let x, h be Real; for f being Function of REAL ,REAL st ( for x being Real holds f . x = (tan (#) cos ) . x ) & x + (h / 2) in dom tan & x - (h / 2) in dom tan holds
(cD f,h) . x = (sin (x + (h / 2))) - (sin (x - (h / 2)))
let f be Function of REAL ,REAL ; ( ( for x being Real holds f . x = (tan (#) cos ) . x ) & x + (h / 2) in dom tan & x - (h / 2) in dom tan implies (cD f,h) . x = (sin (x + (h / 2))) - (sin (x - (h / 2))) )
assume that
A1:
for x being Real holds f . x = (tan (#) cos ) . x
and
A2:
( x + (h / 2) in dom tan & x - (h / 2) in dom tan )
; (cD f,h) . x = (sin (x + (h / 2))) - (sin (x - (h / 2)))
(cD f,h) . x =
(f . (x + (h / 2))) - (f . (x - (h / 2)))
by DIFF_1:5
.=
((tan (#) cos ) . (x + (h / 2))) - (f . (x - (h / 2)))
by A1
.=
((tan (#) cos ) . (x + (h / 2))) - ((tan (#) cos ) . (x - (h / 2)))
by A1
.=
((tan . (x + (h / 2))) * (cos . (x + (h / 2)))) - ((tan (#) cos ) . (x - (h / 2)))
by VALUED_1:5
.=
((tan . (x + (h / 2))) * (cos . (x + (h / 2)))) - ((tan . (x - (h / 2))) * (cos . (x - (h / 2))))
by VALUED_1:5
.=
(((sin . (x + (h / 2))) * ((cos . (x + (h / 2))) " )) * (cos . (x + (h / 2)))) - ((tan . (x - (h / 2))) * (cos . (x - (h / 2))))
by A2, RFUNCT_1:def 4
.=
(((sin (x + (h / 2))) / (cos (x + (h / 2)))) * (cos (x + (h / 2)))) - (((sin (x - (h / 2))) / (cos (x - (h / 2)))) * (cos (x - (h / 2))))
by A2, RFUNCT_1:def 4
.=
((sin (x + (h / 2))) / ((cos (x + (h / 2))) / (cos (x + (h / 2))))) - (((sin (x - (h / 2))) / (cos (x - (h / 2)))) * (cos (x - (h / 2))))
by XCMPLX_1:83
.=
((sin (x + (h / 2))) / ((cos (x + (h / 2))) * (1 / (cos (x + (h / 2)))))) - ((sin (x - (h / 2))) / ((cos (x - (h / 2))) / (cos (x - (h / 2)))))
by XCMPLX_1:83
.=
((sin (x + (h / 2))) / 1) - ((sin (x - (h / 2))) / ((cos (x - (h / 2))) * (1 / (cos (x - (h / 2))))))
by A2, FDIFF_8:1, XCMPLX_1:107
.=
((sin (x + (h / 2))) / 1) - ((sin (x - (h / 2))) / 1)
by A2, FDIFF_8:1, XCMPLX_1:107
.=
(sin (x + (h / 2))) - (sin (x - (h / 2)))
;
hence
(cD f,h) . x = (sin (x + (h / 2))) - (sin (x - (h / 2)))
; verum