let A be finite Subset of REAL; SgmX (RealOrd,A) is increasing
set IT = SgmX (RealOrd,A);
let n, m be Nat; SEQM_3:def 1 ( not n in dom (SgmX (RealOrd,A)) or not m in dom (SgmX (RealOrd,A)) or m <= n or not (SgmX (RealOrd,A)) . m <= (SgmX (RealOrd,A)) . n )
assume that
A1:
( n in dom (SgmX (RealOrd,A)) & m in dom (SgmX (RealOrd,A)) )
and
A2:
n < m
; not (SgmX (RealOrd,A)) . m <= (SgmX (RealOrd,A)) . n
A3:
RealOrd linearly_orders A
by Th6, ORDERS_1:38;
( (SgmX (RealOrd,A)) /. n = (SgmX (RealOrd,A)) . n & (SgmX (RealOrd,A)) /. m = (SgmX (RealOrd,A)) . m )
by A1, PARTFUN1:def 6;
then
[((SgmX (RealOrd,A)) . n),((SgmX (RealOrd,A)) . m)] in RealOrd
by A1, A2, A3, PRE_POLY:def 2;
then A4:
(SgmX (RealOrd,A)) . n <= (SgmX (RealOrd,A)) . m
by Th4;
SgmX (RealOrd,A) is one-to-one
by Th6, ORDERS_1:38, PRE_POLY:10;
then
(SgmX (RealOrd,A)) . n <> (SgmX (RealOrd,A)) . m
by A1, A2, FUNCT_1:def 4;
hence
not (SgmX (RealOrd,A)) . m <= (SgmX (RealOrd,A)) . n
by A4, XXREAL_0:1; verum