Theory HOL-Types_To_Sets.Linear_Algebra_On
Theory HOL-Types_To_Sets.Linear_Algebra_On
theory Linear_Algebra_On
imports
"Prerequisites"
"../Types_To_Sets"
Linear_Algebra_On_With
begin
subsection ‹Rewrite rules to make ‹ab_group_add› operations implicit.›
named_theorems implicit_ab_group_add
lemmas [implicit_ab_group_add] = sum_with[symmetric]
lemma semigroup_add_on_with_eq[implicit_ab_group_add]:
"semigroup_add_on_with S ((+)::_::semigroup_add ⇒ _) ⟷ (∀a∈S. ∀b∈S. a + b ∈ S)"
by (simp add: semigroup_add_on_with_Ball_def ac_simps)
lemma ab_semigroup_add_on_with_eq[implicit_ab_group_add]:
"ab_semigroup_add_on_with S ((+)::_::ab_semigroup_add ⇒ _) = semigroup_add_on_with S (+)"
unfolding ab_semigroup_add_on_with_Ball_def
by (simp add: semigroup_add_on_with_eq ac_simps)
lemma comm_monoid_add_on_with_eq[implicit_ab_group_add]:
"comm_monoid_add_on_with S ((+)::_::comm_monoid_add ⇒ _) 0 ⟷ semigroup_add_on_with S (+) ∧ 0 ∈ S"
unfolding comm_monoid_add_on_with_Ball_def
by (simp add: ab_semigroup_add_on_with_eq ac_simps)
lemma ab_group_add_on_with[implicit_ab_group_add]:
"ab_group_add_on_with S ((+)::_::ab_group_add ⇒ _) 0 (-) uminus ⟷
comm_monoid_add_on_with S (+) 0 ∧ (∀a∈S. -a∈S)"
unfolding ab_group_add_on_with_Ball_def
by simp
subsection ‹Definitions ∗‹on› carrier set›
locale module_on =
fixes S and scale :: "'a::comm_ring_1 ⇒ 'b::ab_group_add ⇒ 'b" (infixr "*s" 75)
assumes scale_right_distrib_on [algebra_simps]: "x ∈ S ⟹ y ∈ S ⟹ a *s (x + y) = a *s x + a *s y"
and scale_left_distrib_on [algebra_simps]: "x ∈ S ⟹ (a + b) *s x = a *s x + b *s x"
and scale_scale_on [simp]: "x ∈ S ⟹ a *s (b *s x) = (a * b) *s x"
and scale_one_on [simp]: "x ∈ S ⟹ 1 *s x = x"
and mem_add: "x ∈ S ⟹ y ∈ S ⟹ x + y ∈ S"
and mem_zero: "0 ∈ S"
and mem_scale: "x ∈ S ⟹ a *s x ∈ S"
begin
lemma S_ne: "S ≠ {}" using mem_zero by auto
lemma scale_minus_left_on: "scale (- a) x = - scale a x" if "x ∈ S"
by (metis add_cancel_right_right scale_left_distrib_on neg_eq_iff_add_eq_0 that)
lemma mem_uminus: "x ∈ S ⟹ -x ∈ S"
by (metis mem_scale scale_minus_left_on scale_one_on)
definition subspace :: "'b set ⇒ bool"
where subspace_on_def: "subspace T ⟷ 0 ∈ T ∧ (∀x∈T. ∀y∈T. x + y ∈ T) ∧ (∀c. ∀x∈T. c *s x ∈ T)"
definition span :: "'b set ⇒ 'b set"
where span_on_def: "span b = {sum (λa. r a *s a) t | t r. finite t ∧ t ⊆ b}"
definition dependent :: "'b set ⇒ bool"
where dependent_on_def: "dependent s ⟷ (∃t u. finite t ∧ t ⊆ s ∧ (sum (λv. u v *s v) t = 0 ∧ (∃v∈t. u v ≠ 0)))"
lemma implicit_subspace_with[implicit_ab_group_add]: "subspace_with (+) 0 (*s) = subspace"
unfolding subspace_on_def subspace_with_def ..
lemma implicit_dependent_with[implicit_ab_group_add]: "dependent_with (+) 0 (*s) = dependent"
unfolding dependent_on_def dependent_with_def sum_with ..
lemma implicit_span_with[implicit_ab_group_add]: "span_with (+) 0 (*s) = span"
unfolding span_on_def span_with_def sum_with ..
end
lemma implicit_module_on_with[implicit_ab_group_add]:
"module_on_with S (+) (-) uminus 0 = module_on S"
proof (intro ext iffI)
fix s::"'a⇒'b⇒'b" assume "module_on S s"
then interpret module_on S s .
show "module_on_with S (+) (-) uminus 0 s"
by (auto simp: module_on_with_def implicit_ab_group_add
mem_add mem_zero mem_uminus scale_right_distrib_on scale_left_distrib_on mem_scale)
qed (auto simp: module_on_with_def module_on_def implicit_ab_group_add)
locale module_pair_on = m1: module_on S1 scale1 +
m2: module_on S2 scale2
for S1:: "'b::ab_group_add set" and S2::"'c::ab_group_add set"
and scale1::"'a::comm_ring_1 ⇒ _" and scale2::"'a ⇒ _"
lemma implicit_module_pair_on_with[implicit_ab_group_add]:
"module_pair_on_with S1 S2 (+) (-) uminus 0 s1 (+) (-) uminus 0 s2 = module_pair_on S1 S2 s1 s2"
unfolding module_pair_on_with_def implicit_module_on_with module_pair_on_def ..
