assume A3: R is RestFunc-like ; :: thesis:
assume ex r being Real st
( r > 0 & ( for d being Real holds
( not d > 0 or ex z being Real st
( z <> 0 & |.z.| < d & not ||.(R /. z).|| / |.z.| < r ) ) ) ) ; :: thesis:
then consider r being Real such that
A4: r > 0 and
A5: for d being Real st d > 0 holds
ex z being Real st
( z <> 0 & |.z.| < d & not ||.(R /. z).|| / |.z.| < r ) ;
defpred S₁[ Nat, Element of REAL ] means ( $2 <> 0 & |.$2.| < 1 / ($1 + 1) & not ||.(R /. $2).|| / |.$2.| < r );

let n be Element of NAT ; :: thesis:
consider z being Real such that
A7: ( z <> 0 & |.z.| < 1 / (n + 1) & not ||.(R /. z).|| / |.z.| < r ) by A5;
reconsider z = z as Element of REAL by XREAL_0:def 1;
take z = z; :: thesis:
thus S₁[n,z] by A7; :: thesis:

end;

consider s being Real_Sequence such that
A8: for n being Element of NAT holds S₁[n,s . n] from FUNCT_2:sch 3(A6);
A9: for n being Nat holds S₁[n,s . n]

end;

end;

then s is convergent by SEQ_2:def 6;
then lim s = 0 by A10, SEQ_2:def 7;
then reconsider s = s as non-zero 0 -convergent Real_Sequence by A9, A10, SEQ_1:5, SEQ_2:def 6, FDIFF_1:def 1;
( (s ") (#) (R /* s) is convergent & lim ((s ") (#) (R /* s)) = 0. T ) by A3, NDIFF_3:def 1;
then consider n being Nat such that
A16: for m being Nat st n <= m holds
||.((((s ") (#) (R /* s)) . m) - (0. T)).|| < r by A4, NORMSP_1:def 7;
A17: n in NAT by ORDINAL1:def 12;
A19: ||.(((s . n) ") * (R /. (s . n))).|| = |.((s . n) ").| * ||.(R /. (s . n)).|| by NORMSP_1:def 1
.= ||.(R /. (s . n)).|| / |.(s . n).| by COMPLEX1:66 ;
dom R = REAL by A1, PARTFUN1:def 2;
then A20: rng s c= dom R ;
||.((((s ") (#) (R /* s)) . n) - (0. T)).|| = ||.(((s ") (#) (R /* s)) . n).|| by RLVECT_1:13
.= ||.(((s ") . n) * ((R /* s) . n)).|| by NDIFF_1:def 2
.= ||.(((s . n) ") * ((R /* s) . n)).|| by VALUED_1:10
.= ||.(((s . n) ") * (R /. (s . n))).|| by A20, FUNCT_2:109, A17 ;
hence for r being Real st r > 0 holds
ex d being Real st
( d > 0 & ( for z being Real st z <> 0 & |.z.| < d holds
||.(R /. z).|| / |.z.| < r ) ) by A9, A16, A19; :: thesis:

end;

assume A21: for r being Real st r > 0 holds
ex d being Real st
( d > 0 & ( for z being Real st z <> 0 & |.z.| < d holds
||.(R /. z).|| / |.z.| < r ) ) ; :: thesis:

let r be Real; :: thesis:
assume r > 0 ; :: thesis:
then consider d being Real such that
A24: d > 0 and
A25: for z being Real st z <> 0 & |.z.| < d holds
||.(R /. z).|| / |.z.| < r by A21;
consider n being Nat such that
A26: for m being Nat st n <= m holds
|.((s . m) - 0).| < d by A22, A24, SEQ_2:def 7;
take n = n; :: thesis:
thus for m being Nat st n <= m holds
||.((((s ") (#) (R /* s)) . m) - (0. T)).|| < r :: thesis:

dom R = REAL by A1, PARTFUN1:def 2;
then A27: rng s c= dom R ;
let m be Nat; :: thesis:
A28: m in NAT by ORDINAL1:def 12;
assume n <= m ; :: thesis:
then A29: |.((s . m) - 0).| < d by A26;
||.(R /. (s . m)).|| / |.(s . m).| = |.((s . m) ").| * ||.(R /. (s . m)).|| by COMPLEX1:66
.= ||.(((s . m) ") * (R /. (s . m))).|| by NORMSP_1:def 1
.= ||.(((s . m) ") * ((R /* s) . m)).|| by A27, FUNCT_2:109, A28
.= ||.(((s ") . m) * ((R /* s) . m)).|| by VALUED_1:10
.= ||.(((s ") (#) (R /* s)) . m).|| by NDIFF_1:def 2
.= ||.((((s ") (#) (R /* s)) . m) - (0. T)).|| by RLVECT_1:13 ;
hence ||.((((s ") (#) (R /* s)) . m) - (0. T)).|| < r by A25, A29, SEQ_1:5; :: thesis:

end;

end;

end;

hence ( R is RestFunc-like iff for r being Real st r > 0 holds
ex d being Real st
( d > 0 & ( for z being Real st z <> 0 & |.z.| < d holds
||.(R /. z).|| / |.z.| < r ) ) ) by A2; :: thesis: