let h, x be Real; :: thesis: for f being Function of REAL,REAL st ( for x being Real holds f . x = (cot (#) sin) . x ) & x in dom cot & x + h in dom cot holds
(fD (f,h)) . x = (cos (x + h)) - (cos x)
let f be Function of REAL,REAL; :: thesis: ( ( for x being Real holds f . x = (cot (#) sin) . x ) & x in dom cot & x + h in dom cot implies (fD (f,h)) . x = (cos (x + h)) - (cos x) )
assume that
A1: for x being Real holds f . x = (cot (#) sin) . x and
A2: ( x in dom cot & x + h in dom cot ) ; :: thesis: (fD (f,h)) . x = (cos (x + h)) - (cos x)
(fD (f,h)) . x = (f . (x + h)) - (f . x) by DIFF_1:3
.= ((cot (#) sin) . (x + h)) - (f . x) by A1
.= ((cot (#) sin) . (x + h)) - ((cot (#) sin) . x) by A1
.= ((cot . (x + h)) * (sin . (x + h))) - ((cot (#) sin) . x) by VALUED_1:5
.= ((cot . (x + h)) * (sin . (x + h))) - ((cot . x) * (sin . x)) by VALUED_1:5
.= (((cos . (x + h)) * ((sin . (x + h)) ")) * (sin . (x + h))) - ((cot . x) * (sin . x)) by A2, RFUNCT_1:def 1
.= (((cos (x + h)) / (sin (x + h))) * (sin (x + h))) - (((cos x) / (sin x)) * (sin x)) by A2, RFUNCT_1:def 1
.= ((cos (x + h)) / ((sin (x + h)) / (sin (x + h)))) - (((cos x) / (sin x)) * (sin x)) by XCMPLX_1:82
.= ((cos (x + h)) / ((sin (x + h)) * (1 / (sin (x + h))))) - ((cos x) / ((sin x) / (sin x))) by XCMPLX_1:82
.= ((cos (x + h)) / 1) - ((cos x) / ((sin x) * (1 / (sin x)))) by A2, FDIFF_8:2, XCMPLX_1:106
.= ((cos (x + h)) / 1) - ((cos x) / 1) by A2, FDIFF_8:2, XCMPLX_1:106
.= (cos (x + h)) - (cos x) ;
hence (fD (f,h)) . x = (cos (x + h)) - (cos x) ; :: thesis: verum