let X be ComplexUnitarySpace; :: thesis: for g being Point of X
for seq being sequence of X st seq is convergent & lim seq = g holds
( dist seq,g is convergent & lim (dist seq,g) = 0 )
let g be Point of X; :: thesis: for seq being sequence of X st seq is convergent & lim seq = g holds
( dist seq,g is convergent & lim (dist seq,g) = 0 )
let seq be sequence of X; :: thesis: ( seq is convergent & lim seq = g implies ( dist seq,g is convergent & lim (dist seq,g) = 0 ) )
assume A1:
( seq is convergent & lim seq = g )
; :: thesis: ( dist seq,g is convergent & lim (dist seq,g) = 0 )
A2:
now let r be
real number ;
:: thesis: ( r > 0 implies ex k being Element of NAT st
for n being Element of NAT st n >= k holds
abs (((dist seq,g) . n) - 0 ) < r )assume A3:
r > 0
;
:: thesis: ex k being Element of NAT st
for n being Element of NAT st n >= k holds
abs (((dist seq,g) . n) - 0 ) < r
r is
Real
by XREAL_0:def 1;
then consider m1 being
Element of
NAT such that A4:
for
n being
Element of
NAT st
n >= m1 holds
dist (seq . n),
g < r
by A1, A3, Def2;
take k =
m1;
:: thesis: for n being Element of NAT st n >= k holds
abs (((dist seq,g) . n) - 0 ) < rlet n be
Element of
NAT ;
:: thesis: ( n >= k implies abs (((dist seq,g) . n) - 0 ) < r )
dist (seq . n),
g >= 0
by CSSPACE:56;
then A5:
abs ((dist (seq . n),g) - 0 ) = dist (seq . n),
g
by ABSVALUE:def 1;
assume
n >= k
;
:: thesis: abs (((dist seq,g) . n) - 0 ) < rthen
dist (seq . n),
g < r
by A4;
hence
abs (((dist seq,g) . n) - 0 ) < r
by A5, Def4;
:: thesis: verum end;
dist seq,g is convergent
by A1, Th23;
hence
( dist seq,g is convergent & lim (dist seq,g) = 0 )
by A2, SEQ_2:def 7; :: thesis: verum