let X be ComplexUnitarySpace; for seq1, seq2 being sequence of X st seq1 is Cauchy & seq1 is_compared_to seq2 holds
seq2 is Cauchy
let seq1, seq2 be sequence of X; ( seq1 is Cauchy & seq1 is_compared_to seq2 implies seq2 is Cauchy )
assume that
A1:
seq1 is Cauchy
and
A2:
seq1 is_compared_to seq2
; seq2 is Cauchy
let r be Real; CLVECT_2:def 8 ( r > 0 implies ex k being Nat st
for n, m being Nat st n >= k & m >= k holds
dist ((seq2 . n),(seq2 . m)) < r )
assume
r > 0
; ex k being Nat st
for n, m being Nat st n >= k & m >= k holds
dist ((seq2 . n),(seq2 . m)) < r
then A3:
r / 3 > 0
by XREAL_1:222;
then consider m1 being Nat such that
A4:
for n, m being Nat st n >= m1 & m >= m1 holds
dist ((seq1 . n),(seq1 . m)) < r / 3
by A1;
consider m2 being Nat such that
A5:
for n being Nat st n >= m2 holds
dist ((seq1 . n),(seq2 . n)) < r / 3
by A2, A3;
take k = m1 + m2; for n, m being Nat st n >= k & m >= k holds
dist ((seq2 . n),(seq2 . m)) < r
let n, m be Nat; ( n >= k & m >= k implies dist ((seq2 . n),(seq2 . m)) < r )
assume that
A6:
n >= k
and
A7:
m >= k
; dist ((seq2 . n),(seq2 . m)) < r
m1 + m2 >= m1
by NAT_1:12;
then
( n >= m1 & m >= m1 )
by A6, A7, XXREAL_0:2;
then A8:
dist ((seq1 . n),(seq1 . m)) < r / 3
by A4;
A9:
dist ((seq2 . n),(seq1 . m)) <= (dist ((seq2 . n),(seq1 . n))) + (dist ((seq1 . n),(seq1 . m)))
by CSSPACE:51;
A10:
k >= m2
by NAT_1:12;
then
n >= m2
by A6, XXREAL_0:2;
then
dist ((seq1 . n),(seq2 . n)) < r / 3
by A5;
then
(dist ((seq2 . n),(seq1 . n))) + (dist ((seq1 . n),(seq1 . m))) < (r / 3) + (r / 3)
by A8, XREAL_1:8;
then A11:
dist ((seq2 . n),(seq1 . m)) < (r / 3) + (r / 3)
by A9, XXREAL_0:2;
A12:
dist ((seq2 . n),(seq2 . m)) <= (dist ((seq2 . n),(seq1 . m))) + (dist ((seq1 . m),(seq2 . m)))
by CSSPACE:51;
m >= m2
by A7, A10, XXREAL_0:2;
then
dist ((seq1 . m),(seq2 . m)) < r / 3
by A5;
then
(dist ((seq2 . n),(seq1 . m))) + (dist ((seq1 . m),(seq2 . m))) < ((r / 3) + (r / 3)) + (r / 3)
by A11, XREAL_1:8;
hence
dist ((seq2 . n),(seq2 . m)) < r
by A12, XXREAL_0:2; verum