let n be Element of NAT ; for h, x being Real
for f1, f2 being Function of REAL ,REAL holds ((cdif (f1 + f2),h) . (n + 1)) . x = (((cdif f1,h) . (n + 1)) . x) + (((cdif f2,h) . (n + 1)) . x)
let h, x be Real; for f1, f2 being Function of REAL ,REAL holds ((cdif (f1 + f2),h) . (n + 1)) . x = (((cdif f1,h) . (n + 1)) . x) + (((cdif f2,h) . (n + 1)) . x)
let f1, f2 be Function of REAL ,REAL ; ((cdif (f1 + f2),h) . (n + 1)) . x = (((cdif f1,h) . (n + 1)) . x) + (((cdif f2,h) . (n + 1)) . x)
defpred S1[ Element of NAT ] means for x being Real holds ((cdif (f1 + f2),h) . ($1 + 1)) . x = (((cdif f1,h) . ($1 + 1)) . x) + (((cdif f2,h) . ($1 + 1)) . x);
A1:
for k being Element of NAT st S1[k] holds
S1[k + 1]
proof
let k be
Element of
NAT ;
( S1[k] implies S1[k + 1] )
assume A2:
for
x being
Real holds
((cdif (f1 + f2),h) . (k + 1)) . x = (((cdif f1,h) . (k + 1)) . x) + (((cdif f2,h) . (k + 1)) . x)
;
S1[k + 1]
let x be
Real;
((cdif (f1 + f2),h) . ((k + 1) + 1)) . x = (((cdif f1,h) . ((k + 1) + 1)) . x) + (((cdif f2,h) . ((k + 1) + 1)) . x)
A3:
(
((cdif (f1 + f2),h) . (k + 1)) . (x - (h / 2)) = (((cdif f1,h) . (k + 1)) . (x - (h / 2))) + (((cdif f2,h) . (k + 1)) . (x - (h / 2))) &
((cdif (f1 + f2),h) . (k + 1)) . (x + (h / 2)) = (((cdif f1,h) . (k + 1)) . (x + (h / 2))) + (((cdif f2,h) . (k + 1)) . (x + (h / 2))) )
by A2;
A4:
(cdif (f1 + f2),h) . (k + 1) is
Function of
REAL ,
REAL
by Th19;
A5:
(cdif f2,h) . (k + 1) is
Function of
REAL ,
REAL
by Th19;
A6:
(cdif f1,h) . (k + 1) is
Function of
REAL ,
REAL
by Th19;
((cdif (f1 + f2),h) . ((k + 1) + 1)) . x =
(cD ((cdif (f1 + f2),h) . (k + 1)),h) . x
by Def8
.=
(((cdif (f1 + f2),h) . (k + 1)) . (x + (h / 2))) - (((cdif (f1 + f2),h) . (k + 1)) . (x - (h / 2)))
by A4, Th5
.=
((((cdif f1,h) . (k + 1)) . (x + (h / 2))) - (((cdif f1,h) . (k + 1)) . (x - (h / 2)))) + ((((cdif f2,h) . (k + 1)) . (x + (h / 2))) - (((cdif f2,h) . (k + 1)) . (x - (h / 2))))
by A3
.=
((cD ((cdif f1,h) . (k + 1)),h) . x) + ((((cdif f2,h) . (k + 1)) . (x + (h / 2))) - (((cdif f2,h) . (k + 1)) . (x - (h / 2))))
by A6, Th5
.=
((cD ((cdif f1,h) . (k + 1)),h) . x) + ((cD ((cdif f2,h) . (k + 1)),h) . x)
by A5, Th5
.=
(((cdif f1,h) . ((k + 1) + 1)) . x) + ((cD ((cdif f2,h) . (k + 1)),h) . x)
by Def8
.=
(((cdif f1,h) . ((k + 1) + 1)) . x) + (((cdif f2,h) . ((k + 1) + 1)) . x)
by Def8
;
hence
((cdif (f1 + f2),h) . ((k + 1) + 1)) . x = (((cdif f1,h) . ((k + 1) + 1)) . x) + (((cdif f2,h) . ((k + 1) + 1)) . x)
;
verum
end;
A7:
S1[ 0 ]
proof
let x be
Real;
((cdif (f1 + f2),h) . (0 + 1)) . x = (((cdif f1,h) . (0 + 1)) . x) + (((cdif f2,h) . (0 + 1)) . x)
((cdif (f1 + f2),h) . (0 + 1)) . x =
(cD ((cdif (f1 + f2),h) . 0 ),h) . x
by Def8
.=
(cD (f1 + f2),h) . x
by Def8
.=
((f1 + f2) . (x + (h / 2))) - ((f1 + f2) . (x - (h / 2)))
by Th5
.=
((f1 . (x + (h / 2))) + (f2 . (x + (h / 2)))) - ((f1 + f2) . (x - (h / 2)))
by VALUED_1:1
.=
((f1 . (x + (h / 2))) + (f2 . (x + (h / 2)))) - ((f1 . (x - (h / 2))) + (f2 . (x - (h / 2))))
by VALUED_1:1
.=
((f1 . (x + (h / 2))) - (f1 . (x - (h / 2)))) + ((f2 . (x + (h / 2))) - (f2 . (x - (h / 2))))
.=
((cD f1,h) . x) + ((f2 . (x + (h / 2))) - (f2 . (x - (h / 2))))
by Th5
.=
((cD f1,h) . x) + ((cD f2,h) . x)
by Th5
.=
((cD ((cdif f1,h) . 0 ),h) . x) + ((cD f2,h) . x)
by Def8
.=
((cD ((cdif f1,h) . 0 ),h) . x) + ((cD ((cdif f2,h) . 0 ),h) . x)
by Def8
.=
(((cdif f1,h) . (0 + 1)) . x) + ((cD ((cdif f2,h) . 0 ),h) . x)
by Def8
.=
(((cdif f1,h) . (0 + 1)) . x) + (((cdif f2,h) . (0 + 1)) . x)
by Def8
;
hence
((cdif (f1 + f2),h) . (0 + 1)) . x = (((cdif f1,h) . (0 + 1)) . x) + (((cdif f2,h) . (0 + 1)) . x)
;
verum
end;
for n being Element of NAT holds S1[n]
from NAT_1:sch 1(A7, A1);
hence
((cdif (f1 + f2),h) . (n + 1)) . x = (((cdif f1,h) . (n + 1)) . x) + (((cdif f2,h) . (n + 1)) . x)
; verum