let n be Element of NAT ; for A being closed-interval Subset of REAL
for f being PartFunc of REAL ,REAL
for Z being open Subset of REAL st A c= Z & f = (n (#) ((#Z (n - 1)) * cos )) / ((#Z (n + 1)) * sin ) & 1 <= n & Z c= dom ((#Z n) * cot ) & Z = dom f holds
integral f,A = ((- ((#Z n) * cot )) . (upper_bound A)) - ((- ((#Z n) * cot )) . (lower_bound A))
let A be closed-interval Subset of REAL ; for f being PartFunc of REAL ,REAL
for Z being open Subset of REAL st A c= Z & f = (n (#) ((#Z (n - 1)) * cos )) / ((#Z (n + 1)) * sin ) & 1 <= n & Z c= dom ((#Z n) * cot ) & Z = dom f holds
integral f,A = ((- ((#Z n) * cot )) . (upper_bound A)) - ((- ((#Z n) * cot )) . (lower_bound A))
let f be PartFunc of REAL ,REAL ; for Z being open Subset of REAL st A c= Z & f = (n (#) ((#Z (n - 1)) * cos )) / ((#Z (n + 1)) * sin ) & 1 <= n & Z c= dom ((#Z n) * cot ) & Z = dom f holds
integral f,A = ((- ((#Z n) * cot )) . (upper_bound A)) - ((- ((#Z n) * cot )) . (lower_bound A))
let Z be open Subset of REAL ; ( A c= Z & f = (n (#) ((#Z (n - 1)) * cos )) / ((#Z (n + 1)) * sin ) & 1 <= n & Z c= dom ((#Z n) * cot ) & Z = dom f implies integral f,A = ((- ((#Z n) * cot )) . (upper_bound A)) - ((- ((#Z n) * cot )) . (lower_bound A)) )
assume A1:
( A c= Z & f = (n (#) ((#Z (n - 1)) * cos )) / ((#Z (n + 1)) * sin ) & 1 <= n & Z c= dom ((#Z n) * cot ) & Z = dom f )
; integral f,A = ((- ((#Z n) * cot )) . (upper_bound A)) - ((- ((#Z n) * cot )) . (lower_bound A))
then
Z = (dom (n (#) ((#Z (n - 1)) * cos ))) /\ ((dom ((#Z (n + 1)) * sin )) \ (((#Z (n + 1)) * sin ) " {0 }))
by RFUNCT_1:def 4;
then A3:
( Z c= dom (n (#) ((#Z (n - 1)) * cos )) & Z c= (dom ((#Z (n + 1)) * sin )) \ (((#Z (n + 1)) * sin ) " {0 }) )
by XBOOLE_1:18;
then A4:
Z c= dom (((#Z (n + 1)) * sin ) ^ )
by RFUNCT_1:def 8;
dom (((#Z (n + 1)) * sin ) ^ ) c= dom ((#Z (n + 1)) * sin )
by RFUNCT_1:11;
then A5:
Z c= dom ((#Z (n + 1)) * sin )
by A4, XBOOLE_1:1;
A6:
for x being Real st x in Z holds
((#Z (n + 1)) * sin ) . x <> 0
A9:
Z c= dom ((#Z (n - 1)) * cos )
by A3, VALUED_1:def 5;
A10:
for x being Real holds (#Z (n - 1)) * cos is_differentiable_in x
(#Z (n - 1)) * cos is_differentiable_on Z
then A15:
n (#) ((#Z (n - 1)) * cos ) is_differentiable_on Z
by A3, FDIFF_1:28;
A16:
for x being Real holds (#Z (n + 1)) * sin is_differentiable_in x
(#Z (n + 1)) * sin is_differentiable_on Z
then
f | Z is continuous
by FDIFF_1:33, A1, A6, A15, FDIFF_2:21;
then
f | A is continuous
by A1, FCONT_1:17;
then A22:
( f is_integrable_on A & f | A is bounded )
by A1, INTEGRA5:10, INTEGRA5:11;
A23:
(#Z n) * cot is_differentiable_on Z
by A1, FDIFF_8:21;
A24:
dom ((#Z n) * cot ) c= dom cot
by RELAT_1:44;
A25:
Z c= dom (- ((#Z n) * cot ))
by A1, VALUED_1:8;
then A26:
(- 1) (#) ((#Z n) * cot ) is_differentiable_on Z
by A23, FDIFF_1:28, X;
A27:
for x being Real st x in Z holds
sin . x <> 0
A28:
for x being Real st x in Z holds
((- ((#Z n) * cot )) `| Z) . x = (n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n + 1))
proof
let x be
Real;
( x in Z implies ((- ((#Z n) * cot )) `| Z) . x = (n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n + 1)) )
assume A29:
x in Z
;
((- ((#Z n) * cot )) `| Z) . x = (n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n + 1))
then A30:
sin . x <> 0
by A27;
then A31:
cot is_differentiable_in x
by FDIFF_7:47;
consider m being
Nat such that A32:
n = m + 1
by A1, NAT_1:6;
set m =
n - 1;
A33:
(#Z n) * cot is_differentiable_in x
by A23, A29, FDIFF_1:16;
((- ((#Z n) * cot )) `| Z) . x =
diff (- ((#Z n) * cot )),
x
by A26, A29, FDIFF_1:def 8
.=
(- 1) * (diff ((#Z n) * cot ),x)
by A33, FDIFF_1:23, X
.=
(- 1) * ((n * ((cot . x) #Z (n - 1))) * (diff cot ,x))
by A31, TAYLOR_1:3
.=
(- 1) * ((n * ((cot . x) #Z (n - 1))) * (- (1 / ((sin . x) ^2 ))))
by A30, FDIFF_7:47
.=
(- 1) * (- ((n * ((cot . x) #Z (n - 1))) / ((sin . x) ^2 )))
.=
(- 1) * (- ((n * (((cos . x) #Z (n - 1)) / ((sin . x) #Z (n - 1)))) / ((sin . x) ^2 )))
by A1, A24, A29, A32, FDIFF_8:3, XBOOLE_1:1
.=
(- 1) * (- (((n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n - 1))) / ((sin . x) ^2 )))
.=
(- 1) * (- ((n * ((cos . x) #Z (n - 1))) / (((sin . x) #Z (n - 1)) * ((sin . x) ^2 ))))
by XCMPLX_1:79
.=
(- 1) * (- ((n * ((cos . x) #Z (n - 1))) / (((sin . x) #Z (n - 1)) * ((sin . x) #Z 2))))
by FDIFF_7:1
.=
(- 1) * (- ((n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z ((n - 1) + 2))))
by A27, A29, PREPOWER:54
.=
(n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n + 1))
;
hence
((- ((#Z n) * cot )) `| Z) . x = (n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n + 1))
;
verum
end;
B1:
for x being Real st x in Z holds
f . x = (n * ((cos . x) #Z (n - 1))) / ((sin . x) #Z (n + 1))
A34:
for x being Real st x in dom ((- ((#Z n) * cot )) `| Z) holds
((- ((#Z n) * cot )) `| Z) . x = f . x
dom ((- ((#Z n) * cot )) `| Z) = dom f
by A1, A26, FDIFF_1:def 8;
then
(- ((#Z n) * cot )) `| Z = f
by A34, PARTFUN1:34;
hence
integral f,A = ((- ((#Z n) * cot )) . (upper_bound A)) - ((- ((#Z n) * cot )) . (lower_bound A))
by A1, A22, A23, A25, FDIFF_1:28, X, INTEGRA5:13; verum