A6: dom (f ^ ) c= dom f by A4, XBOOLE_1:36;
let seq be Real_Sequence; :: thesis: ( seq is convergent & lim seq = x0 & rng seq c= (dom (f ^ )) /\ (left_open_halfline x0) implies ( (f ^ ) /* seq is convergent & lim ((f ^ ) /* seq) = (lim_left f,x0) " ) )
assume that
A7: seq is convergent and
A8: lim seq = x0 and
A9: rng seq c= (dom (f ^ )) /\ (left_open_halfline x0) ; :: thesis: ( (f ^ ) /* seq is convergent & lim ((f ^ ) /* seq) = (lim_left f,x0) " )
A10: (dom (f ^ )) /\ (left_open_halfline x0) c= dom (f ^ ) by XBOOLE_1:17;
then A11: f /* seq is non-zero by A9, RFUNCT_2:26, XBOOLE_1:1;
rng seq c= dom (f ^ ) by A9, A10, XBOOLE_1:1;
then A12: rng seq c= dom f by A6, XBOOLE_1:1;
(dom (f ^ )) /\ (left_open_halfline x0) c= left_open_halfline x0 by XBOOLE_1:17;
then rng seq c= left_open_halfline x0 by A9, XBOOLE_1:1;
then A13: rng seq c= (dom f) /\ (left_open_halfline x0) by A12, XBOOLE_1:19;
then A14: lim (f /* seq) = lim_left f,x0 by A1, A7, A8, Def7;
A15: (f /* seq) " = (f ^ ) /* seq by A9, A10, RFUNCT_2:27, XBOOLE_1:1;
A16: f /* seq is convergent by A1, A2, A7, A8, A13, Def7;
hence (f ^ ) /* seq is convergent by A2, A14, A11, A15, SEQ_2:35; :: thesis: lim ((f ^ ) /* seq) = (lim_left f,x0) "
thus lim ((f ^ ) /* seq) = (lim_left f,x0) " by A2, A16, A14, A11, A15, SEQ_2:36; :: thesis: verum

let r be Real; :: thesis: ( r < x0 implies ex g being Real st
( r < g & g < x0 & g in dom (f ^ ) ) )
assume r < x0 ; :: thesis: ex g being Real st
( r < g & g < x0 & g in dom (f ^ ) )
then consider g being Real such that
A17: r < g and
A18: g < x0 and
A19: g in dom f and
A20: f . g <> 0 by A3;
take g = g; :: thesis: ( r < g & g < x0 & g in dom (f ^ ) )
not f . g in {0 } by A20, TARSKI:def 1;
then not g in f " {0 } by FUNCT_1:def 13;
hence ( r < g & g < x0 & g in dom (f ^ ) ) by A4, A17, A18, A19, XBOOLE_0:def 5; :: thesis: verum