let seq1, seq2 be sequence of X; :: thesis: ( seq1 . 0 = 1. X & ( for n being Nat holds seq1 . (n + 1) = (seq1 . n) * z ) & seq2 . 0 = 1. X & ( for n being Nat holds seq2 . (n + 1) = (seq2 . n) * z ) implies seq1 = seq2 )
assume that
A4: seq1 . 0 = 1. X and
A5: for n being Nat holds seq1 . (n + 1) = (seq1 . n) * z and
A6: seq2 . 0 = 1. X and
A7: for n being Nat holds seq2 . (n + 1) = (seq2 . n) * z ; :: thesis: seq1 = seq2
defpred S1[ Nat] means seq1 . $1 = seq2 . $1;
A8: for k being Nat st S1[k] holds
S1[k + 1]
proof
let k be Nat; :: thesis: ( S1[k] implies S1[k + 1] )
assume S1[k] ; :: thesis: S1[k + 1]
hence seq1 . (k + 1) = (seq2 . k) * z by A5
.= seq2 . (k + 1) by A7 ;
:: thesis: verum
end;
A9: S1[ 0 ] by A4, A6;
for n being Nat holds S1[n] from NAT_1:sch 2(A9, A8);
 then for n being Element of NAT holds S1[n] ;
hence seq1 = seq2 by FUNCT_2:63; :: thesis: verum