locale module_hom_on = m1: module_on S1 s1 + m2: module_on S2 s2
for S1 :: "'b::ab_group_add set" and S2 :: "'c::ab_group_add set"
and s1 :: "'a::comm_ring_1 ⇒ 'b ⇒ 'b" (infixr "*a" 75)
and s2 :: "'a::comm_ring_1 ⇒ 'c ⇒ 'c" (infixr "*b" 75) +
fixes f :: "'b ⇒ 'c"
assumes add: "⋀b1 b2. b1 ∈ S1 ⟹ b2 ∈ S1 ⟹ f (b1 + b2) = f b1 + f b2"
and scale: "⋀b. b ∈ S1 ⟹ f (r *a b) = r *b f b"
lemma implicit_module_hom_on_with[implicit_ab_group_add]:
"module_hom_on_with S1 S2 (+) (-) uminus 0 s1 (+) (-) uminus 0 s2 = module_hom_on S1 S2 s1 s2"
unfolding module_hom_on_with_def implicit_module_pair_on_with module_hom_on_def module_pair_on_def
module_hom_on_axioms_def
by (auto intro!: ext)
locale vector_space_on = module_on S scale
for S and scale :: "'a::field ⇒ 'b::ab_group_add ⇒ 'b" (infixr "*s" 75)
begin
definition dim :: "'b set ⇒ nat"
where "dim V = (if ∃b⊆S. ¬ dependent b ∧ span b = span V
then card (SOME b. b ⊆ S ∧ ¬ dependent b ∧ span b = span V)
else 0)"
lemma implicit_dim_with[implicit_ab_group_add]: "dim_on_with S (+) 0 (*s) = dim"
unfolding dim_on_with_def dim_def implicit_ab_group_add ..
end
lemma vector_space_on_alt_def: "vector_space_on S = module_on S"
unfolding vector_space_on_def module_on_def
by auto
lemma implicit_vector_space_on_with[implicit_ab_group_add]:
"vector_space_on_with S (+) (-) uminus 0 = vector_space_on S"
unfolding vector_space_on_alt_def vector_space_on_def vector_space_on_with_def implicit_module_on_with ..
locale linear_on = module_hom_on S1 S2 s1 s2 f
for S1 S2 and s1::"'a::field ⇒ 'b ⇒ 'b::ab_group_add"
and s2::"'a::field ⇒ 'c ⇒ 'c::ab_group_add"
and f
lemma implicit_linear_on_with[implicit_ab_group_add]:
"linear_on_with S1 S2 (+) (-) uminus 0 s1 (+) (-) uminus 0 s2 = linear_on S1 S2 s1 s2"
unfolding linear_on_with_def linear_on_def implicit_module_hom_on_with ..
locale finite_dimensional_vector_space_on = vector_space_on S scale for S scale +
fixes basis :: "'a set"
assumes finite_Basis: "finite basis"
and independent_Basis: "¬ dependent basis"
and span_Basis: "span basis = S" and basis_subset: "basis ⊆ S"
locale vector_space_pair_on = m1: vector_space_on S1 scale1 +
m2: vector_space_on S2 scale2
for S1:: "'b::ab_group_add set" and S2::"'c::ab_group_add set"
and scale1::"'a::field ⇒ _" and scale2::"'a ⇒ _"
locale finite_dimensional_vector_space_pair_1_on =
vs1: finite_dimensional_vector_space_on S1 scale1 Basis1 +
vs2: vector_space_on S2 scale2
for S1 S2
and scale1::"'a::field ⇒ 'b::ab_group_add ⇒ 'b"
and scale2::"'a::field ⇒ 'c::ab_group_add ⇒ 'c"
and Basis1
locale finite_dimensional_vector_space_pair_on =
vs1: finite_dimensional_vector_space_on S1 scale1 Basis1 +
vs2: finite_dimensional_vector_space_on S2 scale2 Basis2
for S1 S2
and scale1::"'a::field ⇒ 'b::ab_group_add ⇒ 'b"
and scale2::"'a::field ⇒ 'c::ab_group_add ⇒ 'c"
and Basis1 Basis2
subsection ‹Local Typedef for Subspace›
locale local_typedef_module_on = module_on S scale
for S and scale::"'a::comm_ring_1⇒'b⇒'b::ab_group_add" and s::"'s itself" +
assumes Ex_type_definition_S: "∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S"
begin
lemma mem_sum: "sum f X ∈ S" if "⋀x. x ∈ X ⟹ f x ∈ S"
using that
by (induction X rule: infinite_finite_induct) (auto intro!: mem_zero mem_add)
sublocale local_typedef S "TYPE('s)"
using Ex_type_definition_S by unfold_locales
sublocale local_typedef_ab_group_add_on_with "(+)::'b⇒'b⇒'b" "0::'b" "(-)" uminus S "TYPE('s)"
using mem_zero mem_add mem_scale[of _ "-1"]
by unfold_locales (auto simp: scale_minus_left_on)
context includes lifting_syntax begin
definition scale_S::"'a ⇒ 's ⇒ 's" where "scale_S = (id ---> rep ---> Abs) scale"
lemma scale_S_transfer[transfer_rule]: "((=) ===> cr_S ===> cr_S) scale scale_S"
unfolding scale_S_def
by (auto simp: cr_S_def mem_scale intro!: rel_funI)
end
lemma type_module_on_with: "module_on_with UNIV plus_S minus_S uminus_S (zero_S::'s) scale_S"
proof -
have "module_on_with {x. x ∈ S} (+) (-) uminus 0 scale"
using module_on_axioms
by (auto simp: module_on_with_def module_on_def ab_group_add_on_with_Ball_def
comm_monoid_add_on_with_Ball_def mem_uminus
ab_semigroup_add_on_with_Ball_def semigroup_add_on_with_def)
then show ?thesis
by transfer'
qed
lemma UNIV_transfer[transfer_rule]: "(rel_set cr_S) S UNIV"
by (auto simp: rel_set_def cr_S_def) (metis Abs_inverse)
end
context includes lifting_syntax begin
lemma Eps_unique_transfer_lemma:
"f' (Eps (λx. Domainp A x ∧ f x)) = g' (Eps g)"
if [transfer_rule]: "right_total A" "(A ===> (=)) f g" "(A ===> (=)) f' g'"
and holds: "∃x. Domainp A x ∧ f x"
and unique_g: "⋀x y. g x ⟹ g y ⟹ g' x = g' y"
proof -
define Epsg where "Epsg = Eps g"
have "∃x. g x"
by transfer (simp add: holds)
then have "g Epsg"
unfolding Epsg_def
by (rule someI_ex)
obtain x where x[transfer_rule]: "A x Epsg"
by (meson ‹right_total A› right_totalE)
then have "Domainp A x" by auto
from ‹g Epsg›[untransferred] have "f x" .
