let seq, seq1 be Complex_Sequence; :: thesis: ( seq is convergent & ex k being Element of NAT st
for n being Element of NAT st k <= n holds
seq1 . n = seq . n implies seq1 is convergent )
assume that
A1: seq is convergent and
A2: ex k being Element of NAT st
for n being Element of NAT st k <= n holds
seq1 . n = seq . n ; :: thesis: seq1 is convergent
consider g1 being Element of COMPLEX such that
A3: for p being Real st 0 < p holds
ex n being Element of NAT st
for m being Element of NAT st n <= m holds
|.((seq . m) - g1).| < p by A1, COMSEQ_2:def 4;
consider k being Element of NAT such that
A4: for n being Element of NAT st k <= n holds
seq1 . n = seq . n by A2;
take g = g1; :: according to COMSEQ_2:def 4 :: thesis: for b₁ being Element of REAL holds
( b₁ <= 0 or ex b₂ being Element of NAT st
for b₃ being Element of NAT holds
( not b₂ <= b₃ or not b₁ <= |.((seq1 . b₃) - g).| ) )
let p be Real; :: thesis: ( p <= 0 or ex b₁ being Element of NAT st
for b₂ being Element of NAT holds
( not b₁ <= b₂ or not p <= |.((seq1 . b₂) - g).| ) )
assume 0 < p ; :: thesis: ex b₁ being Element of NAT st
for b₂ being Element of NAT holds
( not b₁ <= b₂ or not p <= |.((seq1 . b₂) - g).| )
then consider n1 being Element of NAT such that
A5: for m being Element of NAT st n1 <= m holds
|.((seq . m) - g1).| < p by A3;
hence ex n being Element of NAT st
for m being Element of NAT st n <= m holds
|.((seq1 . m) - g).| < p by A6; :: thesis: verum