Theory Subspace

Up to index of Isabelle/HOL/HOL-Complex/HahnBanach

theory Subspace
imports VectorSpace
begin

(*  Title:      HOL/Real/HahnBanach/Subspace.thy
    ID:         $Id: Subspace.thy,v 1.32 2005/06/17 14:13:10 haftmann Exp $
    Author:     Gertrud Bauer, TU Munich
*)

header {* Subspaces *}

theory Subspace imports VectorSpace begin


subsection {* Definition *}

text {*
  A non-empty subset @{text U} of a vector space @{text V} is a
  \emph{subspace} of @{text V}, iff @{text U} is closed under addition
  and scalar multiplication.
*}

locale subspace = var U + var V +
  assumes non_empty [iff, intro]: "U ≠ {}"
    and subset [iff]: "U ⊆ V"
    and add_closed [iff]: "x ∈ U ==> y ∈ U ==> x + y ∈ U"
    and mult_closed [iff]: "x ∈ U ==> a · x ∈ U"

declare vectorspace.intro [intro?] subspace.intro [intro?]

syntax (symbols)
  subspace :: "'a set => 'a set => bool"    (infix "\<unlhd>" 50)

lemma subspace_subset [elim]: "U \<unlhd> V ==> U ⊆ V"
  by (rule subspace.subset)

lemma (in subspace) subsetD [iff]: "x ∈ U ==> x ∈ V"
  using subset by blast

lemma subspaceD [elim]: "U \<unlhd> V ==> x ∈ U ==> x ∈ V"
  by (rule subspace.subsetD)

lemma rev_subspaceD [elim?]: "x ∈ U ==> U \<unlhd> V ==> x ∈ V"
  by (rule subspace.subsetD)

lemma (in subspace) diff_closed [iff]:
  includes vectorspace
  shows "x ∈ U ==> y ∈ U ==> x - y ∈ U"
  by (simp add: diff_eq1 negate_eq1)


text {*
  \medskip Similar as for linear spaces, the existence of the zero
  element in every subspace follows from the non-emptiness of the
  carrier set and by vector space laws.
*}

lemma (in subspace) zero [intro]:
  includes vectorspace
  shows "0 ∈ U"
proof -
  have "U ≠ {}" by (rule U_V.non_empty)
  then obtain x where x: "x ∈ U" by blast
  hence "x ∈ V" .. hence "0 = x - x" by simp
  also have "... ∈ U" by (rule U_V.diff_closed)
  finally show ?thesis .
qed

lemma (in subspace) neg_closed [iff]:
  includes vectorspace
  shows "x ∈ U ==> - x ∈ U"
  by (simp add: negate_eq1)


text {* \medskip Further derived laws: every subspace is a vector space. *}

lemma (in subspace) vectorspace [iff]:
  includes vectorspace
  shows "vectorspace U"
proof
  show "U ≠ {}" ..
  fix x y z assume x: "x ∈ U" and y: "y ∈ U" and z: "z ∈ U"
  fix a b :: real
  from x y show "x + y ∈ U" by simp
  from x show "a · x ∈ U" by simp
  from x y z show "(x + y) + z = x + (y + z)" by (simp add: add_ac)
  from x y show "x + y = y + x" by (simp add: add_ac)
  from x show "x - x = 0" by simp
  from x show "0 + x = x" by simp
  from x y show "a · (x + y) = a · x + a · y" by (simp add: distrib)
  from x show "(a + b) · x = a · x + b · x" by (simp add: distrib)
  from x show "(a * b) · x = a · b · x" by (simp add: mult_assoc)
  from x show "1 · x = x" by simp
  from x show "- x = - 1 · x" by (simp add: negate_eq1)
  from x y show "x - y = x + - y" by (simp add: diff_eq1)
qed


text {* The subspace relation is reflexive. *}

lemma (in vectorspace) subspace_refl [intro]: "V \<unlhd> V"
proof
  show "V ≠ {}" ..
  show "V ⊆ V" ..
  fix x y assume x: "x ∈ V" and y: "y ∈ V"
  fix a :: real
  from x y show "x + y ∈ V" by simp
  from x show "a · x ∈ V" by simp
qed

