let V be RealLinearSpace; :: thesis:
consider u being Element of V;
consider L being Linear_Combination of {u} such that
A1: L . u = 1 from RLVECT_4:sch 2();
reconsider L = L as Linear_Combination of V ;
A2: L is convex

take <*u*> ; :: according to CONVEX1:def 3 :: thesis:
thus <*u*> is one-to-one by FINSEQ_3:102; :: thesis:
A3: Carrier L c= {u} by RLVECT_2:def 8;
u in { w where w is Element of V : L . w <> 0 } by A1;
then u in Carrier L by RLVECT_2:def 6;
then {u} c= Carrier L by ZFMISC_1:37;
hence Carrier L = {u} by A3, XBOOLE_0:def 10
.= rng <*u*> by FINSEQ_1:55 ;
:: thesis:
take f = <*rr*>; :: thesis:
( len f = len <*u*> & Sum f = 1 & ( for n being Element of NAT st n in dom f holds
( f . n = L . (<*u*> . n) & f . n >= 0 ) ) )

A4: len <*1*> = 1 by FINSEQ_1:56
.= len <*u*> by FINSEQ_1:56 ;
for n being Element of NAT st n in dom f holds
( f . n = L . (<*u*> . n) & f . n >= 0 )

let n be Element of NAT ; :: thesis:
assume n in dom f ; :: thesis:
then n in {1} by FINSEQ_1:4, FINSEQ_1:55;
then A5: n = 1 by TARSKI:def 1;
then f . n = L . u by A1, FINSEQ_1:57
.= L . (<*u*> . n) by A5, FINSEQ_1:57 ;
hence ( f . n = L . (<*u*> . n) & f . n >= 0 ) by A5, FINSEQ_1:57; :: thesis:

end;

hence ( len f = len <*u*> & Sum f = 1 & ( for n being Element of NAT st n in dom f holds
( f . n = L . (<*u*> . n) & f . n >= 0 ) ) ) by A4, FINSOP_1:12; :: thesis:

end;

hence ( len f = len <*u*> & Sum f = 1 & ( for b₁ being set holds
( not b₁ in dom f or ( f . b₁ = L . (<*u*> . b₁) & 0 <= f . b₁ ) ) ) ) ; :: thesis:

end;

take L ; :: thesis:
thus L is convex by A2; :: thesis: