assume that
A2: lim_right f,x0 = g and
A3: ex g1 being Real st
( 0 < g1 & ( for r being Real st x0 < r holds
ex r1 being Real st
( r1 < r & x0 < r1 & r1 in dom f & abs ((f . r1) - g) >= g1 ) ) ) ; :: thesis: contradiction
consider g1 being Real such that
A4: 0 < g1 and
A5: for r being Real st x0 < r holds
ex r1 being Real st
( r1 < r & x0 < r1 & r1 in dom f & abs ((f . r1) - g) >= g1 ) by A3;
defpred S₁[ Element of NAT , real number ] means ( x0 < $2 & $2 < x0 + (1 / ($1 + 1)) & $2 in dom f & g1 <= abs ((f . $2) - g) );
consider s being Real_Sequence such that
A11: for n being Element of NAT holds S₁[n,s . n] from FUNCT_2:sch 3(A6);
A12: rng s c= (dom f) /\ (right_open_halfline x0) by A11, Th6;
A13: lim s = x0 by A11, Th6;
A14: s is convergent by A11, Th6;
then A15: lim (f /* s) = g by A1, A2, A13, A12, Def8;
f /* s is convergent by A1, A2, A14, A13, A12, Def8;
then consider n being Element of NAT such that
A16: for k being Element of NAT st n <= k holds
abs (((f /* s) . k) - g) < g1 by A4, A15, SEQ_2:def 7;
A17: abs (((f /* s) . n) - g) < g1 by A16;
rng s c= dom f by A11, Th6;
then abs ((f . (s . n)) - g) < g1 by A17, FUNCT_2:185;
hence contradiction by A11; :: thesis: verum

let s be Real_Sequence; :: thesis: ( s is convergent & lim s = x0 & rng s c= (dom f) /\ (right_open_halfline x0) implies ( f /* s is convergent & lim (f /* s) = g ) )
assume that
A19: s is convergent and
A20: lim s = x0 and
A21: rng s c= (dom f) /\ (right_open_halfline x0) ; :: thesis: ( f /* s is convergent & lim (f /* s) = g )
A22: (dom f) /\ (right_open_halfline x0) c= dom f by XBOOLE_1:17;
hence f /* s is convergent by SEQ_2:def 6; :: thesis: lim (f /* s) = g
hence lim (f /* s) = g by A23, SEQ_2:def 7; :: thesis: verum