let n be Element of NAT ; :: thesis:
A1: [#] REAL = dom ((- (1 / n)) (#) (cos * (AffineMap (n,0)))) by FUNCT_2:def 1;
A2: ( [#] REAL = dom (cos * (AffineMap (n,0))) & ( for x being Real st x in REAL holds
(AffineMap (n,0)) . x = (n * x) + 0 ) ) by FCONT_1:def 4, FUNCT_2:def 1;
then A3: cos * (AffineMap (n,0)) is_differentiable_on REAL by FDIFF_4:38;
assume A4: n <> 0 ; :: thesis:
for x being Real st x in REAL holds
(((- (1 / n)) (#) (cos * (AffineMap (n,0)))) `| REAL) . x = sin (n * x)

proof

let x be Real; :: thesis:
assume x in REAL ; :: thesis:
(((- (1 / n)) (#) (cos * (AffineMap (n,0)))) `| REAL) . x = (- (1 / n)) * (diff ((cos * (AffineMap (n,0))),x)) by A1, A3, FDIFF_1:20
.= (- (1 / n)) * (((cos * (AffineMap (n,0))) `| REAL) . x) by A3, FDIFF_1:def 7
.= (- (1 / n)) * (- (n * (sin . ((n * x) + 0)))) by A2, FDIFF_4:38
.= ((1 / n) * n) * (sin . ((n * x) + 0))
.= (n / n) * (sin . ((n * x) + 0)) by XCMPLX_1:99
.= 1 * (sin . ((n * x) + 0)) by A4, XCMPLX_1:60
.= sin (n * x) ;
hence (((- (1 / n)) (#) (cos * (AffineMap (n,0)))) `| REAL) . x = sin (n * x) ; :: thesis:

end;

hence ( (- (1 / n)) (#) (cos * (AffineMap (n,0))) is_differentiable_on REAL & ( for x being Real holds (((- (1 / n)) (#) (cos * (AffineMap (n,0)))) `| REAL) . x = sin (n * x) ) ) by A1, A3, FDIFF_1:20; :: thesis: