let f be S-Sequence_in_R2; :: thesis: for Q being closed Subset of (TOP-REAL 2) st L~ f meets Q & not f /. 1 in Q holds
(L~ (R_Cut f,(First_Point (L~ f),(f /. 1),(f /. (len f)),Q))) /\ Q = {(First_Point (L~ f),(f /. 1),(f /. (len f)),Q)}
let Q be closed Subset of (TOP-REAL 2); :: thesis: ( L~ f meets Q & not f /. 1 in Q implies (L~ (R_Cut f,(First_Point (L~ f),(f /. 1),(f /. (len f)),Q))) /\ Q = {(First_Point (L~ f),(f /. 1),(f /. (len f)),Q)} )
assume that
A1: L~ f meets Q and
A2: not f /. 1 in Q ; :: thesis: (L~ (R_Cut f,(First_Point (L~ f),(f /. 1),(f /. (len f)),Q))) /\ Q = {(First_Point (L~ f),(f /. 1),(f /. (len f)),Q)}
set p1 = f /. 1;
set p2 = f /. (len f);
set fp = First_Point (L~ f),(f /. 1),(f /. (len f)),Q;
A3: (L~ f) /\ Q is closed by TOPS_1:35;
len f >= 1 + 1 by TOPREAL1:def 10;
then A4: len f > 1 by NAT_1:13;
L~ f is_an_arc_of f /. 1,f /. (len f) by TOPREAL1:31;
then A5: First_Point (L~ f),(f /. 1),(f /. (len f)),Q in (L~ f) /\ Q by A1, A3, JORDAN5C:def 1;
then A6: First_Point (L~ f),(f /. 1),(f /. (len f)),Q in L~ f by XBOOLE_0:def 4;
then A7: 1 <= Index (First_Point (L~ f),(f /. 1),(f /. (len f)),Q),f by JORDAN3:41;
A8: Index (First_Point (L~ f),(f /. 1),(f /. (len f)),Q),f <= len f by A6, JORDAN3:41;
then A9: Index (First_Point (L~ f),(f /. 1),(f /. (len f)),Q),f in dom f by A7, FINSEQ_3:27;
A28: First_Point (L~ f),(f /. 1),(f /. (len f)),Q in Q by A5, XBOOLE_0:def 4;
1 in dom f by A4, FINSEQ_3:27;
then First_Point (L~ f),(f /. 1),(f /. (len f)),Q <> f . 1 by A2, A28, PARTFUN1:def 8;
then First_Point (L~ f),(f /. 1),(f /. (len f)),Q in L~ (R_Cut f,(First_Point (L~ f),(f /. 1),(f /. (len f)),Q)) by A6, JORDAN5B:23;
then First_Point (L~ f),(f /. 1),(f /. (len f)),Q in (L~ (R_Cut f,(First_Point (L~ f),(f /. 1),(f /. (len f)),Q))) /\ Q by A28, XBOOLE_0:def 4;
hence (L~ (R_Cut f,(First_Point (L~ f),(f /. 1),(f /. (len f)),Q))) /\ Q = {(First_Point (L~ f),(f /. 1),(f /. (len f)),Q)} by A10, ZFMISC_1:39; :: thesis: verum