let seq1, seq2 be Real_Sequence; ( seq1 is divergent_to+infty & seq2 is divergent_to+infty implies seq1 (#) seq2 is divergent_to+infty )
assume that
A1:
seq1 is divergent_to+infty
and
A2:
seq2 is divergent_to+infty
; seq1 (#) seq2 is divergent_to+infty
let r be Real; LIMFUNC1:def 4 ex n being Element of NAT st
for m being Element of NAT st n <= m holds
r < (seq1 (#) seq2) . m
consider n1 being Element of NAT such that
A3:
for m being Element of NAT st n1 <= m holds
sqrt (abs r) < seq1 . m
by A1, Def4;
consider n2 being Element of NAT such that
A4:
for m being Element of NAT st n2 <= m holds
sqrt (abs r) < seq2 . m
by A2, Def4;
take n = max n1,n2; for m being Element of NAT st n <= m holds
r < (seq1 (#) seq2) . m
let m be Element of NAT ; ( n <= m implies r < (seq1 (#) seq2) . m )
assume A5:
n <= m
; r < (seq1 (#) seq2) . m
n2 <= n
by XXREAL_0:25;
then
n2 <= m
by A5, XXREAL_0:2;
then A6:
sqrt (abs r) < seq2 . m
by A4;
n1 <= n
by XXREAL_0:25;
then
n1 <= m
by A5, XXREAL_0:2;
then A7:
sqrt (abs r) < seq1 . m
by A3;
A8:
abs r >= 0
by COMPLEX1:132;
then
sqrt (abs r) >= 0
by SQUARE_1:def 4;
then
(sqrt (abs r)) ^2 < (seq1 . m) * (seq2 . m)
by A7, A6, XREAL_1:98;
then A9:
abs r < (seq1 . m) * (seq2 . m)
by A8, SQUARE_1:def 4;
r <= abs r
by ABSVALUE:11;
then
r < (seq1 . m) * (seq2 . m)
by A9, XXREAL_0:2;
hence
r < (seq1 (#) seq2) . m
by SEQ_1:12; verum