text {* The subspace relation is transitive. *}

lemma (in vectorspace) subspace_trans [trans]:
  "U \<unlhd> V ==> V \<unlhd> W ==> U \<unlhd> W"
proof
  assume uv: "U \<unlhd> V" and vw: "V \<unlhd> W"
  from uv show "U ≠ {}" by (rule subspace.non_empty)
  show "U ⊆ W"
  proof -
    from uv have "U ⊆ V" by (rule subspace.subset)
    also from vw have "V ⊆ W" by (rule subspace.subset)
    finally show ?thesis .
  qed
  fix x y assume x: "x ∈ U" and y: "y ∈ U"
  from uv and x y show "x + y ∈ U" by (rule subspace.add_closed)
  from uv and x show "!!a. a · x ∈ U" by (rule subspace.mult_closed)
qed


subsection {* Linear closure *}

text {*
  The \emph{linear closure} of a vector @{text x} is the set of all
  scalar multiples of @{text x}.
*}

constdefs
  lin :: "('a::{minus, plus, zero}) => 'a set"
  "lin x ≡ {a · x | a. True}"

lemma linI [intro]: "y = a · x ==> y ∈ lin x"
  by (unfold lin_def) blast

lemma linI' [iff]: "a · x ∈ lin x"
  by (unfold lin_def) blast

lemma linE [elim]:
    "x ∈ lin v ==> (!!a::real. x = a · v ==> C) ==> C"
  by (unfold lin_def) blast


text {* Every vector is contained in its linear closure. *}

lemma (in vectorspace) x_lin_x [iff]: "x ∈ V ==> x ∈ lin x"
proof -
  assume "x ∈ V"
  hence "x = 1 · x" by simp
  also have "… ∈ lin x" ..
  finally show ?thesis .
qed

lemma (in vectorspace) "0_lin_x" [iff]: "x ∈ V ==> 0 ∈ lin x"
proof
  assume "x ∈ V"
  thus "0 = 0 · x" by simp
qed

text {* Any linear closure is a subspace. *}

lemma (in vectorspace) lin_subspace [intro]:
  "x ∈ V ==> lin x \<unlhd> V"
proof
  assume x: "x ∈ V"
  thus "lin x ≠ {}" by (auto simp add: x_lin_x)
  show "lin x ⊆ V"
  proof
    fix x' assume "x' ∈ lin x"
    then obtain a where "x' = a · x" ..
    with x show "x' ∈ V" by simp
  qed
  fix x' x'' assume x': "x' ∈ lin x" and x'': "x'' ∈ lin x"
  show "x' + x'' ∈ lin x"
  proof -
    from x' obtain a' where "x' = a' · x" ..
    moreover from x'' obtain a'' where "x'' = a'' · x" ..
    ultimately have "x' + x'' = (a' + a'') · x"
      using x by (simp add: distrib)
    also have "… ∈ lin x" ..
    finally show ?thesis .
  qed
  fix a :: real
  show "a · x' ∈ lin x"
  proof -
    from x' obtain a' where "x' = a' · x" ..
    with x have "a · x' = (a * a') · x" by (simp add: mult_assoc)
    also have "… ∈ lin x" ..
    finally show ?thesis .
  qed
qed


text {* Any linear closure is a vector space. *}

lemma (in vectorspace) lin_vectorspace [intro]:
    "x ∈ V ==> vectorspace (lin x)"
  by (rule subspace.vectorspace) (rule lin_subspace)


subsection {* Sum of two vectorspaces *}

text {*
  The \emph{sum} of two vectorspaces @{text U} and @{text V} is the
  set of all sums of elements from @{text U} and @{text V}.
*}

instance set :: (plus) plus ..

defs (overloaded)
  sum_def: "U + V ≡ {u + v | u v. u ∈ U ∧ v ∈ V}"

lemma sumE [elim]:
    "x ∈ U + V ==> (!!u v. x = u + v ==> u ∈ U ==> v ∈ V ==> C) ==> C"
  by (unfold sum_def) blast

lemma sumI [intro]:
    "u ∈ U ==> v ∈ V ==> x = u + v ==> x ∈ U + V"
  by (unfold sum_def) blast

lemma sumI' [intro]:
    "u ∈ U ==> v ∈ V ==> u + v ∈ U + V"
  by (unfold sum_def) blast

text {* @{text U} is a subspace of @{text "U + V"}. *}

lemma subspace_sum1 [iff]:
  includes vectorspace U + vectorspace V
  shows "U \<unlhd> U + V"
proof
  show "U ≠ {}" ..
  show "U ⊆ U + V"
  proof
    fix x assume x: "x ∈ U"
    moreover have "0 ∈ V" ..
    ultimately have "x + 0 ∈ U + V" ..
    with x show "x ∈ U + V" by simp
  qed
  fix x y assume x: "x ∈ U" and "y ∈ U"
  thus "x + y ∈ U" by simp
  from x show "!!a. a · x ∈ U" by simp
qed

text {* The sum of two subspaces is again a subspace. *}

lemma sum_subspace [intro?]:
  includes subspace U E + vectorspace E + subspace V E
  shows "U + V \<unlhd> E"
proof
  have "0 ∈ U + V"
  proof
    show "0 ∈ U" ..
    show "0 ∈ V" ..
    show "(0::'a) = 0 + 0" by simp
  qed
  thus "U + V ≠ {}" by blast
  show "U + V ⊆ E"
  proof
    fix x assume "x ∈ U + V"
    then obtain u v where x: "x = u + v" and
      u: "u ∈ U" and v: "v ∈ V" ..
    have "U \<unlhd> E" . with u have "u ∈ E" ..
    moreover have "V \<unlhd> E" . with v have "v ∈ E" ..
    ultimately show "x ∈ E" using x by simp
  qed
  fix x y assume x: "x ∈ U + V" and y: "y ∈ U + V"
  show "x + y ∈ U + V"
  proof -
    from x obtain ux vx where "x = ux + vx" and "ux ∈ U" and "vx ∈ V" ..
    moreover
    from y obtain uy vy where "y = uy + vy" and "uy ∈ U" and "vy ∈ V" ..
    ultimately
    have "ux + uy ∈ U"
      and "vx + vy ∈ V"
      and "x + y = (ux + uy) + (vx + vy)"
      using x y by (simp_all add: add_ac)
    thus ?thesis ..
  qed
  fix a show "a · x ∈ U + V"
  proof -
    from x obtain u v where "x = u + v" and "u ∈ U" and "v ∈ V" ..
    hence "a · u ∈ U" and "a · v ∈ V"
      and "a · x = (a · u) + (a · v)" by (simp_all add: distrib)
    thus ?thesis ..
  qed
qed

text{* The sum of two subspaces is a vectorspace. *}

lemma sum_vs [intro?]:
    "U \<unlhd> E ==> V \<unlhd> E ==> vectorspace E ==> vectorspace (U + V)"
  by (rule subspace.vectorspace) (rule sum_subspace)


subsection {* Direct sums *}

text {*
  The sum of @{text U} and @{text V} is called \emph{direct}, iff the
  zero element is the only common element of @{text U} and @{text
  V}. For every element @{text x} of the direct sum of @{text U} and
  @{text V} the decomposition in @{text "x = u + v"} with
  @{text "u ∈ U"} and @{text "v ∈ V"} is unique.
*}

lemma decomp:
  includes vectorspace E + subspace U E + subspace V E
  assumes direct: "U ∩ V = {0}"
    and u1: "u1 ∈ U" and u2: "u2 ∈ U"
    and v1: "v1 ∈ V" and v2: "v2 ∈ V"
    and sum: "u1 + v1 = u2 + v2"
  shows "u1 = u2 ∧ v1 = v2"
proof
  have U: "vectorspace U" by (rule subspace.vectorspace)
  have V: "vectorspace V" by (rule subspace.vectorspace)
  from u1 u2 v1 v2 and sum have eq: "u1 - u2 = v2 - v1"
    by (simp add: add_diff_swap)
  from u1 u2 have u: "u1 - u2 ∈ U"
    by (rule vectorspace.diff_closed [OF U])
  with eq have v': "v2 - v1 ∈ U" by (simp only:)
  from v2 v1 have v: "v2 - v1 ∈ V"
    by (rule vectorspace.diff_closed [OF V])
  with eq have u': " u1 - u2 ∈ V" by (simp only:)

