let n be Element of NAT ; for A being closed-interval Subset of REAL st A = [.0,(2 * PI).] holds
integral ((((#Z n) * sin) (#) cos),A) = 0
let A be closed-interval Subset of REAL; ( A = [.0,(2 * PI).] implies integral ((((#Z n) * sin) (#) cos),A) = 0 )
assume
A = [.0,(2 * PI).]
; integral ((((#Z n) * sin) (#) cos),A) = 0
then
( upper_bound A = 2 * PI & lower_bound A = 0 )
by INTEGRA8:37;
then integral ((((#Z n) * sin) (#) cos),A) =
(((1 / (n + 1)) (#) ((#Z (n + 1)) * sin)) . (2 * PI)) - (((1 / (n + 1)) (#) ((#Z (n + 1)) * sin)) . 0)
by Th19
.=
((1 / (n + 1)) * (((#Z (n + 1)) * sin) . (2 * PI))) - (((1 / (n + 1)) (#) ((#Z (n + 1)) * sin)) . 0)
by VALUED_1:6
.=
((1 / (n + 1)) * (((#Z (n + 1)) * sin) . (2 * PI))) - ((1 / (n + 1)) * (((#Z (n + 1)) * sin) . 0))
by VALUED_1:6
.=
((1 / (n + 1)) * ((#Z (n + 1)) . (sin . (2 * PI)))) - ((1 / (n + 1)) * (((#Z (n + 1)) * sin) . 0))
by FUNCT_1:23, SIN_COS:27
.=
((1 / (n + 1)) * ((#Z (n + 1)) . (sin . (2 * PI)))) - ((1 / (n + 1)) * ((#Z (n + 1)) . (sin . 0)))
by FUNCT_1:23, SIN_COS:27
.=
0
by SIN_COS:33, SIN_COS:81
;
hence
integral ((((#Z n) * sin) (#) cos),A) = 0
; verum