(* Title: HOL/Real/HahnBanach/FunctionNorm.thy
ID: $Id$
Author: Gertrud Bauer, TU Munich
*)
theory FunctionNorm = NormedSpace + FunctionOrder:;
constdefs
is_continous :: "['a set, 'a => real, 'a => real] => bool"
"is_continous V norm f == (is_linearform V f
& (EX c. ALL x:V. rabs (f x) <= c * norm x))";
lemma lipschitz_continousI [intro]:
"[| is_linearform V f; !! x. x:V ==> rabs (f x) <= c * norm x |]
==> is_continous V norm f";
proof (unfold is_continous_def, intro exI conjI ballI);
assume r: "!! x. x:V ==> rabs (f x) <= c * norm x";
fix x; assume "x:V"; show "rabs (f x) <= c * norm x"; by (rule r);
qed;
lemma continous_linearform [intro!!]: "is_continous V norm f ==> is_linearform V f";
by (unfold is_continous_def) force;
lemma continous_bounded [intro!!]:
"is_continous V norm f ==> EX c. ALL x:V. rabs (f x) <= c * norm x";
by (unfold is_continous_def) force;
constdefs
B:: "[ 'a set, 'a => real, 'a => real ] => real set"
"B V norm f == {z. z = 0r | (EX x:V. x ~= <0> & z = rabs (f x) * rinv (norm (x)))}";
constdefs
function_norm :: " ['a set, 'a => real, 'a => real] => real"
"function_norm V norm f ==
Sup UNIV (B V norm f)";
constdefs
is_function_norm :: " ['a set, 'a => real, 'a => real] => real => bool"
"is_function_norm V norm f fn ==
is_Sup UNIV (B V norm f) fn";
lemma B_not_empty: "0r : B V norm f";
by (unfold B_def, force);
lemma ex_fnorm [intro!!]:
"[| is_normed_vectorspace V norm; is_continous V norm f|]
==> is_function_norm V norm f (function_norm V norm f)";
proof (unfold function_norm_def is_function_norm_def is_continous_def Sup_def, elim conjE,
rule selectI2EX);
assume "is_normed_vectorspace V norm";
assume "is_linearform V f" and e: "EX c. ALL x:V. rabs (f x) <= c * norm x";
show "EX a. is_Sup UNIV (B V norm f) a";
proof (unfold is_Sup_def, rule reals_complete);
show "EX X. X : B V norm f";
proof (intro exI);
show "0r : (B V norm f)"; by (unfold B_def, force);
qed;
from e; show "EX Y. isUb UNIV (B V norm f) Y";
proof;
fix c; assume a: "ALL x:V. rabs (f x) <= c * norm x";
def b == "max c 0r";
show "EX Y. isUb UNIV (B V norm f) Y";
proof (intro exI isUbI setleI ballI, unfold B_def,
elim CollectE disjE bexE conjE);
fix x y; assume "x:V" "x ~= <0>" "y = rabs (f x) * rinv (norm x)";
from a; have le: "rabs (f x) <= c * norm x"; ..;
have "y = rabs (f x) * rinv (norm x)";.;
also; from _ le; have "... <= c * norm x * rinv (norm x)";
proof (rule real_mult_le_le_mono2);
show "0r <= rinv (norm x)";
proof (rule less_imp_le);
show "0r < rinv (norm x)";
proof (rule real_rinv_gt_zero);
show "0r < norm x"; ..;
qed;
qed;
(*** or: by (rule less_imp_le, rule real_rinv_gt_zero, rule normed_vs_norm_gt_zero); ***)
qed;
also; have "... = c * (norm x * rinv (norm x))"; by (rule real_mult_assoc);
also; have "(norm x * rinv (norm x)) = 1r";
proof (rule real_mult_inv_right);
show "norm x ~= 0r";
proof (rule not_sym);
show "0r ~= norm x";
proof (rule lt_imp_not_eq);
show "0r < norm x"; ..;
qed;
qed;
(*** or: by (rule not_sym, rule lt_imp_not_eq, rule normed_vs_norm_gt_zero); ***)
qed;
also; have "c * ... = c"; by (simp!);
also; have "... <= b"; by (simp! add: le_max1);
finally; show "y <= b"; .;
next;
fix y; assume "y = 0r"; show "y <= b"; by (simp! add: le_max2);
qed simp;
qed;
qed;
qed;
lemma fnorm_ge_zero [intro!!]: "[| is_continous V norm f; is_normed_vectorspace V norm|]
==> 0r <= function_norm V norm f";
proof -;
assume c: "is_continous V norm f" and n: "is_normed_vectorspace V norm";
have "is_function_norm V norm f (function_norm V norm f)"; ..;
hence s: "is_Sup UNIV (B V norm f) (function_norm V norm f)";
by (simp add: is_function_norm_def);
show ?thesis;
proof (unfold function_norm_def, rule sup_ub1);
show "ALL x:(B V norm f). 0r <= x";
proof (intro ballI, unfold B_def, elim CollectE bexE conjE disjE);
fix x r; assume "x : V" "x ~= <0>"
"r = rabs (f x) * rinv (norm x)";
show "0r <= r";
proof (simp!, rule real_le_mult_order);
show "0r <= rabs (f x)"; by (simp! only: rabs_ge_zero);
show "0r <= rinv (norm x)";
proof (rule less_imp_le);
show "0r < rinv (norm x)";
proof (rule real_rinv_gt_zero);
show "0r < norm x"; ..;
qed;
qed;
qed;
qed (simp!);
from ex_fnorm [OF n c]; show "is_Sup UNIV (B V norm f) (Sup UNIV (B V norm f))";
by (simp! add: is_function_norm_def function_norm_def);
show "0r : B V norm f"; by (rule B_not_empty);
qed;
qed;
lemma norm_fx_le_norm_f_norm_x:
"[| is_normed_vectorspace V norm; x:V; is_continous V norm f |]
==> rabs (f x) <= (function_norm V norm f) * norm x";
proof -;
assume "is_normed_vectorspace V norm" "x:V" and c: "is_continous V norm f";
have v: "is_vectorspace V"; ..;
assume "x:V";
show "?thesis";
proof (rule case [of "x = <0>"]);
assume "x ~= <0>";
show "?thesis";
proof -;
have n: "0r <= norm x"; ..;
have le: "rabs (f x) * rinv (norm x) <= function_norm V norm f";
proof (unfold function_norm_def, rule sup_ub);
from ex_fnorm [OF _ c]; show "is_Sup UNIV (B V norm f) (Sup UNIV (B V norm f))";
by (simp! add: is_function_norm_def function_norm_def);
show "rabs (f x) * rinv (norm x) : B V norm f";
by (unfold B_def, intro CollectI disjI2 bexI [of _ x] conjI, simp);
qed;
have "rabs (f x) = rabs (f x) * 1r"; by (simp!);
also; have "1r = rinv (norm x) * norm x";
proof (rule real_mult_inv_left [RS sym]);
show "norm x ~= 0r";
proof (rule lt_imp_not_eq[RS not_sym]);
show "0r < norm x"; ..;
qed;
qed;
also; have "rabs (f x) * ... = rabs (f x) * rinv (norm x) * norm x";
by (simp! add: real_mult_assoc [of "rabs (f x)"]);
also; have "rabs (f x) * rinv (norm x) * norm x <= function_norm V norm f * norm x";
by (rule real_mult_le_le_mono2 [OF n le]);
finally; show "rabs (f x) <= function_norm V norm f * norm x"; .;
qed;
next;
assume "x = <0>";
then; show "?thesis";
proof -;
have "rabs (f x) = rabs (f <0>)"; by (simp!);
also; from v continous_linearform; have "f <0> = 0r"; ..;
also; note rabs_zero;
also; have" 0r <= function_norm V norm f * norm x";
proof (rule real_le_mult_order);
show "0r <= function_norm V norm f"; ..;
show "0r <= norm x"; ..;
qed;
finally; show "rabs (f x) <= function_norm V norm f * norm x"; .;
qed;
qed;
qed;
lemma fnorm_le_ub:
"[| is_normed_vectorspace V norm; is_continous V norm f;
ALL x:V. rabs (f x) <= c * norm x; 0r <= c |]
==> function_norm V norm f <= c";
proof (unfold function_norm_def);
assume "is_normed_vectorspace V norm";
assume c: "is_continous V norm f";
assume fb: "ALL x:V. rabs (f x) <= c * norm x"
and "0r <= c";
show "Sup UNIV (B V norm f) <= c";
proof (rule ub_ge_sup);
from ex_fnorm [OF _ c]; show "is_Sup UNIV (B V norm f) (Sup UNIV (B V norm f))";
by (simp! add: is_function_norm_def function_norm_def);
show "isUb UNIV (B V norm f) c";
proof (intro isUbI setleI ballI);
fix y; assume "y: B V norm f";
thus le: "y <= c";
proof (-, unfold B_def, elim CollectE disjE bexE);
fix x; assume Px: "x ~= <0> & y = rabs (f x) * rinv (norm x)";
assume x: "x : V";
have lt: "0r < norm x"; by (simp! add: normed_vs_norm_gt_zero);
have neq: "norm x ~= 0r";
proof (rule not_sym);
from lt; show "0r ~= norm x";
by (simp! add: order_less_imp_not_eq);
qed;
from lt; have "0r < rinv (norm x)";
by (simp! add: real_rinv_gt_zero);
then; have inv_leq: "0r <= rinv (norm x)"; by (rule less_imp_le);
from Px; have "y = rabs (f x) * rinv (norm x)"; ..;
also; from inv_leq; have "... <= c * norm x * rinv (norm x)";
proof (rule real_mult_le_le_mono2);
from fb x; show "rabs (f x) <= c * norm x"; ..;
qed;
also; have "... <= c";
by (simp add: neq real_mult_assoc);
finally; show ?thesis; .;
next;
assume "y = 0r";
show "y <= c"; by (force!);
qed;
qed force;
qed;
qed;
end;