from unique_g have unique:
"⋀x y. Domainp A x ⟹ Domainp A y ⟹ f x ⟹ f y ⟹ f' x = f' y"
by transfer
have "f' (Eps (λx. Domainp A x ∧ f x)) = f' x"
apply (rule unique[OF _ ‹Domainp A x› _ ‹f x›])
apply (metis (mono_tags, lifting) local.holds someI_ex)
apply (metis (mono_tags, lifting) local.holds someI_ex)
done
show "f' (SOME x. Domainp A x ∧ f x) = g' (Eps g)"
using x ‹f' (Eps _) = f' x› Epsg_def
using rel_funE that(3) by fastforce
qed
end
locale local_typedef_vector_space_on = local_typedef_module_on S scale s + vector_space_on S scale
for S and scale::"'a::field⇒'b⇒'b::ab_group_add" and s::"'s itself"
begin
lemma type_vector_space_on_with: "vector_space_on_with UNIV plus_S minus_S uminus_S (zero_S::'s) scale_S"
using type_module_on_with
by (auto simp: vector_space_on_with_def)
context includes lifting_syntax begin
definition dim_S::"'s set ⇒ nat" where "dim_S = dim_on_with UNIV plus_S zero_S scale_S"
lemma transfer_dim[transfer_rule]: "(rel_set cr_S ===> (=)) dim dim_S"
proof (rule rel_funI)
fix V V'
assume [transfer_rule]: "rel_set cr_S V V'"
then have subset: "V ⊆ S"
by (auto simp: rel_set_def cr_S_def)
then have "span V ⊆ S"
by (auto simp: span_on_def intro!: mem_sum mem_scale)
note type_dim_eq_card =
vector_space.dim_eq_card[var_simplified explicit_ab_group_add, unoverload_type 'd,
OF type.ab_group_add_axioms type_vector_space_on_with]
have *: "(∃b⊆UNIV. ¬ dependent_with plus_S zero_S scale_S b ∧ span_with plus_S zero_S scale_S b = span_with plus_S zero_S scale_S V') ⟷
(∃b⊆S. ¬ local.dependent b ∧ local.span b = local.span V)"
unfolding subset_iff
by transfer (simp add: implicit_ab_group_add Ball_def)
have **[symmetric]:
"card (SOME b. Domainp (rel_set cr_S) b ∧ (¬ dependent_with (+) 0 scale b ∧ span_with (+) 0 scale b = span_with (+) 0 scale V)) =
card (SOME b. ¬ dependent_with plus_S zero_S scale_S b ∧ span_with plus_S zero_S scale_S b = span_with plus_S zero_S scale_S V')"
if "b ⊆ S" "¬dependent b" "span b = span V" for b
apply (rule Eps_unique_transfer_lemma[where f'=card and g'=card])
subgoal by (rule right_total_rel_set) (rule transfer_raw)
subgoal by transfer_prover
subgoal by transfer_prover
subgoal using that by (auto simp: implicit_ab_group_add Domainp_set Domainp_cr_S)
subgoal premises prems for b c
proof -
from type_dim_eq_card[of b V'] type_dim_eq_card[of c V'] prems
show ?thesis by simp
qed
done
show "local.dim V = dim_S V'"
unfolding dim_def dim_S_def * dim_on_with_def
by (auto simp: ** Domainp_set Domainp_cr_S implicit_ab_group_add subset_eq)
qed
end
end
locale local_typedef_finite_dimensional_vector_space_on = local_typedef_vector_space_on S scale s +
finite_dimensional_vector_space_on S scale Basis
for S and scale::"'a::field⇒'b⇒'b::ab_group_add" and Basis and s::"'s itself"
begin
definition "Basis_S = Abs ` Basis"
lemma Basis_S_transfer[transfer_rule]: "rel_set cr_S Basis Basis_S"
using Abs_inverse rep_inverse basis_subset
by (force simp: rel_set_def Basis_S_def cr_S_def)
lemma type_finite_dimensional_vector_space_on_with:
"finite_dimensional_vector_space_on_with UNIV plus_S minus_S uminus_S zero_S scale_S Basis_S"
proof -
have "finite Basis_S" by transfer (rule finite_Basis)
moreover have "¬ dependent_with plus_S zero_S scale_S Basis_S"
by transfer (simp add: implicit_dependent_with independent_Basis)
moreover have "span_with plus_S zero_S scale_S Basis_S = UNIV"
by transfer (simp add: implicit_span_with span_Basis)
ultimately show ?thesis
using type_vector_space_on_with
by (auto simp: finite_dimensional_vector_space_on_with_def)
qed
end
locale local_typedef_module_pair =
lt1: local_typedef_module_on S1 scale1 s +
lt2: local_typedef_module_on S2 scale2 t
for S1::"'b::ab_group_add set" and scale1::"'a::comm_ring_1 ⇒ 'b ⇒ 'b" and s::"'s itself"
and S2::"'c::ab_group_add set" and scale2::"'a ⇒ 'c ⇒ 'c" and t::"'t itself"
begin
lemma type_module_pair_on_with:
"module_pair_on_with UNIV UNIV lt1.plus_S lt1.minus_S lt1.uminus_S (lt1.zero_S::'s) lt1.scale_S
lt2.plus_S lt2.minus_S lt2.uminus_S (lt2.zero_S::'t) lt2.scale_S"
by (simp add: lt1.type_module_on_with lt2.type_module_on_with module_pair_on_with_def)
end
locale local_typedef_vector_space_pair =
local_typedef_module_pair S1 scale1 s S2 scale2 t
for S1::"'b::ab_group_add set" and scale1::"'a::field ⇒ 'b ⇒ 'b" and s::"'s itself"
and S2::"'c::ab_group_add set" and scale2::"'a ⇒ 'c ⇒ 'c" and t::"'t itself"
begin
lemma type_vector_space_pair_on_with:
"vector_space_pair_on_with UNIV UNIV lt1.plus_S lt1.minus_S lt1.uminus_S (lt1.zero_S::'s) lt1.scale_S
lt2.plus_S lt2.minus_S lt2.uminus_S (lt2.zero_S::'t) lt2.scale_S"
by (simp add: type_module_pair_on_with vector_space_pair_on_with_def)
sublocale lt1: local_typedef_vector_space_on S1 scale1 s by unfold_locales
sublocale lt2: local_typedef_vector_space_on S2 scale2 t by unfold_locales
end
locale local_typedef_finite_dimensional_vector_space_pair_1 =
lt1: local_typedef_finite_dimensional_vector_space_on S1 scale1 Basis1 s +
lt2: local_typedef_vector_space_on S2 scale2 t
for S1::"'b::ab_group_add set" and scale1::"'a::field ⇒ 'b ⇒ 'b" and Basis1 and s::"'s itself"
and S2::"'c::ab_group_add set" and scale2::"'a ⇒ 'c ⇒ 'c" and t::"'t itself"
begin
lemma type_finite_dimensional_vector_space_pair_1_on_with:
"finite_dimensional_vector_space_pair_1_on_with UNIV UNIV lt1.plus_S lt1.minus_S lt1.uminus_S (lt1.zero_S::'s) lt1.scale_S lt1.Basis_S
lt2.plus_S lt2.minus_S lt2.uminus_S (lt2.zero_S::'t) lt2.scale_S"
by (simp add: finite_dimensional_vector_space_pair_1_on_with_def
