemma (in group0) rearr_ab_gr_4_elemA:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
shows
"a·b·c·d = a·d·b·c"
"a·b·c·d = a·c·(b·d)"
proof -
from A1 A2 have "a·b·c·d = d·(a·b·c)"
using IsCommutative_def group_op_closed
by simp;
also from A2 have "… = d·a·b·c"
using group_op_closed group_oper_assoc
by simp;
also from A1 A2 have "… = a·d·b·c"
using IsCommutative_def group_op_closed
by simp;
finally show "a·b·c·d = a·d·b·c"
by simp;
from A1 A2 have "a·b·c·d = c·(a·b)·d"
using IsCommutative_def group_op_closed
by simp
also from A2 have "… = c·a·b·d"
using group_op_closed group_oper_assoc
by simp
also from A1 A2 have "… = a·c·b·d"
using IsCommutative_def group_op_closed
by simp
also from A2 have "… = a·c·(b·d)"
using group_op_closed group_oper_assoc
by simp
finally show "a·b·c·d = a·c·(b·d)"
by simp
qed;
text{*Some rearrangements with four elements and inverse
that are applications of @{text "rearr_ab_gr_4_elem"}
*}
lemma (in group0) rearr_ab_gr_4_elemB:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
shows
"a·b¯·c¯·d¯ = a·d¯·b¯·c¯"
"a·b·c·d¯ = a·d¯·b·c"
"a·b·c¯·d¯ = a·c¯·(b·d¯)"
proof -
from A2 have T: "b¯ ∈ G" "c¯ ∈ G" "d¯ ∈ G"
using inverse_in_group by auto;
with A1 A2 show
"a·b¯·c¯·d¯ = a·d¯·b¯·c¯"
"a·b·c·d¯ = a·d¯·b·c"
"a·b·c¯·d¯ = a·c¯·(b·d¯)"
using rearr_ab_gr_4_elemA by auto;
qed;
text{*Some rearrangement lemmas with four elements.*}
lemma (in group0) group0_4_L7:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
shows
"a·b·c·d¯ = a·d¯· b·c"
"a·d·(b·d·(c·d))¯ = a·(b·c)¯·d¯"
"a·(b·c)·d = a·b·d·c"
proof -
from A2 have T:
"b·c ∈ G" "d¯ ∈ G" "b¯∈G" "c¯∈G"
"d¯·b ∈ G" "c¯·d ∈ G" "(b·c)¯ ∈ G"
"b·d ∈ G" "b·d·c ∈ G" "(b·d·c)¯ ∈ G"
"a·d ∈ G" "b·c ∈ G"
using group_op_closed inverse_in_group
by auto;
with A1 A2 have "a·b·c·d¯ = a·(d¯·b·c)"
using group_oper_assoc group0_4_L4A by simp;
also from A2 T have "a·(d¯·b·c) = a·d¯·b·c"
using group_oper_assoc by simp;
finally show "a·b·c·d¯ = a·d¯· b·c" by simp;
from A2 T have "a·d·(b·d·(c·d))¯ = a·d·(d¯·(b·d·c)¯)"
using group_oper_assoc group_inv_of_two by simp;
also from A2 T have "… = a·(b·d·c)¯"
using group_oper_assoc group0_2_L16 by simp;
also from A1 A2 have "… = a·(d·(b·c))¯"
using IsCommutative_def group_oper_assoc by simp;
also from A2 T have "… = a·((b·c)¯·d¯)"
using group_inv_of_two by simp;
also from A2 T have "… = a·(b·c)¯·d¯"
using group_oper_assoc by simp;
finally show "a·d·(b·d·(c·d))¯ = a·(b·c)¯·d¯"
by simp;
from A2 have "a·(b·c)·d = a·(b·(c·d))"
using group_op_closed group_oper_assoc by simp;
also from A1 A2 have "… = a·(b·(d·c))"
using IsCommutative_def group_op_closed by simp;
also from A2 have "… = a·b·d·c"
using group_op_closed group_oper_assoc by simp;
finally show "a·(b·c)·d = a·b·d·c" by simp;
qed;
text{*Some other rearrangements with four elements.*}
lemma (in group0) group0_4_L8:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
shows
"a·(b·c)¯ = (a·d¯·c¯)·(d·b¯)"
"a·b·(c·d) = c·a·(b·d)"
"a·b·(c·d) = a·c·(b·d)"
"a·(b·c¯)·d = a·b·d·c¯"
"(a·b)·(c·d)¯·(b·d¯)¯ = a·c¯"
proof -
from A2 have T:
"b·c ∈ G" "a·b ∈ G" "d¯ ∈ G" "b¯∈G" "c¯∈G"
"d¯·b ∈ G" "c¯·d ∈ G" "(b·c)¯ ∈ G"
"a·b ∈ G" "(c·d)¯ ∈ G" "(b·d¯)¯ ∈ G" "d·b¯ ∈ G"
using group_op_closed inverse_in_group
by auto;
from A2 have "a·(b·c)¯ = a·c¯·b¯" using group0_2_L14A by blast;
moreover from A2 have "a·c¯ = (a·d¯)·(d·c¯)" using group0_2_L14A
by blast;
ultimately have "a·(b·c)¯ = (a·d¯)·(d·c¯)·b¯" by simp;
with A1 A2 T have "a·(b·c)¯= a·d¯·(c¯·d)·b¯"
using IsCommutative_def by simp;
with A2 T show "a·(b·c)¯ = (a·d¯·c¯)·(d·b¯)"
using group_op_closed group_oper_assoc by simp;
from A2 T have "a·b·(c·d) = a·b·c·d"
using group_oper_assoc by simp;
also have "a·b·c·d = c·a·b·d"
proof -;
from A1 A2 have "a·b·c·d = c·(a·b)·d"
using IsCommutative_def group_op_closed
by simp;
also from A2 have "… = c·a·b·d"
using group_op_closed group_oper_assoc
by simp;
finally show ?thesis by simp;
qed;
also from A2 have "c·a·b·d = c·a·(b·d)"
using group_op_closed group_oper_assoc
by simp;
finally show "a·b·(c·d) = c·a·(b·d)" by simp;
with A1 A2 show "a·b·(c·d) = a·c·(b·d)"
using IsCommutative_def by simp
from A1 A2 T show "a·(b·c¯)·d = a·b·d·c¯"
using group0_4_L7 by simp;
from T have "(a·b)·(c·d)¯·(b·d¯)¯ = (a·b)·((c·d)¯·(b·d¯)¯)"
using group_oper_assoc by simp;
also from A1 A2 T have "… = (a·b)·(c¯·d¯·(d·b¯))"
using group_inv_of_two group0_2_L12 IsCommutative_def
by simp;
also from T have "… = (a·b)·(c¯·(d¯·(d·b¯)))"
using group_oper_assoc by simp;
also from A1 A2 T have "… = a·c¯"
using group_oper_assoc group0_2_L6 group0_2_L2 IsCommutative_def
group0_2_L16 by simp;
finally show "(a·b)·(c·d)¯·(b·d¯)¯ = a·c¯"
by simp;
qed;
text{*Some other rearrangements with four elements.*}
lemma (in group0) group0_4_L8A:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
shows
"a·b¯·(c·d¯) = a·c·(b¯·d¯)"
"a·b¯·(c·d¯) = a·c·b¯·d¯"
proof -
from A2 have
T: "a∈G" "b¯ ∈ G" "c∈G" "d¯ ∈ G"
using inverse_in_group by auto
with A1 show "a·b¯·(c·d¯) = a·c·(b¯·d¯)"
by (rule group0_4_L8);
with A2 T show "a·b¯·(c·d¯) = a·c·b¯·d¯"
using group_op_closed group_oper_assoc
by simp;
qed;
text{*Another rearrangement about equation.*}
lemma (in group0) group0_4_L9:
assumes A1: "f {is commutative on} G"
and A2: "a∈G" "b∈G" "c∈G" "d∈G"
and A3: "a = b·c¯·d¯"
shows
"d = b·a¯·c¯"
"d = a¯·b·c¯"
"b = a·d·c"
proof -
from A2 have T:
"a¯ ∈ G" "c¯ ∈ G" "d¯ ∈ G" "b·c¯ ∈ G"
using group_op_closed inverse_in_group
by auto
with A2 A3 have "a·(d¯)¯ = b·c¯"
using group0_2_L18 by simp;
with A2 have "b·c¯ = a·d"
using group_inv_of_inv by simp;
with A2 T have I: "a¯·(b·c¯) = d"
using group0_2_L18 by simp;
with A1 A2 T show
"d = b·a¯·c¯"
"d = a¯·b·c¯"
using group_oper_assoc IsCommutative_def by auto;
from A3 have "a·d·c = (b·c¯·d¯)·d·c" by simp;
also from A2 T have "… = b·c¯·(d¯·d)·c"
using group_oper_assoc by simp;
also from A2 T have "… = b·c¯·c"
using group0_2_L6 group0_2_L2 by simp;
also from A2 T have "… = b·(c¯·c)"
using group_oper_assoc by simp;
also from A2 have "… = b"
using group0_2_L6 group0_2_L2 by simp
finally have "a·d·c = b" by simp;
thus "b = a·d·c" by simp;
qed;
section{*Translations*}
text{*In this section we consider translations. Translations are maps
$T: G\rightarrow G$ of the form $T_g (a) = g\cdot a$ or
$T_g (a) = a\cdot g$. We also consider two-dimensional translations
$T_g : G\times G \rightarrow G\times G$, where
$T_g(a,b) = (a\cdot g, b\cdot g)$ or$T_g(a,b) = (g\cdot a, g\cdot b)$.
*}
constdefs
"RightTranslation(G,P,g) ≡ {<a,b> ∈ G×G. P`<a,g> = b}"
"LeftTranslation(G,P,g) ≡ {<a,b> ∈ G×G. P`<g,a> = b}"
"RightTranslation2(G,P,g) ≡
{<x,y> ∈ (G×G)×(G×G). ⟨P`<fst(x),g>, P`<snd(x),g>⟩ = y}"
"LeftTranslation2(G,P,g) ≡
{<x,y> ∈ (G×G)×(G×G). ⟨P`<g,fst(x)>, P`<g,snd(x)>⟩ = y}"
text{*Translations map $G$ into $G$. Two dimensional translations map
$G\times G$ into itself.*}
lemma (in group0) group0_5_L1: assumes A1: "g∈G"
shows "RightTranslation(G,f,g) : G->G"
"LeftTranslation(G,f,g) : G->G"
"RightTranslation2(G,f,g) : (G×G)->(G×G)"
"LeftTranslation2(G,f,g) : (G×G)->(G×G)"
proof -
from A1 have "∀a∈G. a·g ∈ G" "∀a∈G. g·a ∈ G"
"∀x ∈ G×G. <fst(x)·g, snd(x)·g> ∈ G×G"
"∀x ∈ G×G. <g·fst(x),g·snd(x)> ∈ G×G"
using group_oper_assocA apply_funtype by auto;
then show "RightTranslation(G,f,g) : G->G"
"LeftTranslation(G,f,g) : G->G"
"RightTranslation2(G,f,g) : (G×G)->(G×G)"
"LeftTranslation2(G,f,g) : (G×G)->(G×G)"
using RightTranslation_def LeftTranslation_def
RightTranslation2_def LeftTranslation2_def func1_1_L11A
by auto;
qed;
text{*The values of the translations are what we expect.*}
lemma (in group0) group0_5_L2: assumes A1: "g∈G" "a∈G"
shows
"RightTranslation(G,f,g)`(a) = a·g"
"LeftTranslation(G,f,g)`(a) = g·a"
using prems group0_5_L1 RightTranslation_def LeftTranslation_def
func1_1_L11B by auto;
text{*The values of the two-dimensional translations are what we expect.*}
lemma (in group0) group0_5_L3: assumes A1: "g∈G" "a∈G" "b∈G"
shows "RightTranslation2(G,f,g)`<a,b> = <a·g,b·g>"
"LeftTranslation2(G,f,g)`<a,b> = <g·a,g·b>"
using prems RightTranslation2_def LeftTranslation2_def
group0_5_L1 func1_1_L11B by auto;
text{*Composition of left translations is a left translation by the product.*}
lemma (in group0) group0_5_L4: assumes A1:"g∈G" "h∈G" "a∈G"
and A2: "Tg = LeftTranslation(G,f,g)" "Th = LeftTranslation(G,f,h)"
shows "Tg`(Th`(a)) = g·h·a"
"Tg`(Th`(a)) = LeftTranslation(G,f,g·h)`(a)"
proof -;
from A1 have T1:"h·a∈G" "g·h∈G"
using group_oper_assocA apply_funtype by auto;
with A1 A2 show "Tg`(Th`(a)) = g·h·a"
using group0_5_L2 group_oper_assoc by simp;
with A1 A2 T1 show
"Tg`(Th`(a)) = LeftTranslation(G,f,g·h)`(a)"
using group0_5_L2 group_oper_assoc by simp;
qed;
text{*Composition of right translations is a right translation by
the product.*}
lemma (in group0) group0_5_L5: assumes A1:"g∈G" "h∈G" "a∈G"
and A2: "Tg = RightTranslation(G,f,g)" "Th = RightTranslation(G,f,h)"
shows "Tg`(Th`(a)) = a·h·g"
"Tg`(Th`(a)) = RightTranslation(G,f,h·g)`(a)"
proof -
from A1 have T1: "a·h∈G" "h·g ∈G"
using group_oper_assocA apply_funtype by auto;
with A1 A2 show "Tg`(Th`(a)) = a·h·g"
using group0_5_L2 group_oper_assoc by simp;
with A1 A2 T1 show
"Tg`(Th`(a)) = RightTranslation(G,f,h·g)`(a)"
using group0_5_L2 group_oper_assoc by simp;
qed;
text{*The image of a set under a composition of translations is the same as
the image under translation by a product.*}
lemma (in group0) group0_5_L6: assumes A1: "g∈G" "h∈G" and A2: "A⊆G"
and A3: "Tg = RightTranslation(G,f,g)" "Th = RightTranslation(G,f,h)"
shows "Tg``(Th``(A)) = {a·h·g. a∈A}"
proof -;
from A2 have T1:"∀a∈A. a∈G" by auto;
from A1 A3 have "Tg : G->G" "Th : G->G"
using group0_5_L1 by auto;
with A1 A2 T1 A3 show "Tg``(Th``(A)) = {a·h·g. a∈A}"
using func1_1_L15C group0_5_L5 by simp;
qed;
section{*Odd functions*}
text{*This section is about odd functions.*}
text{*Odd functions are those that commute with the group inverse:
$f(a^{-1}) = (f(a))^{-1}.$*}
constdefs
"IsOdd(G,P,f) ≡ (∀a∈G. f`(GroupInv(G,P)`(a)) = GroupInv(G,P)`(f`(a)) )"
