let seq1, seq2 be Complex_Sequence; ( seq1 . 0 = seq . 0 & ( for n being Element of NAT holds seq1 . (n + 1) = (seq1 . n) + (seq . (n + 1)) ) & seq2 . 0 = seq . 0 & ( for n being Element of NAT holds seq2 . (n + 1) = (seq2 . n) + (seq . (n + 1)) ) implies seq1 = seq2 )
assume that
A2:
seq1 . 0 = seq . 0
and
A3:
for n being Element of NAT holds seq1 . (n + 1) = (seq1 . n) + (seq . (n + 1))
and
A4:
seq2 . 0 = seq . 0
and
A5:
for n being Element of NAT holds seq2 . (n + 1) = (seq2 . n) + (seq . (n + 1))
; seq1 = seq2
defpred S1[ Element of NAT ] means seq1 . $1 = seq2 . $1;
A6:
for k being Element of NAT st S1[k] holds
S1[k + 1]
proof
let k be
Element of
NAT ;
( S1[k] implies S1[k + 1] )
assume
S1[
k]
;
S1[k + 1]
hence seq1 . (k + 1) =
(seq2 . k) + (seq . (k + 1))
by A3
.=
seq2 . (k + 1)
by A5
;
verum
end;
A7:
S1[ 0 ]
by A2, A4;
for n being Element of NAT holds S1[n]
from NAT_1:sch 1(A7, A6);
hence
seq1 = seq2
by FUNCT_2:113; verum