lt1.type_finite_dimensional_vector_space_on_with lt2.type_vector_space_on_with)
end
locale local_typedef_finite_dimensional_vector_space_pair =
lt1: local_typedef_finite_dimensional_vector_space_on S1 scale1 Basis1 s +
lt2: local_typedef_finite_dimensional_vector_space_on S2 scale2 Basis2 t
for S1::"'b::ab_group_add set" and scale1::"'a::field ⇒ 'b ⇒ 'b" and Basis1 and s::"'s itself"
and S2::"'c::ab_group_add set" and scale2::"'a ⇒ 'c ⇒ 'c" and Basis2 and t::"'t itself"
begin
lemma type_finite_dimensional_vector_space_pair_on_with:
"finite_dimensional_vector_space_pair_on_with UNIV UNIV lt1.plus_S lt1.minus_S lt1.uminus_S (lt1.zero_S::'s) lt1.scale_S lt1.Basis_S
lt2.plus_S lt2.minus_S lt2.uminus_S (lt2.zero_S::'t) lt2.scale_S lt2.Basis_S"
by (simp add: finite_dimensional_vector_space_pair_on_with_def
lt1.type_finite_dimensional_vector_space_on_with
lt2.type_finite_dimensional_vector_space_on_with)
end
subsection ‹Transfer from type-based \<^theory>‹HOL.Modules› and \<^theory>‹HOL.Vector_Spaces››
lemmas [transfer_rule] = right_total_fun_eq_transfer
and [transfer_rule del] = vimage_parametric
subsubsection ‹Modules›
context module_on begin
context includes lifting_syntax assumes ltd: "∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S" begin
interpretation local_typedef_module_on S scale "TYPE('s)" by unfold_locales fact
text‹Get theorem names:›
print_locale! module
text‹Then replace:
▩‹notes[^"]*"([^"]*).*›
with
▩‹$1 = module.$1›
›
text ‹TODO: automate systematic naming!›
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'd,
OF type.ab_group_add_axioms type_module_on_with,
untransferred,
var_simplified implicit_ab_group_add]:
lt_scale_left_commute = module.scale_left_commute
and lt_scale_zero_left = module.scale_zero_left
and lt_scale_minus_left = module.scale_minus_left
and lt_scale_left_diff_distrib = module.scale_left_diff_distrib
and lt_scale_sum_left = module.scale_sum_left
and lt_scale_zero_right = module.scale_zero_right
and lt_scale_minus_right = module.scale_minus_right
and lt_scale_right_diff_distrib = module.scale_right_diff_distrib
and lt_scale_sum_right = module.scale_sum_right
and lt_sum_constant_scale = module.sum_constant_scale
and lt_subspace_def = module.subspace_def
and lt_subspaceI = module.subspaceI
and lt_subspace_single_0 = module.subspace_single_0
and lt_subspace_0 = module.subspace_0
and lt_subspace_add = module.subspace_add
and lt_subspace_scale = module.subspace_scale
and lt_subspace_neg = module.subspace_neg
and lt_subspace_diff = module.subspace_diff
and lt_subspace_sum = module.subspace_sum
and lt_subspace_inter = module.subspace_inter
and lt_span_explicit = module.span_explicit
and lt_span_explicit' = module.span_explicit'
and lt_span_finite = module.span_finite
and lt_span_induct_alt = module.span_induct_alt
and lt_span_mono = module.span_mono
and lt_span_base = module.span_base
and lt_span_superset = module.span_superset
and lt_span_zero = module.span_zero
and lt_span_add = module.span_add
and lt_span_scale = module.span_scale
and lt_subspace_span = module.subspace_span
and lt_span_neg = module.span_neg
and lt_span_diff = module.span_diff
and lt_span_sum = module.span_sum
and lt_span_minimal = module.span_minimal
and lt_span_unique = module.span_unique
and lt_span_subspace_induct = module.span_subspace_induct
and lt_span_induct = module.span_induct
and lt_span_empty = module.span_empty
and lt_span_subspace = module.span_subspace
and lt_span_span = module.span_span
and lt_span_add_eq = module.span_add_eq
and lt_span_add_eq2 = module.span_add_eq2
and lt_span_singleton = module.span_singleton
and lt_span_Un = module.span_Un
and lt_span_insert = module.span_insert
and lt_span_breakdown = module.span_breakdown
and lt_span_breakdown_eq = module.span_breakdown_eq
and lt_span_clauses = module.span_clauses
and lt_span_eq_iff = module.span_eq_iff
and lt_span_eq = module.span_eq
and lt_eq_span_insert_eq = module.eq_span_insert_eq
and lt_dependent_explicit = module.dependent_explicit
and lt_dependent_mono = module.dependent_mono
and lt_independent_mono = module.independent_mono
and lt_dependent_zero = module.dependent_zero
and lt_independent_empty = module.independent_empty
and lt_independent_explicit_module = module.independent_explicit_module
and lt_independentD = module.independentD
and lt_independent_Union_directed = module.independent_Union_directed
and lt_dependent_finite = module.dependent_finite
and lt_independentD_alt = module.independentD_alt
and lt_independentD_unique = module.independentD_unique
and lt_spanning_subset_independent = module.spanning_subset_independent
and lt_module_hom_scale_self = module.module_hom_scale_self
and lt_module_hom_scale_left = module.module_hom_scale_left
and lt_module_hom_id = module.module_hom_id
and lt_module_hom_ident = module.module_hom_ident
and lt_module_hom_uminus = module.module_hom_uminus
and lt_subspace_UNIV = module.subspace_UNIV
end
lemmas_with [cancel_type_definition,
OF S_ne,
folded subset_iff',
simplified pred_fun_def,
simplified]:
scale_left_commute = lt_scale_left_commute
and scale_zero_left = lt_scale_zero_left
and scale_minus_left = lt_scale_minus_left
and scale_left_diff_distrib = lt_scale_left_diff_distrib
and scale_sum_left = lt_scale_sum_left
and scale_zero_right = lt_scale_zero_right
and scale_minus_right = lt_scale_minus_right
and scale_right_diff_distrib = lt_scale_right_diff_distrib
and scale_sum_right = lt_scale_sum_right
