let f be PartFunc of REAL,REAL; ( f is divergent_in-infty_to+infty implies ( not f is convergent_in-infty & not f is divergent_in-infty_to-infty ) )
assume A1:
f is divergent_in-infty_to+infty
; ( not f is convergent_in-infty & not f is divergent_in-infty_to-infty )
hereby not f is divergent_in-infty_to-infty
assume
f is
convergent_in-infty
;
contradictionthen consider g being
Real such that A2:
for
g1 being
Real st
0 < g1 holds
ex
r being
Real st
for
r1 being
Real st
r1 < r &
r1 in dom f holds
|.((f . r1) - g).| < g1
by LIMFUNC1:45;
consider R1 being
Real such that A3:
for
r1 being
Real st
r1 < R1 &
r1 in dom f holds
|.((f . r1) - g).| < 1
by A2;
consider R2 being
Real such that A4:
for
r1 being
Real st
r1 < R2 &
r1 in dom f holds
g + 1
< f . r1
by A1, LIMFUNC1:48;
set R =
min (
R1,
R2);
A5:
(
min (
R1,
R2)
<= R1 &
min (
R1,
R2)
<= R2 )
by XXREAL_0:17;
consider r being
Real such that A6:
(
r < min (
R1,
R2) &
r in dom f )
by A1, LIMFUNC1:48;
A7:
r < R1
by A5, A6, XXREAL_0:2;
r < R2
by A5, A6, XXREAL_0:2;
then A8:
1
< (f . r) - g
by A4, A6, XREAL_1:20;
(f . r) - g <= |.((f . r) - g).|
by ABSVALUE:4;
then
1
< |.((f . r) - g).|
by A8, XXREAL_0:2;
hence
contradiction
by A3, A6, A7;
verum
end;
hereby verum
assume
f is
divergent_in-infty_to-infty
;
contradictionthen consider R1 being
Real such that A9:
for
r1 being
Real st
r1 < R1 &
r1 in dom f holds
f . r1 < 0
by LIMFUNC1:49;
consider R2 being
Real such that A10:
for
r1 being
Real st
r1 < R2 &
r1 in dom f holds
0 < f . r1
by A1, LIMFUNC1:48;
set R =
min (
R1,
R2);
A11:
(
min (
R1,
R2)
<= R1 &
min (
R1,
R2)
<= R2 )
by XXREAL_0:17;
consider r being
Real such that A12:
(
r < min (
R1,
R2) &
r in dom f )
by A1, LIMFUNC1:48;
A13:
(
r < R1 &
r < R2 )
by A11, A12, XXREAL_0:2;
then
f . r > 0
by A10, A12;
hence
contradiction
by A9, A12, A13;
verum
end;