set f2 = T --> (R^1 1);
set f1 = T --> (R^1 0 );
let C, D be non empty closed Subset of T; :: thesis: ( C misses D implies ex f being continuous Function of T,R^1 st
( f .: C = {0 } & f .: D = {1} ) )
assume A2: C misses D ; :: thesis: ex f being continuous Function of T,R^1 st
( f .: C = {0 } & f .: D = {1} )
set g1 = (T --> (R^1 0 )) | (T | C);
set g2 = (T --> (R^1 1)) | (T | D);
set f = ((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D));
A3: the carrier of (T | D) = D by PRE_TOPC:29;
(T --> (R^1 1)) | (T | D) = (T --> (R^1 1)) | the carrier of (T | D) by TMAP_1:def 3;
then A4: rng ((T --> (R^1 1)) | (T | D)) c= rng (T --> (R^1 1)) by RELAT_1:99;
(T --> (R^1 0 )) | (T | C) = (T --> (R^1 0 )) | the carrier of (T | C) by TMAP_1:def 3;
then rng ((T --> (R^1 0 )) | (T | C)) c= rng (T --> (R^1 0 )) by RELAT_1:99;
then A5: (rng ((T --> (R^1 0 )) | (T | C))) \/ (rng ((T --> (R^1 1)) | (T | D))) c= (rng (T --> (R^1 0 ))) \/ (rng (T --> (R^1 1))) by A4, XBOOLE_1:13;
A6: T --> (R^1 0 ) = the carrier of T --> 0 by TOPREALB:def 2;
then A7: rng (T --> (R^1 0 )) = {0 } by FUNCOP_1:14;
A8: T --> (R^1 1) = the carrier of T --> 1 by TOPREALB:def 2;
then A9: rng (T --> (R^1 1)) = {1} by FUNCOP_1:14;
A10: the carrier of (T | C) = C by PRE_TOPC:29;
then A11: T | C misses T | D by A2, A3, TSEP_1:def 3;
then rng (((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D))) c= (rng ((T --> (R^1 0 )) | (T | C))) \/ (rng ((T --> (R^1 1)) | (T | D))) by Th15;
then A12: rng (((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D))) c= (rng (T --> (R^1 0 ))) \/ (rng (T --> (R^1 1))) by A5, XBOOLE_1:1;
A13: rng (((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D))) c= [.(- 1),1.] the carrier of (T | (C \/ D)) = C \/ D by PRE_TOPC:29;
then A14: T | (C \/ D) = (T | C) union (T | D) by A10, A3, TSEP_1:def 2;
A15: (T --> (R^1 1)) .: D = {1} A18: D c= D ;
A19: (T --> (R^1 0 )) .: C = {0 } A22: C \/ D is closed by TOPS_1:36;
the carrier of (Closed-Interval-TSpace (- 1),1) = [.(- 1),1.] by TOPMETR:25;
then reconsider h = ((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D)) as Function of (T | (C \/ D)),(Closed-Interval-TSpace (- 1),1) by A14, A13, FUNCT_2:8;
( (T --> (R^1 0 )) | (T | C) is continuous & (T --> (R^1 1)) | (T | D) is continuous ) by TMAP_1:68;
then ((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D)) is continuous Function of ((T | C) union (T | D)),R^1 by A11, TMAP_1:148;
then h is continuous by A14, PRE_TOPC:57;
then consider g being continuous Function of T,(Closed-Interval-TSpace (- 1),1) such that
A23: g | (C \/ D) = ((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D)) by A1, A22;
reconsider F = g as continuous Function of T,R^1 by PRE_TOPC:56, TOPREALA:28;
take F ; :: thesis: ( F .: C = {0 } & F .: D = {1} )
A24: C c= C ;
thus F .: C = (((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D))) .: C by A23, FUNCT_2:174, XBOOLE_1:7
.= ((T --> (R^1 0 )) | (T | C)) .: C by A10, A11, A24, Th16
.= ((T --> (R^1 0 )) | C) .: C by A10, TMAP_1:def 3
.= {0 } by A19, RELAT_1:162 ; :: thesis: F .: D = {1}
thus F .: D = (((T --> (R^1 0 )) | (T | C)) union ((T --> (R^1 1)) | (T | D))) .: D by A23, FUNCT_2:174, XBOOLE_1:7
.= ((T --> (R^1 1)) | (T | D)) .: D by A3, A11, A18, Th16
.= ((T --> (R^1 1)) | D) .: D by A3, TMAP_1:def 3
.= {1} by A15, RELAT_1:162 ; :: thesis: verum