and sum_constant_scale = lt_sum_constant_scale
and subspace_def = lt_subspace_def
and subspaceI = lt_subspaceI
and subspace_single_0 = lt_subspace_single_0
and subspace_0 = lt_subspace_0
and subspace_add = lt_subspace_add
and subspace_scale = lt_subspace_scale
and subspace_neg = lt_subspace_neg
and subspace_diff = lt_subspace_diff
and subspace_sum = lt_subspace_sum
and subspace_inter = lt_subspace_inter
and span_explicit = lt_span_explicit
and span_explicit' = lt_span_explicit'
and span_finite = lt_span_finite
and span_induct_alt[consumes 1, case_names base step, induct set : span] = lt_span_induct_alt
and span_mono = lt_span_mono
and span_base = lt_span_base
and span_superset = lt_span_superset
and span_zero = lt_span_zero
and span_add = lt_span_add
and span_scale = lt_span_scale
and subspace_span = lt_subspace_span
and span_neg = lt_span_neg
and span_diff = lt_span_diff
and span_sum = lt_span_sum
and span_minimal = lt_span_minimal
and span_unique = lt_span_unique
and span_subspace_induct[consumes 2] = lt_span_subspace_induct
and span_induct[consumes 1, case_names base step, induct set : span] = lt_span_induct
and span_empty = lt_span_empty
and span_subspace = lt_span_subspace
and span_span = lt_span_span
and span_add_eq = lt_span_add_eq
and span_add_eq2 = lt_span_add_eq2
and span_singleton = lt_span_singleton
and span_Un = lt_span_Un
and span_insert = lt_span_insert
and span_breakdown = lt_span_breakdown
and span_breakdown_eq = lt_span_breakdown_eq
and span_clauses = lt_span_clauses
and span_eq_iff = lt_span_eq_iff
and span_eq = lt_span_eq
and eq_span_insert_eq = lt_eq_span_insert_eq
and dependent_explicit = lt_dependent_explicit
and dependent_mono = lt_dependent_mono
and independent_mono = lt_independent_mono
and dependent_zero = lt_dependent_zero
and independent_empty = lt_independent_empty
and independent_explicit_module = lt_independent_explicit_module
and independentD = lt_independentD
and independent_Union_directed = lt_independent_Union_directed
and dependent_finite = lt_dependent_finite
and independentD_alt = lt_independentD_alt
and independentD_unique = lt_independentD_unique
and spanning_subset_independent = lt_spanning_subset_independent
and module_hom_scale_self = lt_module_hom_scale_self
and module_hom_scale_left = lt_module_hom_scale_left
and module_hom_id = lt_module_hom_id
and module_hom_ident = lt_module_hom_ident
and module_hom_uminus = lt_module_hom_uminus
and subspace_UNIV = lt_subspace_UNIV
end
subsubsection ‹Vector Spaces›
context vector_space_on begin
context includes lifting_syntax assumes "∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S" begin
interpretation local_typedef_vector_space_on S scale "TYPE('s)" by unfold_locales fact
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'd,
OF type.ab_group_add_axioms type_vector_space_on_with,
folded dim_S_def,
untransferred,
var_simplified implicit_ab_group_add]:
lt_linear_id = vector_space.linear_id
and lt_linear_ident = vector_space.linear_ident
and lt_linear_scale_self = vector_space.linear_scale_self
and lt_linear_scale_left = vector_space.linear_scale_left
and lt_linear_uminus = vector_space.linear_uminus
and lt_linear_imp_scale["consumes" - 1, "case_names" "1"] = vector_space.linear_imp_scale
and lt_scale_eq_0_iff = vector_space.scale_eq_0_iff
and lt_scale_left_imp_eq = vector_space.scale_left_imp_eq
and lt_scale_right_imp_eq = vector_space.scale_right_imp_eq
and lt_scale_cancel_left = vector_space.scale_cancel_left
and lt_scale_cancel_right = vector_space.scale_cancel_right
and lt_injective_scale = vector_space.injective_scale
and lt_dependent_def = vector_space.dependent_def
and lt_dependent_single = vector_space.dependent_single
and lt_in_span_insert = vector_space.in_span_insert
and lt_dependent_insertD = vector_space.dependent_insertD
and lt_independent_insertI = vector_space.independent_insertI
and lt_independent_insert = vector_space.independent_insert
and lt_maximal_independent_subset_extend["consumes" - 1, "case_names" "1"] = vector_space.maximal_independent_subset_extend
and lt_maximal_independent_subset["consumes" - 1, "case_names" "1"] = vector_space.maximal_independent_subset
and lt_in_span_delete = vector_space.in_span_delete
and lt_span_redundant = vector_space.span_redundant
and lt_span_trans = vector_space.span_trans
and lt_span_insert_0 = vector_space.span_insert_0
and lt_span_delete_0 = vector_space.span_delete_0
and lt_span_image_scale = vector_space.span_image_scale
and lt_exchange_lemma = vector_space.exchange_lemma
and lt_independent_span_bound = vector_space.independent_span_bound
and lt_independent_explicit_finite_subsets = vector_space.independent_explicit_finite_subsets
and lt_independent_if_scalars_zero = vector_space.independent_if_scalars_zero
and lt_subspace_sums = vector_space.subspace_sums
and lt_dim_unique = vector_space.dim_unique
and lt_dim_eq_card = vector_space.dim_eq_card
and lt_basis_card_eq_dim = vector_space.basis_card_eq_dim
and lt_basis_exists = vector_space.basis_exists
and lt_dim_eq_card_independent = vector_space.dim_eq_card_independent
and lt_dim_span = vector_space.dim_span
and lt_dim_span_eq_card_independent = vector_space.dim_span_eq_card_independent
and lt_dim_le_card = vector_space.dim_le_card
and lt_span_eq_dim = vector_space.span_eq_dim
and lt_dim_le_card' = vector_space.dim_le_card'
and lt_span_card_ge_dim = vector_space.span_card_ge_dim
and lt_dim_with = vector_space.dim_with
end
lemmas_with [cancel_type_definition,
OF S_ne,
folded subset_iff',
simplified pred_fun_def,
simplified]:
linear_id = lt_linear_id
and linear_ident = lt_linear_ident
and linear_scale_self = lt_linear_scale_self
and linear_scale_left = lt_linear_scale_left
and linear_uminus = lt_linear_uminus
and linear_imp_scale["consumes" - 1, "case_names" "1"] = lt_linear_imp_scale
and scale_eq_0_iff = lt_scale_eq_0_iff
and scale_left_imp_eq = lt_scale_left_imp_eq
and scale_right_imp_eq = lt_scale_right_imp_eq
and scale_cancel_left = lt_scale_cancel_left
and scale_cancel_right = lt_scale_cancel_right
and dependent_def = lt_dependent_def
and dependent_single = lt_dependent_single
and in_span_insert = lt_in_span_insert
and dependent_insertD = lt_dependent_insertD
and independent_insertI = lt_independent_insertI
and independent_insert = lt_independent_insert
and maximal_independent_subset_extend["consumes" - 1, "case_names" "1"] = lt_maximal_independent_subset_extend
and maximal_independent_subset["consumes" - 1, "case_names" "1"] = lt_maximal_independent_subset
and in_span_delete = lt_in_span_delete
and span_redundant = lt_span_redundant
and span_trans = lt_span_trans
and span_insert_0 = lt_span_insert_0
and span_delete_0 = lt_span_delete_0
and span_image_scale = lt_span_image_scale
and exchange_lemma = lt_exchange_lemma
and independent_span_bound = lt_independent_span_bound
and independent_explicit_finite_subsets = lt_independent_explicit_finite_subsets
and independent_if_scalars_zero = lt_independent_if_scalars_zero
and subspace_sums = lt_subspace_sums
and dim_unique = lt_dim_unique
and dim_eq_card = lt_dim_eq_card
and basis_card_eq_dim = lt_basis_card_eq_dim
and basis_exists["consumes" - 1, "case_names" "1"] = lt_basis_exists
and dim_eq_card_independent = lt_dim_eq_card_independent
and dim_span = lt_dim_span
and dim_span_eq_card_independent = lt_dim_span_eq_card_independent
and dim_le_card = lt_dim_le_card
and span_eq_dim = lt_span_eq_dim
and dim_le_card' = lt_dim_le_card'
and span_card_ge_dim = lt_span_card_ge_dim
and dim_with = lt_dim_with
end
subsubsection ‹Finite Dimensional Vector Spaces›
context finite_dimensional_vector_space_on begin
context includes lifting_syntax assumes "∃(Rep::'s ⇒ 'a) (Abs::'a ⇒ 's). type_definition Rep Abs S" begin
interpretation local_typedef_finite_dimensional_vector_space_on S scale basis "TYPE('s)" by unfold_locales fact
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'd,
OF type.ab_group_add_axioms type_finite_dimensional_vector_space_on_with,
folded dim_S_def,
untransferred,
var_simplified implicit_ab_group_add]:
lt_finiteI_independent = finite_dimensional_vector_space.finiteI_independent
and lt_dim_empty = finite_dimensional_vector_space.dim_empty
and lt_dim_insert = finite_dimensional_vector_space.dim_insert
and lt_dim_singleton = finite_dimensional_vector_space.dim_singleton
and lt_choose_subspace_of_subspace["consumes" - 1, "case_names" "1"] = finite_dimensional_vector_space.choose_subspace_of_subspace
and lt_basis_subspace_exists["consumes" - 1, "case_names" "1"] = finite_dimensional_vector_space.basis_subspace_exists
and lt_dim_mono = finite_dimensional_vector_space.dim_mono
and lt_dim_subset = finite_dimensional_vector_space.dim_subset
and lt_dim_eq_0 = finite_dimensional_vector_space.dim_eq_0
and lt_dim_UNIV = finite_dimensional_vector_space.dim_UNIV
and lt_independent_card_le_dim = finite_dimensional_vector_space.independent_card_le_dim
and lt_card_ge_dim_independent = finite_dimensional_vector_space.card_ge_dim_independent
and lt_card_le_dim_spanning = finite_dimensional_vector_space.card_le_dim_spanning
and lt_card_eq_dim = finite_dimensional_vector_space.card_eq_dim
and lt_subspace_dim_equal = finite_dimensional_vector_space.subspace_dim_equal
and lt_dim_eq_span = finite_dimensional_vector_space.dim_eq_span
and lt_dim_psubset = finite_dimensional_vector_space.dim_psubset
and lt_indep_card_eq_dim_span = finite_dimensional_vector_space.indep_card_eq_dim_span
and lt_independent_bound_general = finite_dimensional_vector_space.independent_bound_general
and lt_independent_explicit = finite_dimensional_vector_space.independent_explicit
and lt_dim_sums_Int = finite_dimensional_vector_space.dim_sums_Int
and lt_dependent_biggerset_general = finite_dimensional_vector_space.dependent_biggerset_general
and lt_subset_le_dim = finite_dimensional_vector_space.subset_le_dim
and lt_linear_inj_imp_surj = finite_dimensional_vector_space.linear_inj_imp_surj
and lt_linear_surj_imp_inj = finite_dimensional_vector_space.linear_surj_imp_inj
and lt_linear_inverse_left = finite_dimensional_vector_space.linear_inverse_left
and lt_left_inverse_linear = finite_dimensional_vector_space.left_inverse_linear
and lt_right_inverse_linear = finite_dimensional_vector_space.right_inverse_linear
end
lemmas_with [cancel_type_definition,
OF S_ne,
folded subset_iff',
simplified pred_fun_def,
simplified]:
finiteI_independent = lt_finiteI_independent
and dim_empty = lt_dim_empty
and dim_insert = lt_dim_insert
and dim_singleton = lt_dim_singleton
and choose_subspace_of_subspace["consumes" - 1, "case_names" "1"] = lt_choose_subspace_of_subspace
and basis_subspace_exists["consumes" - 1, "case_names" "1"] = lt_basis_subspace_exists
and dim_mono = lt_dim_mono
and dim_subset = lt_dim_subset
and dim_eq_0 = lt_dim_eq_0
and dim_UNIV = lt_dim_UNIV
and independent_card_le_dim = lt_independent_card_le_dim
and card_ge_dim_independent = lt_card_ge_dim_independent
and card_le_dim_spanning = lt_card_le_dim_spanning