text{*Let's see the definition of an odd function in a more readable
notation.*}
lemma (in group0) group0_6_L1:
shows "IsOdd(G,f,p) <-> (∀a∈G. p`(a¯) = (p`(a))¯)"
using IsOdd_def by simp;
text{*We can express the definition of an odd function in two ways.*}
lemma (in group0) group0_6_L2:
assumes A1: "p : G->G" shows
"(∀a∈G. p`(a¯) = (p`(a))¯) <-> (∀a∈G. (p`(a¯))¯ = p`(a))"
proof
assume "∀a∈G. p`(a¯) = (p`(a))¯"
with A1 show "∀a∈G. (p`(a¯))¯ = p`(a)"
using apply_funtype group_inv_of_inv by simp;
next assume A2: "∀a∈G. (p`(a¯))¯ = p`(a)"
{ fix a assume "a∈G"
with A1 A2 have "p`(a¯) ∈ G" "((p`(a¯))¯)¯ = (p`(a))¯"
using apply_funtype inverse_in_group by auto;
then have "p`(a¯) = (p`(a))¯"
using group_inv_of_inv by simp;
} then show "∀a∈G. p`(a¯) = (p`(a))¯" by simp;
qed;
end
lemma group0_1_L1:
[| monoid0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨a, b⟩ ∈ G
lemma group0_1_L2:
monoid0(G, f) ==> ∃!e. e ∈ G ∧ (∀g∈G. f ` ⟨e, g⟩ = g ∧ f ` ⟨g, e⟩ = g)
lemma group0_1_L3:
[| monoid0(G, f); e = TheNeutralElement(G, f) |] ==> e ∈ G ∧ (∀g∈G. f ` ⟨e, g⟩ = g ∧ f ` ⟨g, e⟩ = g)
lemma group0_1_L3A:
monoid0(G, f) ==> G ≠ 0
lemma group0_1_L3B:
monoid0(G, f) ==> range(f) = G
lemma group0_1_L4:
[| monoid0(G, f); e ∈ G ∧ (∀g∈G. f ` ⟨e, g⟩ = g ∧ f ` ⟨g, e⟩ = g) |] ==> e = TheNeutralElement(G, f)
lemma group0_1_L5:
[| monoid0(G, f); ∀x∈H. ∀y∈H. f ` ⟨x, y⟩ ∈ H; H ⊆ G; e = TheNeutralElement(G, f); g = restrict(f, H × H); e ∈ H; h ∈ H |] ==> g ` ⟨e, h⟩ = h ∧ g ` ⟨h, e⟩ = h
theorem group0_1_T1:
[| monoid0(G, f); H {is closed under} f; H ⊆ G; TheNeutralElement(G, f) ∈ H |] ==> IsAmonoid(H, restrict(f, H × H))
lemma group0_1_L6:
[| IsAmonoid(G, f); H {is closed under} f; H ⊆ G; TheNeutralElement(G, f) ∈ H |] ==> TheNeutralElement(H, restrict(f, H × H)) = TheNeutralElement(G, f)
lemma group0_2_L1:
group0(G, f) ==> monoid0(G, f)
lemma definition_of_group:
[| IsAmonoid(G, f); ∀g∈G. ∃b∈G. f ` ⟨g, b⟩ = TheNeutralElement(G, f) |] ==> IsAgroup(G, f)
lemma group0_2_L2:
group0(G, f) ==> TheNeutralElement(G, f) ∈ G ∧ (∀g∈G. f ` ⟨TheNeutralElement(G, f), g⟩ = g ∧ f ` ⟨g, TheNeutralElement(G, f)⟩ = g)
lemma group_op_closed:
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨a, b⟩ ∈ G
lemma group_oper_assoc:
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, f ` ⟨b, c⟩⟩ = f ` ⟨f ` ⟨a, b⟩, c⟩
lemma group_oper_assocA:
group0(G, f) ==> f ∈ G × G -> G
theorem group0_2_T1:
[| group0(G, f); g ∈ G; b ∈ G; f ` ⟨g, b⟩ = TheNeutralElement(G, f) |] ==> f ` ⟨b, g⟩ = TheNeutralElement(G, f)
lemma group0_2_L4:
[| group0(G, f); x ∈ G |] ==> ∃!y. y ∈ G ∧ f ` ⟨x, y⟩ = TheNeutralElement(G, f)
theorem group0_2_T2:
IsAgroup(G, f) ==> GroupInv(G, f) ∈ G -> G
theorem group0_2_T3:
group0(G, f) ==> f -`` {TheNeutralElement(G, f)} = GroupInv(G, f)
lemma inverse_in_group:
[| group0(G, f); x ∈ G |] ==> GroupInv(G, f) ` x ∈ G
lemma group0_2_L6:
[| group0(G, f); x ∈ G |] ==> f ` ⟨x, GroupInv(G, f) ` x⟩ = TheNeutralElement(G, f) ∧ f ` ⟨GroupInv(G, f) ` x, x⟩ = TheNeutralElement(G, f)
lemma group0_2_L7:
[| group0(G, f); a ∈ G; b ∈ G; f ` ⟨a, b⟩ = a |] ==> b = TheNeutralElement(G, f)
lemma group0_2_L8:
[| group0(G, f); a ∈ G; b ∈ G; f ` ⟨a, b⟩ = b |] ==> a = TheNeutralElement(G, f)
lemma group_inv_of_one:
group0(G, f) ==> GroupInv(G, f) ` TheNeutralElement(G, f) = TheNeutralElement(G, f)
lemma group0_2_L8A:
[| group0(G, f); a ∈ G; GroupInv(G, f) ` a = TheNeutralElement(G, f) |] ==> a = TheNeutralElement(G, f)
lemma group0_2_L8B:
[| group0(G, f); a ∈ G; a ≠ TheNeutralElement(G, f) |] ==> GroupInv(G, f) ` a ≠ TheNeutralElement(G, f)
lemma group0_2_L8C:
[| group0(G, f); a ∈ G; GroupInv(G, f) ` a ≠ TheNeutralElement(G, f) |] ==> a ≠ TheNeutralElement(G, f)
lemma group0_2_L9:
[| group0(G, f); a ∈ G; b ∈ G; f ` ⟨a, b⟩ = TheNeutralElement(G, f) |] ==> a = GroupInv(G, f) ` b
[| group0(G, f); a ∈ G; b ∈ G; f ` ⟨a, b⟩ = TheNeutralElement(G, f) |] ==> b = GroupInv(G, f) ` a
lemma group0_2_L9A:
[| group0(G, f); ∀g∈G. b(g) ∈ G ∧ f ` ⟨g, b(g)⟩ = TheNeutralElement(G, f) |] ==> ∀g∈G. b(g) = GroupInv(G, f) ` g
lemma group_inv_of_two:
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` a⟩ = GroupInv(G, f) ` (f ` ⟨a, b⟩)
lemma group_inv_of_three:
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨f ` ⟨a, b⟩, c⟩) = f ` ⟨GroupInv(G, f) ` c, GroupInv(G, f) ` (f ` ⟨a, b⟩)⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨f ` ⟨a, b⟩, c⟩) = f ` ⟨GroupInv(G, f) ` c, f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` a⟩⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨f ` ⟨a, b⟩, c⟩) = f ` ⟨f ` ⟨GroupInv(G, f) ` c, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` a⟩
lemma group_inv_of_inv:
[| group0(G, f); a ∈ G |] ==> a = GroupInv(G, f) ` (GroupInv(G, f) ` a)
lemma group0_2_L11:
[| group0(G, f); a ∈ G; b ∈ G; f ` ⟨GroupInv(G, f) ` a, b⟩ = TheNeutralElement(G, f) |] ==> a = b
lemma group0_2_L11A:
[| group0(G, f); a ∈ G; b ∈ G; f ` ⟨a, GroupInv(G, f) ` b⟩ = TheNeutralElement(G, f) |] ==> a = b
lemma group0_2_L11B:
[| group0(G, f); a ∈ G; GroupInv(G, f) ` b ≠ a |] ==> GroupInv(G, f) ` a ≠ b
lemma group0_2_L12:
[| group0(G, f); a ∈ G; b ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨a, GroupInv(G, f) ` b⟩) = f ` ⟨b, GroupInv(G, f) ` a⟩
[| group0(G, f); a ∈ G; b ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨GroupInv(G, f) ` a, b⟩) = f ` ⟨GroupInv(G, f) ` b, a⟩
lemma group0_2_L14A:
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` c⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, f ` ⟨b, GroupInv(G, f) ` c⟩⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨GroupInv(G, f) ` a, c⟩ = f ` ⟨f ` ⟨GroupInv(G, f) ` a, b⟩, f ` ⟨GroupInv(G, f) ` b, c⟩⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, c⟩)⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` b⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, f ` ⟨b, GroupInv(G, f) ` c⟩⟩ = f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` c⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` c⟩) = f ` ⟨f ` ⟨c, b⟩, GroupInv(G, f) ` a⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` c⟩, f ` ⟨c, GroupInv(G, f) ` b⟩⟩ = a
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, f ` ⟨b, c⟩⟩, GroupInv(G, f) ` c⟩ = f ` ⟨a, b⟩
lemma group0_2_L15:
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` (f ` ⟨c, d⟩)⟩ = f ` ⟨f ` ⟨f ` ⟨a, f ` ⟨b, GroupInv(G, f) ` d⟩⟩, GroupInv(G, f) ` a⟩, f ` ⟨a, GroupInv(G, f) ` c⟩⟩
lemma group0_2_L16:
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, b⟩ = a
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` b⟩ = a
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨GroupInv(G, f) ` a, f ` ⟨a, b⟩⟩ = b
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨a, f ` ⟨GroupInv(G, f) ` a, b⟩⟩ = b
lemma group0_2_L16A:
[| group0(G, f); a ∈ G; b ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, a⟩)⟩ = GroupInv(G, f) ` b
lemma group0_2_L17:
[| group0(G, f); H ⊆ G; H {is closed under} f |] ==> (H ∪ {TheNeutralElement(G, f)}) {is closed under} f
lemma group0_2_L18:
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G; c = f ` ⟨a, b⟩ |] ==> f ` ⟨c, GroupInv(G, f) ` b⟩ = a
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G; c = f ` ⟨a, b⟩ |] ==> f ` ⟨GroupInv(G, f) ` a, c⟩ = b
