let p1, p2 be Point of (TOP-REAL 2); :: thesis:
let P be non empty compact Subset of (TOP-REAL 2); :: thesis:
assume A1: ( P = { p where p is Point of (TOP-REAL 2) : |.p.| = 1 } & p1 in P & p2 in P & p1 `2 <= 0 & p2 `2 <= 0 & p2 <> W-min P & p1 `1 >= p2 `1 ) ; :: thesis:
then A2: P is being_simple_closed_curve by JGRAPH_3:36;
then A3: Lower_Arc P is_an_arc_of E-max P, W-min P by JORDAN6:def 9;
set P4 = Lower_Arc P;
A4: ( Lower_Arc P is_an_arc_of E-max P, W-min P & (Upper_Arc P) /\ (Lower_Arc P) = {(W-min P),(E-max P)} & (Upper_Arc P) \/ (Lower_Arc P) = P & (First_Point (Upper_Arc P),(W-min P),(E-max P),(Vertical_Line (((W-bound P) + (E-bound P)) / 2))) `2 > (Last_Point (Lower_Arc P),(E-max P),(W-min P),(Vertical_Line (((W-bound P) + (E-bound P)) / 2))) `2 ) by A2, JORDAN6:def 9;
A5: Lower_Arc P = { p where p is Point of (TOP-REAL 2) : ( p in P & p `2 <= 0 ) } by A1, Th38;
then A6: p1 in Lower_Arc P by A1;
A7: p2 in Lower_Arc P by A1, A5;
A8: W-min P = |[(- 1),0 ]| by A1, Th32;
A9: E-max P = |[1,0 ]| by A1, Th33;
for g being Function of I[01] ,((TOP-REAL 2) | (Lower_Arc P))
for s1, s2 being Real st g is being_homeomorphism & g . 0 = E-max P & g . 1 = W-min P & g . s1 = p1 & 0 <= s1 & s1 <= 1 & g . s2 = p2 & 0 <= s2 & s2 <= 1 holds
s1 <= s2

proof

let g be Function of I[01] ,((TOP-REAL 2) | (Lower_Arc P)); :: thesis:
let s1, s2 be Real; :: thesis:
assume A10: ( g is being_homeomorphism & g . 0 = E-max P & g . 1 = W-min P & g . s1 = p1 & 0 <= s1 & s1 <= 1 & g . s2 = p2 & 0 <= s2 & s2 <= 1 ) ; :: thesis:
then A11: dom g = [#] I[01] by TOPS_2:def 5
.= [.0 ,1.] by BORSUK_1:83 ;
reconsider g0 = proj1 as Function of (TOP-REAL 2),R^1 by TOPMETR:24;
set K0 = Lower_Arc P;
reconsider g2 = g0 | (Lower_Arc P) as Function of ((TOP-REAL 2) | (Lower_Arc P)),R^1 by PRE_TOPC:30;
reconsider g3 = g2 as continuous Function of ((TOP-REAL 2) | (Lower_Arc P)),(Closed-Interval-TSpace (- 1),1) by A1, Lm4;
E-max P in {(W-min P),(E-max P)} by TARSKI:def 2;
then A12: E-max P in Lower_Arc P by A4, XBOOLE_0:def 4;
W-min P in {(W-min P),(E-max P)} by TARSKI:def 2;
then A13: W-min P in Lower_Arc P by A4, XBOOLE_0:def 4;
A14: dom g3 = [#] ((TOP-REAL 2) | (Lower_Arc P)) by FUNCT_2:def 1;
A15: rng g3 = [#] (Closed-Interval-TSpace (- 1),1) by A1, Lm4;
A16: g3 is one-to-one by A1, Lm4;
( not Lower_Arc P is empty & Lower_Arc P is compact ) by A3, JORDAN5A:1;
then A17: (TOP-REAL 2) | (Lower_Arc P) is compact ;
Closed-Interval-TSpace (- 1),1 = TopSpaceMetr (Closed-Interval-MSpace (- 1),1) by TOPMETR:def 8;
then Closed-Interval-TSpace (- 1),1 is T_2 by PCOMPS_1:38;
then A18: g3 is being_homeomorphism by A14, A15, A16, A17, COMPTS_1:26;
reconsider h = g3 * g as Function of (Closed-Interval-TSpace 0 ,1),(Closed-Interval-TSpace (- 1),1) by TOPMETR:27;
A19: h is being_homeomorphism by A10, A18, TOPMETR:27, TOPS_2:71;
A20: 0 in dom g by A11, XXREAL_1:1;
A21: 1 in dom g by A11, XXREAL_1:1;
A22: s1 in [.0 ,1.] by A10, XXREAL_1:1;
A23: s2 in [.0 ,1.] by A10, XXREAL_1:1;
A24: - 1 = |[(- 1),0 ]| `1 by EUCLID:56
.= proj1 . |[(- 1),0 ]| by PSCOMP_1:def 28
.= g3 . |[(- 1),0 ]| by A8, A13, FUNCT_1:72
.= h . 1 by A8, A10, A21, FUNCT_1:23 ;
A25: 1 = |[1,0 ]| `1 by EUCLID:56
.= proj1 . |[1,0 ]| by PSCOMP_1:def 28
.= g3 . |[1,0 ]| by A9, A12, FUNCT_1:72
.= h . 0 by A9, A10, A20, FUNCT_1:23 ;
A26: p1 `1 = g0 . p1 by PSCOMP_1:def 28
.= g3 . p1 by A6, FUNCT_1:72
.= h . s1 by A10, A11, A22, FUNCT_1:23 ;
p2 `1 = g0 . p2 by PSCOMP_1:def 28
.= g3 . p2 by A7, FUNCT_1:72
.= h . s2 by A10, A11, A23, FUNCT_1:23 ;
hence s1 <= s2 by A1, A19, A22, A23, A24, A25, A26, Th12; :: thesis:

end;

then ( p1 in Lower_Arc P & p2 in Lower_Arc P & not p2 = W-min P & LE p1,p2, Lower_Arc P, E-max P, W-min P ) by A1, A6, A7, JORDAN5C:def 3;
hence LE p1,p2,P by JORDAN6:def 10; :: thesis: