let Y be set ; :: thesis: for h being PartFunc of REAL,REAL holds
( h | Y is non-increasing iff for r1, r2 being Real st r1 in Y /\ (dom h) & r2 in Y /\ (dom h) & r1 < r2 holds
h . r2 <= h . r1 )
let h be PartFunc of REAL,REAL; :: thesis: ( h | Y is non-increasing iff for r1, r2 being Real st r1 in Y /\ (dom h) & r2 in Y /\ (dom h) & r1 < r2 holds
h . r2 <= h . r1 )
thus ( h | Y is non-increasing implies for r1, r2 being Real st r1 in Y /\ (dom h) & r2 in Y /\ (dom h) & r1 < r2 holds
h . r2 <= h . r1 ) :: thesis: ( ( for r1, r2 being Real st r1 in Y /\ (dom h) & r2 in Y /\ (dom h) & r1 < r2 holds
h . r2 <= h . r1 ) implies h | Y is non-increasing ) assume A8: for r1, r2 being Real st r1 in Y /\ (dom h) & r2 in Y /\ (dom h) & r1 < r2 holds
h . r2 <= h . r1 ; :: thesis: h | Y is non-increasing
let r1 be Real; :: according to RFUNCT_2:def 4 :: thesis: for r2 being Real st r1 in dom (h | Y) & r2 in dom (h | Y) & r1 < r2 holds
(h | Y) . r2 <= (h | Y) . r1
let r2 be Real; :: thesis: ( r1 in dom (h | Y) & r2 in dom (h | Y) & r1 < r2 implies (h | Y) . r2 <= (h | Y) . r1 )
assume that
A9: ( r1 in dom (h | Y) & r2 in dom (h | Y) ) and
A10: r1 < r2 ; :: thesis: (h | Y) . r2 <= (h | Y) . r1
A11: ( (h | Y) . r1 = h . r1 & (h | Y) . r2 = h . r2 ) by A9, FUNCT_1:47;
( r1 in Y /\ (dom h) & r2 in Y /\ (dom h) ) by A9, RELAT_1:61;
hence (h | Y) . r2 <= (h | Y) . r1 by A8, A10, A11; :: thesis: verum