lemma group0_2_L19:
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G; a ≠ b |] ==> f ` ⟨a, c⟩ ≠ f ` ⟨b, c⟩
[| group0(G, f); a ∈ G; b ∈ G; c ∈ G; a ≠ b |] ==> f ` ⟨c, a⟩ ≠ f ` ⟨c, b⟩
lemma group0_3_L1:
[| IsAsubgroup(H, f); n = TheNeutralElement(H, restrict(f, H × H)) |] ==> n ∈ H
[| IsAsubgroup(H, f); n = TheNeutralElement(H, restrict(f, H × H)) |] ==> ∀h∈H. restrict(f, H × H) ` ⟨n, h⟩ = h
[| IsAsubgroup(H, f); n = TheNeutralElement(H, restrict(f, H × H)) |] ==> ∀h∈H. restrict(f, H × H) ` ⟨h, n⟩ = h
lemma group0_3_L2:
[| group0(G, f); IsAsubgroup(H, f) |] ==> H ⊆ G
lemma group0_3_L3:
[| group0(G, f); IsAsubgroup(H, f) |] ==> ∀h∈H. f ` ⟨TheNeutralElement(G, f), h⟩ = h ∧ f ` ⟨h, TheNeutralElement(G, f)⟩ = h
lemma group0_3_L4:
[| group0(G, f); IsAsubgroup(H, f) |] ==> TheNeutralElement(H, restrict(f, H × H)) = TheNeutralElement(G, f)
lemma group0_3_L5:
[| group0(G, f); IsAsubgroup(H, f) |] ==> TheNeutralElement(G, f) ∈ H
lemma group0_3_L6:
[| group0(G, f); IsAsubgroup(H, f); a ∈ H; b ∈ H |] ==> f ` ⟨a, b⟩ ∈ H
lemma group0_3_L7A:
[| IsAgroup(G, f); IsAsubgroup(H, f); g = restrict(f, H × H) |] ==> GroupInv(G, f) ∩ H × H = GroupInv(H, g)
theorem group0_3_T1:
[| group0(G, f); IsAsubgroup(H, f); g = restrict(f, H × H) |] ==> GroupInv(H, g) = restrict(GroupInv(G, f), H)
theorem group0_3_T2:
[| group0(G, f); IsAsubgroup(H, f); g = restrict(f, H × H) |] ==> ∀h∈H. GroupInv(H, g) ` h = GroupInv(G, f) ` h
theorem group0_3_T3A:
[| group0(G, f); IsAsubgroup(H, f); h ∈ H |] ==> GroupInv(G, f) ` h ∈ H
theorem group0_3_T3:
[| group0(G, f); H ≠ 0; H ⊆ G; H {is closed under} f; ∀x∈H. GroupInv(G, f) ` x ∈ H |] ==> IsAsubgroup(H, f)
lemma group0_3_L7:
[| IsAgroup(G, f); IsAsubgroup(H1, f); IsAsubgroup(H2, f) |] ==> IsAsubgroup(H1 ∩ H2, restrict(f, H1 × H1))
lemma group0_4_L2:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G; E ∈ G; F ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, f ` ⟨c, d⟩⟩, f ` ⟨E, F⟩⟩ = f ` ⟨f ` ⟨a, f ` ⟨d, F⟩⟩, f ` ⟨b, f ` ⟨c, E⟩⟩⟩
lemma group0_4_L3:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G; E ∈ G; F ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, f ` ⟨GroupInv(G, f) ` (f ` ⟨c, d⟩), GroupInv(G, f) ` (f ` ⟨E, F⟩)⟩⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` (f ` ⟨E, c⟩)⟩, f ` ⟨b, GroupInv(G, f) ` (f ` ⟨F, d⟩)⟩⟩
lemma group0_4_L4:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` a⟩ = f ` ⟨GroupInv(G, f) ` a, GroupInv(G, f) ` b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨a, b⟩) = f ` ⟨GroupInv(G, f) ` a, GroupInv(G, f) ` b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨a, GroupInv(G, f) ` b⟩) = f ` ⟨GroupInv(G, f) ` a, b⟩
lemma group0_4_L4A:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, c⟩ = f ` ⟨f ` ⟨c, a⟩, b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨GroupInv(G, f) ` a, GroupInv(G, f) ` (f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` c⟩)⟩ = GroupInv(G, f) ` (f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, c⟩)⟩)
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, c⟩)⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, GroupInv(G, f) ` c⟩)⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` c⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` b⟩
lemma group0_4_L4B:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, f ` ⟨b, GroupInv(G, f) ` c⟩⟩ = f ` ⟨a, GroupInv(G, f) ` c⟩
lemma group0_4_L4C:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, c⟩ = f ` ⟨f ` ⟨c, a⟩, b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, c⟩ = f ` ⟨a, f ` ⟨c, b⟩⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, c⟩ = f ` ⟨c, f ` ⟨a, b⟩⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, c⟩ = f ` ⟨f ` ⟨c, b⟩, a⟩
lemma group0_4_L4D:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨GroupInv(G, f) ` a, GroupInv(G, f) ` b⟩, c⟩ = f ` ⟨f ` ⟨c, GroupInv(G, f) ` a⟩, GroupInv(G, f) ` b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` a⟩, c⟩ = f ` ⟨f ` ⟨c, GroupInv(G, f) ` a⟩, GroupInv(G, f) ` b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> GroupInv(G, f) ` (f ` ⟨f ` ⟨GroupInv(G, f) ` a, b⟩, c⟩) = f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` c⟩
lemma group0_4_L5:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; c = f ` ⟨a, GroupInv(G, f) ` b⟩ |] ==> a = f ` ⟨b, c⟩
lemma group0_4_L6A:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` a⟩ = b
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨f ` ⟨GroupInv(G, f) ` a, b⟩, a⟩ = b
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨GroupInv(G, f) ` a, f ` ⟨b, a⟩⟩ = b
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨a, f ` ⟨b, GroupInv(G, f) ` a⟩⟩ = b
lemma group0_4_L6AA:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` a⟩ = GroupInv(G, f) ` b
lemma group0_4_L6AB:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨a, b⟩)⟩ = GroupInv(G, f) ` b
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨a, f ` ⟨b, GroupInv(G, f) ` a⟩⟩ = b
lemma group0_4_L6AC:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨a, GroupInv(G, f) ` b⟩)⟩ = b
lemma group0_4_L6B:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, c⟩, GroupInv(G, f) ` a⟩ = f ` ⟨b, c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨GroupInv(G, f) ` a, b⟩, c⟩, a⟩ = f ` ⟨b, c⟩
lemma group0_4_L6C:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨f ` ⟨a, b⟩, c⟩, d⟩, GroupInv(G, f) ` a⟩ = f ` ⟨f ` ⟨b, c⟩, d⟩
lemma group0_4_L6D:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` (f ` ⟨a, GroupInv(G, f) ` c⟩)⟩ = f ` ⟨c, GroupInv(G, f) ` b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨GroupInv(G, f) ` (f ` ⟨a, c⟩), f ` ⟨b, c⟩⟩ = f ` ⟨GroupInv(G, f) ` a, b⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨a, f ` ⟨b, f ` ⟨f ` ⟨c, GroupInv(G, f) ` a⟩, GroupInv(G, f) ` b⟩⟩⟩ = c
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` c⟩, f ` ⟨c, GroupInv(G, f) ` a⟩⟩ = b
lemma group0_4_L6E:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` (f ` ⟨a, c⟩)⟩ = f ` ⟨b, GroupInv(G, f) ` c⟩
lemma group0_4_L6F:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` (f ` ⟨a, b⟩)⟩ = f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` b⟩
lemma rearr_ab_gr_4_elemA:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, c⟩, d⟩ = f ` ⟨f ` ⟨f ` ⟨a, d⟩, b⟩, c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, c⟩, d⟩ = f ` ⟨f ` ⟨a, c⟩, f ` ⟨b, d⟩⟩
lemma rearr_ab_gr_4_elemB:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` d⟩ = f ` ⟨f ` ⟨f ` ⟨a, GroupInv(G, f) ` d⟩, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, c⟩, GroupInv(G, f) ` d⟩ = f ` ⟨f ` ⟨f ` ⟨a, GroupInv(G, f) ` d⟩, b⟩, c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` d⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` c⟩, f ` ⟨b, GroupInv(G, f) ` d⟩⟩
lemma group0_4_L7:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, c⟩, GroupInv(G, f) ` d⟩ = f ` ⟨f ` ⟨f ` ⟨a, GroupInv(G, f) ` d⟩, b⟩, c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, d⟩, GroupInv(G, f) ` (f ` ⟨f ` ⟨b, d⟩, f ` ⟨c, d⟩⟩)⟩ = f ` ⟨f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, c⟩)⟩, GroupInv(G, f) ` d⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, f ` ⟨b, c⟩⟩, d⟩ = f ` ⟨f ` ⟨f ` ⟨a, b⟩, d⟩, c⟩
