let f1, f2 be PartFunc of REAL ,REAL ; ( f1 is divergent_in+infty_to-infty & f2 is convergent_in-infty & ( for r being Real ex g being Real st
( r < g & g in dom (f2 * f1) ) ) implies ( f2 * f1 is convergent_in+infty & lim_in+infty (f2 * f1) = lim_in-infty f2 ) )
assume that
A1:
f1 is divergent_in+infty_to-infty
and
A2:
f2 is convergent_in-infty
and
A3:
for r being Real ex g being Real st
( r < g & g in dom (f2 * f1) )
; ( f2 * f1 is convergent_in+infty & lim_in+infty (f2 * f1) = lim_in-infty f2 )
A4:
now let s be
Real_Sequence;
( s is divergent_to+infty & rng s c= dom (f2 * f1) implies ( (f2 * f1) /* s is convergent & lim ((f2 * f1) /* s) = lim_in-infty f2 ) )assume that A5:
s is
divergent_to+infty
and A6:
rng s c= dom (f2 * f1)
;
( (f2 * f1) /* s is convergent & lim ((f2 * f1) /* s) = lim_in-infty f2 )
rng s c= dom f1
by A6, Lm2;
then A7:
f1 /* s is
divergent_to-infty
by A1, A5, LIMFUNC1:def 8;
A8:
rng (f1 /* s) c= dom f2
by A6, Lm2;
then A9:
lim (f2 /* (f1 /* s)) = lim_in-infty f2
by A2, A7, LIMFUNC1:def 13;
lim_in-infty f2 = lim_in-infty f2
;
then
f2 /* (f1 /* s) is
convergent
by A2, A8, A7, LIMFUNC1:def 13;
hence
(
(f2 * f1) /* s is
convergent &
lim ((f2 * f1) /* s) = lim_in-infty f2 )
by A6, A9, VALUED_0:31;
verum end;
hence
f2 * f1 is convergent_in+infty
by A3, LIMFUNC1:def 6; lim_in+infty (f2 * f1) = lim_in-infty f2
hence
lim_in+infty (f2 * f1) = lim_in-infty f2
by A4, LIMFUNC1:def 12; verum