let f be PartFunc of REAL,REAL; :: thesis: for x0 being Real st f is_right_divergent_to-infty_in x0 holds
ex r being Real st
( 0 < r & f | ].x0,(x0 + r).[ is bounded_above )
let x0 be Real; :: thesis: ( f is_right_divergent_to-infty_in x0 implies ex r being Real st
( 0 < r & f | ].x0,(x0 + r).[ is bounded_above ) )
assume A1: f is_right_divergent_to-infty_in x0 ; :: thesis: ex r being Real st
( 0 < r & f | ].x0,(x0 + r).[ is bounded_above )
consider r being Real such that
A2: x0 < r and
A3: for r1 being Real st r1 < r & x0 < r1 & r1 in dom f holds
f . r1 < 1 by A1, LIMFUNC2:12;
set R = r - x0;
for r1 being object st r1 in dom (f | ].x0,(x0 + (r - x0)).[) holds
(f | ].x0,(x0 + (r - x0)).[) . r1 < 1
proof
let r1 be object ; :: thesis: ( r1 in dom (f | ].x0,(x0 + (r - x0)).[) implies (f | ].x0,(x0 + (r - x0)).[) . r1 < 1 )
assume A4: r1 in dom (f | ].x0,(x0 + (r - x0)).[) ; :: thesis: (f | ].x0,(x0 + (r - x0)).[) . r1 < 1
then reconsider r1 = r1 as Real ;
r1 in (dom f) /\ ].x0,(x0 + (r - x0)).[ by A4, RELAT_1:61;
then A5: ( r1 in dom f & r1 in ].x0,(x0 + (r - x0)).[ ) by XBOOLE_0:def 4;
then ( x0 < r1 & r1 < x0 + (r - x0) ) by XXREAL_1:4;
then f . r1 < 1 by A3, A5;
hence (f | ].x0,(x0 + (r - x0)).[) . r1 < 1 by A5, FUNCT_1:49; :: thesis: verum
end;
then f | ].x0,(x0 + (r - x0)).[ is bounded_above by SEQ_2:def 1;
hence ex r being Real st
( 0 < r & f | ].x0,(x0 + r).[ is bounded_above ) by A2, XREAL_1:50; :: thesis: verum