  show "u1 = u2"
  proof (rule add_minus_eq)
    show "u1 ∈ E" ..
    show "u2 ∈ E" ..
    from u u' and direct show "u1 - u2 = 0" by force
  qed
  show "v1 = v2"
  proof (rule add_minus_eq [symmetric])
    show "v1 ∈ E" ..
    show "v2 ∈ E" ..
    from v v' and direct show "v2 - v1 = 0" by force
  qed
qed

text {*
  An application of the previous lemma will be used in the proof of
  the Hahn-Banach Theorem (see page \pageref{decomp-H-use}): for any
  element @{text "y + a · x0"} of the direct sum of a
  vectorspace @{text H} and the linear closure of @{text "x0"}
  the components @{text "y ∈ H"} and @{text a} are uniquely
  determined.
*}

lemma decomp_H':
  includes vectorspace E + subspace H E
  assumes y1: "y1 ∈ H" and y2: "y2 ∈ H"
    and x': "x' ∉ H"  "x' ∈ E"  "x' ≠ 0"
    and eq: "y1 + a1 · x' = y2 + a2 · x'"
  shows "y1 = y2 ∧ a1 = a2"
proof
  have c: "y1 = y2 ∧ a1 · x' = a2 · x'"
  proof (rule decomp)
    show "a1 · x' ∈ lin x'" ..
    show "a2 · x' ∈ lin x'" ..
    show "H ∩ lin x' = {0}"
    proof
      show "H ∩ lin x' ⊆ {0}"
      proof
        fix x assume x: "x ∈ H ∩ lin x'"
        then obtain a where xx': "x = a · x'"
          by blast
        have "x = 0"
        proof cases
          assume "a = 0"
          with xx' and x' show ?thesis by simp
        next
          assume a: "a ≠ 0"
          from x have "x ∈ H" ..
          with xx' have "inverse a · a · x' ∈ H" by simp
          with a and x' have "x' ∈ H" by (simp add: mult_assoc2)
          thus ?thesis by contradiction
        qed
        thus "x ∈ {0}" ..
      qed
      show "{0} ⊆ H ∩ lin x'"
      proof -
        have "0 ∈ H" ..
        moreover have "0 ∈ lin x'" ..
        ultimately show ?thesis by blast
      qed
    qed
    show "lin x' \<unlhd> E" ..
  qed
  thus "y1 = y2" ..
  from c have "a1 · x' = a2 · x'" ..
  with x' show "a1 = a2" by (simp add: mult_right_cancel)
qed

text {*
  Since for any element @{text "y + a · x'"} of the direct sum of a
  vectorspace @{text H} and the linear closure of @{text x'} the
  components @{text "y ∈ H"} and @{text a} are unique, it follows from
  @{text "y ∈ H"} that @{text "a = 0"}.
*}

lemma decomp_H'_H:
  includes vectorspace E + subspace H E
  assumes t: "t ∈ H"
    and x': "x' ∉ H"  "x' ∈ E"  "x' ≠ 0"
  shows "(SOME (y, a). t = y + a · x' ∧ y ∈ H) = (t, 0)"
proof (rule, simp_all only: split_paired_all split_conv)
  from t x' show "t = t + 0 · x' ∧ t ∈ H" by simp
  fix y and a assume ya: "t = y + a · x' ∧ y ∈ H"
  have "y = t ∧ a = 0"
  proof (rule decomp_H')
    from ya x' show "y + a · x' = t + 0 · x'" by simp
    from ya show "y ∈ H" ..
  qed
  with t x' show "(y, a) = (y + a · x', 0)" by simp
qed

text {*
  The components @{text "y ∈ H"} and @{text a} in @{text "y + a · x'"}
  are unique, so the function @{text h'} defined by
  @{text "h' (y + a · x') = h y + a · ξ"} is definite.
*}

lemma h'_definite:
  includes var H
  assumes h'_def:
    "h' ≡ (λx. let (y, a) = SOME (y, a). (x = y + a · x' ∧ y ∈ H)
                in (h y) + a * xi)"
    and x: "x = y + a · x'"
  includes vectorspace E + subspace H E
  assumes y: "y ∈ H"
    and x': "x' ∉ H"  "x' ∈ E"  "x' ≠ 0"
  shows "h' x = h y + a * xi"
proof -
  from x y x' have "x ∈ H + lin x'" by auto
  have "∃!p. (λ(y, a). x = y + a · x' ∧ y ∈ H) p" (is "∃!p. ?P p")
  proof
    from x y show "∃p. ?P p" by blast
    fix p q assume p: "?P p" and q: "?P q"
    show "p = q"
    proof -
      from p have xp: "x = fst p + snd p · x' ∧ fst p ∈ H"
        by (cases p) simp
      from q have xq: "x = fst q + snd q · x' ∧ fst q ∈ H"
        by (cases q) simp
      have "fst p = fst q ∧ snd p = snd q"
      proof (rule decomp_H')
        from xp show "fst p ∈ H" ..
        from xq show "fst q ∈ H" ..
        from xp and xq show "fst p + snd p · x' = fst q + snd q · x'"
          by simp
        apply_end assumption+
      qed
      thus ?thesis by (cases p, cases q) simp
    qed
  qed
  hence eq: "(SOME (y, a). x = y + a · x' ∧ y ∈ H) = (y, a)"
    by (rule some1_equality) (simp add: x y)
  with h'_def show "h' x = h y + a * xi" by (simp add: Let_def)
qed

end

Definition

lemma subspace_subset:

  subspace U V ==> UV

lemma subsetD:

  [| subspace U V; xU |] ==> xV

lemma subspaceD:

  [| subspace U V; xU |] ==> xV

lemma rev_subspaceD:

  [| xU; subspace U V |] ==> xV

lemma diff_closed:

  [| subspace U V; vectorspace V; xU; yU |] ==> x - yU

lemma zero:

  [| subspace U V; vectorspace V |] ==> (0::'a) ∈ U

lemma neg_closed:

  [| subspace U V; vectorspace V; xU |] ==> - xU

lemma vectorspace:

  [| subspace U V; vectorspace V |] ==> vectorspace U

lemma subspace_refl:

  vectorspace V ==> subspace V V

lemma subspace_trans:

  [| vectorspace V; subspace U V; subspace V W |] ==> subspace U W

Linear closure

lemma linI:

  y = a · x ==> y ∈ lin x

lemma linI':

  a · x ∈ lin x

lemma linE:

  [| x ∈ lin v; !!a. x = a · v ==> C |] ==> C

lemma x_lin_x:

  [| vectorspace V; xV |] ==> x ∈ lin x

lemma 0_lin_x:

  [| vectorspace V; xV |] ==> (0::'a) ∈ lin x

lemma lin_subspace:

  [| vectorspace V; xV |] ==> subspace (lin x) V

lemma lin_vectorspace:

  [| vectorspace V; xV |] ==> vectorspace (lin x)

Sum of two vectorspaces

lemma sumE:

  [| xU + V; !!u v. [| x = u + v; uU; vV |] ==> C |] ==> C

lemma sumI:

  [| uU; vV; x = u + v |] ==> xU + V

lemma sumI':

  [| uU; vV |] ==> u + vU + V

lemma subspace_sum1:

  [| vectorspace U; vectorspace V |] ==> subspace U (U + V)

lemma sum_subspace:

  [| subspace U E; vectorspace E; subspace V E |] ==> subspace (U + V) E

lemma sum_vs:

  [| subspace U E; subspace V E; vectorspace E |] ==> vectorspace (U + V)

Direct sums

lemma decomp:

  [| vectorspace E; subspace U E; subspace V E; UV = {0::'a}; u1.0U;
     u2.0U; v1.0V; v2.0V; u1.0 + v1.0 = u2.0 + v2.0 |]
  ==> u1.0 = u2.0v1.0 = v2.0

lemma decomp_H':

  [| vectorspace E; subspace H E; y1.0H; y2.0H; x'H; x'E;
     x' ≠ (0::'a); y1.0 + a1.0 · x' = y2.0 + a2.0 · x' |]
  ==> y1.0 = y2.0a1.0 = a2.0

lemma decomp_H'_H:

  [| vectorspace E; subspace H E; tH; x'H; x'E; x' ≠ (0::'a) |]
  ==> (SOME (y, a). t = y + a · x'yH) = (t, 0)

lemma h'_definite:

  [| h' == %x. let (y, a) = SOME (y, a). x = y + a · x'yH in h y + a * xi;
     x = y + a · x'; vectorspace E; subspace H E; yH; x'H; x'E;
     x' ≠ (0::'a) |]
  ==> h' x = h y + a * xi