let X be Complex_Banach_Algebra; :: thesis: for seq being sequence of X
for rseq being Real_Sequence st ( for n being Element of NAT holds ||.(seq . n).|| <= rseq . n ) & rseq is convergent & lim rseq = 0 holds
( seq is convergent & lim seq = 0. X )
let seq be sequence of X; :: thesis: for rseq being Real_Sequence st ( for n being Element of NAT holds ||.(seq . n).|| <= rseq . n ) & rseq is convergent & lim rseq = 0 holds
( seq is convergent & lim seq = 0. X )
let rseq be Real_Sequence; :: thesis: ( ( for n being Element of NAT holds ||.(seq . n).|| <= rseq . n ) & rseq is convergent & lim rseq = 0 implies ( seq is convergent & lim seq = 0. X ) )
assume that
A1: for n being Element of NAT holds ||.(seq . n).|| <= rseq . n and
A2: rseq is convergent and
A3: lim rseq = 0 ; :: thesis: ( seq is convergent & lim seq = 0. X )
then A8: 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) - (0. X)).|| < p ;
hence seq is convergent by CLVECT_1:def 15; :: thesis: lim seq = 0. X
hence lim seq = 0. X by A8, CLVECT_1:def 16; :: thesis: verum