and card_eq_dim = lt_card_eq_dim
and subspace_dim_equal = lt_subspace_dim_equal
and dim_eq_span = lt_dim_eq_span
and dim_psubset = lt_dim_psubset
and indep_card_eq_dim_span = lt_indep_card_eq_dim_span
and independent_bound_general = lt_independent_bound_general
and independent_explicit = lt_independent_explicit
and dim_sums_Int = lt_dim_sums_Int
and dependent_biggerset_general = lt_dependent_biggerset_general
and subset_le_dim = lt_subset_le_dim
and linear_inj_imp_surj = lt_linear_inj_imp_surj
and linear_surj_imp_inj = lt_linear_surj_imp_inj
and linear_inverse_left = lt_linear_inverse_left
and left_inverse_linear = lt_left_inverse_linear
and right_inverse_linear = lt_right_inverse_linear
end
context module_pair_on begin
context includes lifting_syntax
assumes
"∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S1"
"∃(Rep::'t ⇒ 'c) (Abs::'c ⇒ 't). type_definition Rep Abs S2" begin
interpretation local_typedef_module_pair S1 scale1 "TYPE('s)" S2 scale2 "TYPE('t)" by unfold_locales fact+
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'e 'f,
OF lt2.type.ab_group_add_axioms lt1.type.ab_group_add_axioms type_module_pair_on_with,
untransferred,
var_simplified implicit_ab_group_add]:
lt_module_hom_zero = module_pair.module_hom_zero
and lt_module_hom_add = module_pair.module_hom_add
and lt_module_hom_sub = module_pair.module_hom_sub
and lt_module_hom_neg = module_pair.module_hom_neg
and lt_module_hom_scale = module_pair.module_hom_scale
and lt_module_hom_compose_scale = module_pair.module_hom_compose_scale
and lt_module_hom_sum = module_pair.module_hom_sum
and lt_module_hom_eq_on_span = module_pair.module_hom_eq_on_span
end
lemmas_with [cancel_type_definition, OF m1.S_ne,
cancel_type_definition, OF m2.S_ne,
folded subset_iff' top_set_def,
simplified pred_fun_def,
simplified]:
module_hom_zero = lt_module_hom_zero
and module_hom_add = lt_module_hom_add
and module_hom_sub = lt_module_hom_sub
and module_hom_neg = lt_module_hom_neg
and module_hom_scale = lt_module_hom_scale
and module_hom_compose_scale = lt_module_hom_compose_scale
and module_hom_sum = lt_module_hom_sum
and module_hom_eq_on_span = lt_module_hom_eq_on_span
end
context vector_space_pair_on begin
context includes lifting_syntax
notes [transfer_rule del] = Collect_transfer
assumes
"∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S1"
"∃(Rep::'t ⇒ 'c) (Abs::'c ⇒ 't). type_definition Rep Abs S2" begin
interpretation local_typedef_vector_space_pair S1 scale1 "TYPE('s)" S2 scale2 "TYPE('t)" by unfold_locales fact+
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'e 'f,
OF lt2.type.ab_group_add_axioms lt1.type.ab_group_add_axioms type_vector_space_pair_on_with,
folded lt1.dim_S_def lt2.dim_S_def,
untransferred,
var_simplified implicit_ab_group_add]:
lt_linear_0 = vector_space_pair.linear_0
and lt_linear_add = vector_space_pair.linear_add
and lt_linear_scale = vector_space_pair.linear_scale
and lt_linear_neg = vector_space_pair.linear_neg
and lt_linear_diff = vector_space_pair.linear_diff
and lt_linear_sum = vector_space_pair.linear_sum
and lt_linear_inj_on_iff_eq_0 = vector_space_pair.linear_inj_on_iff_eq_0
and lt_linear_inj_iff_eq_0 = vector_space_pair.linear_inj_iff_eq_0
and lt_linear_subspace_image = vector_space_pair.linear_subspace_image
and lt_linear_subspace_vimage = vector_space_pair.linear_subspace_vimage
and lt_linear_subspace_kernel = vector_space_pair.linear_subspace_kernel
and lt_linear_span_image = vector_space_pair.linear_span_image
and lt_linear_dependent_inj_imageD = vector_space_pair.linear_dependent_inj_imageD
and lt_linear_eq_0_on_span = vector_space_pair.linear_eq_0_on_span
and lt_linear_independent_injective_image = vector_space_pair.linear_independent_injective_image
and lt_linear_inj_on_span_independent_image = vector_space_pair.linear_inj_on_span_independent_image
and lt_linear_inj_on_span_iff_independent_image = vector_space_pair.linear_inj_on_span_iff_independent_image
and lt_linear_subspace_linear_preimage = vector_space_pair.linear_subspace_linear_preimage
and lt_linear_spans_image = vector_space_pair.linear_spans_image
and lt_linear_spanning_surjective_image = vector_space_pair.linear_spanning_surjective_image
and lt_linear_eq_on_span = vector_space_pair.linear_eq_on_span
and lt_linear_compose_scale_right = vector_space_pair.linear_compose_scale_right
and lt_linear_compose_add = vector_space_pair.linear_compose_add
and lt_linear_zero = vector_space_pair.linear_zero
and lt_linear_compose_sub = vector_space_pair.linear_compose_sub
and lt_linear_compose_neg = vector_space_pair.linear_compose_neg
and lt_linear_compose_scale = vector_space_pair.linear_compose_scale
and lt_linear_indep_image_lemma = vector_space_pair.linear_indep_image_lemma
and lt_linear_eq_on = vector_space_pair.linear_eq_on
and lt_linear_compose_sum = vector_space_pair.linear_compose_sum
and lt_linear_independent_extend_subspace = vector_space_pair.linear_independent_extend_subspace
and lt_linear_independent_extend = vector_space_pair.linear_independent_extend
and lt_linear_exists_left_inverse_on = vector_space_pair.linear_exists_left_inverse_on
and lt_linear_exists_right_inverse_on = vector_space_pair.linear_exists_right_inverse_on
and lt_linear_inj_on_left_inverse = vector_space_pair.linear_inj_on_left_inverse
and lt_linear_injective_left_inverse = vector_space_pair.linear_injective_left_inverse
and lt_linear_surj_right_inverse = vector_space_pair.linear_surj_right_inverse