lemma group0_4_L8:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨a, GroupInv(G, f) ` (f ` ⟨b, c⟩)⟩ = f ` ⟨f ` ⟨f ` ⟨a, GroupInv(G, f) ` d⟩, GroupInv(G, f) ` c⟩, f ` ⟨d, GroupInv(G, f) ` b⟩⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, f ` ⟨c, d⟩⟩ = f ` ⟨f ` ⟨c, a⟩, f ` ⟨b, d⟩⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, b⟩, f ` ⟨c, d⟩⟩ = f ` ⟨f ` ⟨a, c⟩, f ` ⟨b, d⟩⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, f ` ⟨b, GroupInv(G, f) ` c⟩⟩, d⟩ = f ` ⟨f ` ⟨f ` ⟨a, b⟩, d⟩, GroupInv(G, f) ` c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨f ` ⟨a, b⟩, GroupInv(G, f) ` (f ` ⟨c, d⟩)⟩, GroupInv(G, f) ` (f ` ⟨b, GroupInv(G, f) ` d⟩)⟩ = f ` ⟨a, GroupInv(G, f) ` c⟩
lemma group0_4_L8A:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, f ` ⟨c, GroupInv(G, f) ` d⟩⟩ = f ` ⟨f ` ⟨a, c⟩, f ` ⟨GroupInv(G, f) ` b, GroupInv(G, f) ` d⟩⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G |] ==> f ` ⟨f ` ⟨a, GroupInv(G, f) ` b⟩, f ` ⟨c, GroupInv(G, f) ` d⟩⟩ = f ` ⟨f ` ⟨f ` ⟨a, c⟩, GroupInv(G, f) ` b⟩, GroupInv(G, f) ` d⟩
lemma group0_4_L9:
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G; a = f ` ⟨f ` ⟨b, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` d⟩ |] ==> d = f ` ⟨f ` ⟨b, GroupInv(G, f) ` a⟩, GroupInv(G, f) ` c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G; a = f ` ⟨f ` ⟨b, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` d⟩ |] ==> d = f ` ⟨f ` ⟨GroupInv(G, f) ` a, b⟩, GroupInv(G, f) ` c⟩
[| group0(G, f); f {is commutative on} G; a ∈ G; b ∈ G; c ∈ G; d ∈ G; a = f ` ⟨f ` ⟨b, GroupInv(G, f) ` c⟩, GroupInv(G, f) ` d⟩ |] ==> b = f ` ⟨f ` ⟨a, d⟩, c⟩
lemma group0_5_L1:
[| group0(G, f); g ∈ G |] ==> RightTranslation(G, f, g) ∈ G -> G
[| group0(G, f); g ∈ G |] ==> LeftTranslation(G, f, g) ∈ G -> G
[| group0(G, f); g ∈ G |] ==> RightTranslation2(G, f, g) ∈ G × G -> G × G
[| group0(G, f); g ∈ G |] ==> LeftTranslation2(G, f, g) ∈ G × G -> G × G
lemma group0_5_L2:
[| group0(G, f); g ∈ G; a ∈ G |] ==> RightTranslation(G, f, g) ` a = f ` ⟨a, g⟩
[| group0(G, f); g ∈ G; a ∈ G |] ==> LeftTranslation(G, f, g) ` a = f ` ⟨g, a⟩
lemma group0_5_L3:
[| group0(G, f); g ∈ G; a ∈ G; b ∈ G |] ==> RightTranslation2(G, f, g) ` ⟨a, b⟩ = ⟨f ` ⟨a, g⟩, f ` ⟨b, g⟩⟩
[| group0(G, f); g ∈ G; a ∈ G; b ∈ G |] ==> LeftTranslation2(G, f, g) ` ⟨a, b⟩ = ⟨f ` ⟨g, a⟩, f ` ⟨g, b⟩⟩
lemma group0_5_L4:
[| group0(G, f); g ∈ G; h ∈ G; a ∈ G; Tg = LeftTranslation(G, f, g); Th = LeftTranslation(G, f, h) |] ==> Tg ` (Th ` a) = f ` ⟨f ` ⟨g, h⟩, a⟩
[| group0(G, f); g ∈ G; h ∈ G; a ∈ G; Tg = LeftTranslation(G, f, g); Th = LeftTranslation(G, f, h) |] ==> Tg ` (Th ` a) = LeftTranslation(G, f, f ` ⟨g, h⟩) ` a
lemma group0_5_L5:
[| group0(G, f); g ∈ G; h ∈ G; a ∈ G; Tg = RightTranslation(G, f, g); Th = RightTranslation(G, f, h) |] ==> Tg ` (Th ` a) = f ` ⟨f ` ⟨a, h⟩, g⟩
[| group0(G, f); g ∈ G; h ∈ G; a ∈ G; Tg = RightTranslation(G, f, g); Th = RightTranslation(G, f, h) |] ==> Tg ` (Th ` a) = RightTranslation(G, f, f ` ⟨h, g⟩) ` a
lemma group0_5_L6:
[| group0(G, f); g ∈ G; h ∈ G; A ⊆ G; Tg = RightTranslation(G, f, g); Th = RightTranslation(G, f, h) |] ==> Tg `` (Th `` A) = {f ` ⟨f ` ⟨a, h⟩, g⟩ . a ∈ A}
lemma group0_6_L1:
group0(G, f) ==> IsOdd(G, f, p) <-> (∀a∈G. p ` (GroupInv(G, f) ` a) = GroupInv(G, f) ` (p ` a))
lemma group0_6_L2:
[| group0(G, f); p ∈ G -> G |] ==> (∀a∈G. p ` (GroupInv(G, f) ` a) = GroupInv(G, f) ` (p ` a)) <-> (∀a∈G. GroupInv(G, f) ` (p ` (GroupInv(G, f) ` a)) = p ` a)