let F be RealNormSpace; for x0 being Real
for f1, f2 being PartFunc of REAL, the carrier of F st f1 is_differentiable_in x0 & f2 is_differentiable_in x0 holds
( f1 + f2 is_differentiable_in x0 & diff ((f1 + f2),x0) = (diff (f1,x0)) + (diff (f2,x0)) )
let x0 be Real; for f1, f2 being PartFunc of REAL, the carrier of F st f1 is_differentiable_in x0 & f2 is_differentiable_in x0 holds
( f1 + f2 is_differentiable_in x0 & diff ((f1 + f2),x0) = (diff (f1,x0)) + (diff (f2,x0)) )
let f1, f2 be PartFunc of REAL, the carrier of F; ( f1 is_differentiable_in x0 & f2 is_differentiable_in x0 implies ( f1 + f2 is_differentiable_in x0 & diff ((f1 + f2),x0) = (diff (f1,x0)) + (diff (f2,x0)) ) )
assume that
A1:
f1 is_differentiable_in x0
and
A2:
f2 is_differentiable_in x0
; ( f1 + f2 is_differentiable_in x0 & diff ((f1 + f2),x0) = (diff (f1,x0)) + (diff (f2,x0)) )
consider N1 being Neighbourhood of x0 such that
A3:
N1 c= dom f1
and
A4:
ex L being LinearFunc of F ex R being RestFunc of F st
for x being Real st x in N1 holds
(f1 /. x) - (f1 /. x0) = (L /. (x - x0)) + (R /. (x - x0))
by A1;
consider L1 being LinearFunc of F, R1 being RestFunc of F such that
A5:
for x being Real st x in N1 holds
(f1 /. x) - (f1 /. x0) = (L1 /. (x - x0)) + (R1 /. (x - x0))
by A4;
consider N2 being Neighbourhood of x0 such that
A6:
N2 c= dom f2
and
A7:
ex L being LinearFunc of F ex R being RestFunc of F st
for x being Real st x in N2 holds
(f2 /. x) - (f2 /. x0) = (L /. (x - x0)) + (R /. (x - x0))
by A2;
consider L2 being LinearFunc of F, R2 being RestFunc of F such that
A8:
for x being Real st x in N2 holds
(f2 /. x) - (f2 /. x0) = (L2 /. (x - x0)) + (R2 /. (x - x0))
by A7;
reconsider R = R1 + R2 as RestFunc of F by Th7;
reconsider L = L1 + L2 as LinearFunc of F by Th3;
consider N being Neighbourhood of x0 such that
A9:
N c= N1
and
A10:
N c= N2
by RCOMP_1:17;
A11:
N c= dom f2
by A6, A10;
N c= dom f1
by A3, A9;
then
N /\ N c= (dom f1) /\ (dom f2)
by A11, XBOOLE_1:27;
then A12:
N c= dom (f1 + f2)
by VFUNCT_1:def 1;
( R1 is total & R2 is total )
by Def1;
then
R1 + R2 is total
by VFUNCT_1:32;
then A13:
dom (R1 + R2) = REAL
by FUNCT_2:def 1;
L1 + L2 is total
by VFUNCT_1:32;
then A14:
dom (L1 + L2) = REAL
by FUNCT_2:def 1;
A15:
now for x being Real st x in N holds
((f1 + f2) /. x) - ((f1 + f2) /. x0) = (L /. (x - x0)) + (R /. (x - x0))let x be
Real;
( x in N implies ((f1 + f2) /. x) - ((f1 + f2) /. x0) = (L /. (x - x0)) + (R /. (x - x0)) )A16:
x0 in N
by RCOMP_1:16;
A17:
x - x0 in REAL
by XREAL_0:def 1;
assume A18:
x in N
;
((f1 + f2) /. x) - ((f1 + f2) /. x0) = (L /. (x - x0)) + (R /. (x - x0))hence ((f1 + f2) /. x) - ((f1 + f2) /. x0) =
((f1 /. x) + (f2 /. x)) - ((f1 + f2) /. x0)
by A12, VFUNCT_1:def 1
.=
((f1 /. x) + (f2 /. x)) - ((f1 /. x0) + (f2 /. x0))
by A12, A16, VFUNCT_1:def 1
.=
(f1 /. x) + ((f2 /. x) - ((f1 /. x0) + (f2 /. x0)))
by RLVECT_1:28
.=
(f1 /. x) + (((f2 /. x) - (f2 /. x0)) - (f1 /. x0))
by RLVECT_1:27
.=
((f1 /. x) + ((f2 /. x) - (f2 /. x0))) - (f1 /. x0)
by RLVECT_1:28
.=
((f2 /. x) - (f2 /. x0)) + ((f1 /. x) - (f1 /. x0))
by RLVECT_1:28
.=
((L1 /. (x - x0)) + (R1 /. (x - x0))) + ((f2 /. x) - (f2 /. x0))
by A5, A9, A18
.=
((L1 /. (x - x0)) + (R1 /. (x - x0))) + ((L2 /. (x - x0)) + (R2 /. (x - x0)))
by A8, A10, A18
.=
(((L1 /. (x - x0)) + (R1 /. (x - x0))) + (L2 /. (x - x0))) + (R2 /. (x - x0))
by RLVECT_1:def 3
.=
(((L1 /. (x - x0)) + (L2 /. (x - x0))) + (R1 /. (x - x0))) + (R2 /. (x - x0))
by RLVECT_1:def 3
.=
((L1 /. (x - x0)) + (L2 /. (x - x0))) + ((R1 /. (x - x0)) + (R2 /. (x - x0)))
by RLVECT_1:def 3
.=
(L /. (x - x0)) + ((R1 /. (x - x0)) + (R2 /. (x - x0)))
by A14, VFUNCT_1:def 1, A17
.=
(L /. (x - x0)) + (R /. (x - x0))
by A13, VFUNCT_1:def 1, A17
;
verum end;
hence
f1 + f2 is_differentiable_in x0
by A12; diff ((f1 + f2),x0) = (diff (f1,x0)) + (diff (f2,x0))
hence diff ((f1 + f2),x0) =
L /. jj
by A12, A15, Def4
.=
L /. jj
.=
(L1 /. jj) + (L2 /. jj)
by A14, VFUNCT_1:def 1
.=
(L1 /. jj) + (L2 /. jj)
.=
(L1 /. jj) + (L2 /. jj)
.=
(diff (f1,x0)) + (L2 /. jj)
by A1, A3, A5, Def4
.=
(diff (f1,x0)) + (diff (f2,x0))
by A2, A6, A8, Def4
;
verum