let n be Nat; :: thesis: for A being convex Subset of (TOP-REAL n) st A is compact & not A is boundary holds
for h being continuous Function of ((TOP-REAL n) | A),((TOP-REAL n) | A) holds h is with_fixpoint
set T = TOP-REAL n;
consider I being affinely-independent Subset of (TOP-REAL n) such that
{} (TOP-REAL n) c= I and
I c= [#] (TOP-REAL n) and
A1: Affin I = Affin ([#] (TOP-REAL n)) by RLAFFIN1:60;
reconsider TT = TOP-REAL n as non empty RLSStruct ;
reconsider i = I as Subset of TT ;
set II = Int i;
A2: not I is empty by A1;
then A3: not Int i is empty by RLAFFIN2:20;
reconsider ii = Int i as Subset of (TOP-REAL n) ;
A4: Int ii c= Int (conv I) by RLAFFIN2:5, TOPS_1:19;
let A be convex Subset of (TOP-REAL n); :: thesis: ( A is compact & not A is boundary implies for h being continuous Function of ((TOP-REAL n) | A),((TOP-REAL n) | A) holds h is with_fixpoint )
assume A5: ( A is compact & not A is boundary ) ; :: thesis: for h being continuous Function of ((TOP-REAL n) | A),((TOP-REAL n) | A) holds h is with_fixpoint
A6: not A is empty by A5;
let h be continuous Function of ((TOP-REAL n) | A),((TOP-REAL n) | A); :: thesis: h is with_fixpoint
[#] (TOP-REAL n) is Affine by RUSUB_4:22;
then ( dim (TOP-REAL n) = n & Affin ([#] (TOP-REAL n)) = [#] (TOP-REAL n) ) by RLAFFIN1:50, RLAFFIN3:4;
then A7: card I = n + 1 by A1, RLAFFIN3:6;
then ii is open by RLAFFIN3:33;
then not conv I is boundary by A3, A4, TOPS_1:23;
then consider f being Function of ((TOP-REAL n) | A),((TOP-REAL n) | (conv I)) such that
A8: f is being_homeomorphism and
f .: (Fr A) = Fr (conv I) by A5, Th7;
reconsider fhf = f * (h * (f ")) as Function of ((TOP-REAL n) | (conv I)),((TOP-REAL n) | (conv I)) by A6;
f " is continuous by A8, TOPS_2:def 5;
then consider p being Point of (TOP-REAL n) such that
A9: p in dom fhf and
A10: fhf . p = p by A7, A2, A8, A6, SIMPLEX2:23;
A11: p in dom (h * (f ")) by A9, FUNCT_1:11;
reconsider F = f as Function ;
A12: rng f = [#] ((TOP-REAL n) | (conv I)) by A8, TOPS_2:def 5;
A13: f " = F " by A8, TOPS_2:def 4;
consider x being object such that
A14: x in dom F and
A15: F . x = p by A12, A9, FUNCT_1:def 3;
(F ") . p = x by A8, A14, A15, FUNCT_1:34;
then (h * (f ")) . p = h . x by A11, A13, FUNCT_1:12;
then A16: p = f . (h . x) by A9, A10, FUNCT_1:12;
A17: dom f = [#] ((TOP-REAL n) | A) by A8, TOPS_2:def 5;
then A18: x in dom h by A14, FUNCT_2:52;
then h . x in rng h by FUNCT_1:def 3;
then h . x = x by A8, A17, A14, A15, A16, FUNCT_1:def 4;
then x is_a_fixpoint_of h by A18, ABIAN:def 3;
hence h is with_fixpoint by ABIAN:def 5; :: thesis: verum