and lt_linear_surjective_right_inverse = vector_space_pair.linear_surjective_right_inverse
and lt_finite_basis_to_basis_subspace_isomorphism = vector_space_pair.finite_basis_to_basis_subspace_isomorphism
end
lemmas_with [cancel_type_definition, OF m1.S_ne,
cancel_type_definition, OF m2.S_ne,
folded subset_iff' top_set_def,
simplified pred_fun_def,
simplified]:
linear_0 = lt_linear_0
and linear_add = lt_linear_add
and linear_scale = lt_linear_scale
and linear_neg = lt_linear_neg
and linear_diff = lt_linear_diff
and linear_sum = lt_linear_sum
and linear_inj_on_iff_eq_0 = lt_linear_inj_on_iff_eq_0
and linear_inj_iff_eq_0 = lt_linear_inj_iff_eq_0
and linear_subspace_image = lt_linear_subspace_image
and linear_subspace_vimage = lt_linear_subspace_vimage
and linear_subspace_kernel = lt_linear_subspace_kernel
and linear_span_image = lt_linear_span_image
and linear_dependent_inj_imageD = lt_linear_dependent_inj_imageD
and linear_eq_0_on_span = lt_linear_eq_0_on_span
and linear_independent_injective_image = lt_linear_independent_injective_image
and linear_inj_on_span_independent_image = lt_linear_inj_on_span_independent_image
and linear_inj_on_span_iff_independent_image = lt_linear_inj_on_span_iff_independent_image
and linear_subspace_linear_preimage = lt_linear_subspace_linear_preimage
and linear_spans_image = lt_linear_spans_image
and linear_spanning_surjective_image = lt_linear_spanning_surjective_image
and linear_eq_on_span = lt_linear_eq_on_span
and linear_compose_scale_right = lt_linear_compose_scale_right
and linear_compose_add = lt_linear_compose_add
and linear_zero = lt_linear_zero
and linear_compose_sub = lt_linear_compose_sub
and linear_compose_neg = lt_linear_compose_neg
and linear_compose_scale = lt_linear_compose_scale
and linear_indep_image_lemma = lt_linear_indep_image_lemma
and linear_eq_on = lt_linear_eq_on
and linear_compose_sum = lt_linear_compose_sum
and linear_independent_extend_subspace = lt_linear_independent_extend_subspace
and linear_independent_extend = lt_linear_independent_extend
and linear_exists_left_inverse_on = lt_linear_exists_left_inverse_on
and linear_exists_right_inverse_on = lt_linear_exists_right_inverse_on
and linear_inj_on_left_inverse = lt_linear_inj_on_left_inverse
and linear_injective_left_inverse = lt_linear_injective_left_inverse
and linear_surj_right_inverse = lt_linear_surj_right_inverse
and linear_surjective_right_inverse = lt_linear_surjective_right_inverse
and finite_basis_to_basis_subspace_isomorphism = lt_finite_basis_to_basis_subspace_isomorphism
end
context finite_dimensional_vector_space_pair_1_on begin
context includes lifting_syntax
notes [transfer_rule del] = Collect_transfer
assumes
"∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S1"
"∃(Rep::'t ⇒ 'c) (Abs::'c ⇒ 't). type_definition Rep Abs S2" begin
interpretation local_typedef_finite_dimensional_vector_space_pair_1 S1 scale1 Basis1 "TYPE('s)" S2 scale2 "TYPE('t)" by unfold_locales fact+
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'e 'f,
OF lt2.type.ab_group_add_axioms lt1.type.ab_group_add_axioms type_finite_dimensional_vector_space_pair_1_on_with,
folded lt1.dim_S_def lt2.dim_S_def,
untransferred,
var_simplified implicit_ab_group_add]:
lt_dim_image_eq = finite_dimensional_vector_space_pair_1.dim_image_eq
and lt_dim_image_le = finite_dimensional_vector_space_pair_1.dim_image_le
end
lemmas_with [cancel_type_definition, OF vs1.S_ne,
cancel_type_definition, OF vs2.S_ne,
folded subset_iff' top_set_def,
simplified pred_fun_def,
simplified]:
dim_image_eq = lt_dim_image_eq
and dim_image_le = lt_dim_image_le
end
context finite_dimensional_vector_space_pair_on begin
context includes lifting_syntax
notes [transfer_rule del] = Collect_transfer
assumes
"∃(Rep::'s ⇒ 'b) (Abs::'b ⇒ 's). type_definition Rep Abs S1"
"∃(Rep::'t ⇒ 'c) (Abs::'c ⇒ 't). type_definition Rep Abs S2" begin
interpretation local_typedef_finite_dimensional_vector_space_pair S1 scale1 Basis1 "TYPE('s)" S2 scale2 Basis2 "TYPE('t)" by unfold_locales fact+
lemmas_with [var_simplified explicit_ab_group_add,
unoverload_type 'e 'f,
OF lt2.type.ab_group_add_axioms lt1.type.ab_group_add_axioms type_finite_dimensional_vector_space_pair_on_with,
folded lt1.dim_S_def lt2.dim_S_def,
untransferred,
var_simplified implicit_ab_group_add]:
lt_linear_surjective_imp_injective = finite_dimensional_vector_space_pair.linear_surjective_imp_injective
and lt_linear_injective_imp_surjective = finite_dimensional_vector_space_pair.linear_injective_imp_surjective
and lt_linear_injective_isomorphism = finite_dimensional_vector_space_pair.linear_injective_isomorphism
and lt_linear_surjective_isomorphism = finite_dimensional_vector_space_pair.linear_surjective_isomorphism
and lt_basis_to_basis_subspace_isomorphism = finite_dimensional_vector_space_pair.basis_to_basis_subspace_isomorphism
and lt_subspace_isomorphism = finite_dimensional_vector_space_pair.subspace_isomorphism
end
lemmas_with [cancel_type_definition, OF vs1.S_ne,
cancel_type_definition, OF vs2.S_ne,
folded subset_iff' top_set_def,
simplified pred_fun_def,
simplified]:
linear_surjective_imp_injective = lt_linear_surjective_imp_injective
and linear_injective_imp_surjective = lt_linear_injective_imp_surjective
and linear_injective_isomorphism = lt_linear_injective_isomorphism
and linear_surjective_isomorphism = lt_linear_surjective_isomorphism
and basis_to_basis_subspace_isomorphism = lt_basis_to_basis_subspace_isomorphism
and subspace_isomorphism = lt_subspace_isomorphism
end
end