let A be closed-interval Subset of REAL ; :: thesis: for f being PartFunc of REAL ,REAL
for Z being open Subset of REAL st A c= Z & f = (exp_R * sec ) (#) (sin / (cos ^2 )) & Z = dom f & f | A is continuous holds
integral f,A = ((exp_R * sec ) . (upper_bound A)) - ((exp_R * sec ) . (lower_bound A))
let f be PartFunc of REAL ,REAL ; :: thesis: for Z being open Subset of REAL st A c= Z & f = (exp_R * sec ) (#) (sin / (cos ^2 )) & Z = dom f & f | A is continuous holds
integral f,A = ((exp_R * sec ) . (upper_bound A)) - ((exp_R * sec ) . (lower_bound A))
let Z be open Subset of REAL ; :: thesis: ( A c= Z & f = (exp_R * sec ) (#) (sin / (cos ^2 )) & Z = dom f & f | A is continuous implies integral f,A = ((exp_R * sec ) . (upper_bound A)) - ((exp_R * sec ) . (lower_bound A)) )
assume A1: ( A c= Z & f = (exp_R * sec ) (#) (sin / (cos ^2 )) & Z = dom f & f | A is continuous ) ; :: thesis: integral f,A = ((exp_R * sec ) . (upper_bound A)) - ((exp_R * sec ) . (lower_bound A))
then A2: ( f is_integrable_on A & f | A is bounded ) by INTEGRA5:10, INTEGRA5:11;
Z = (dom (exp_R * sec )) /\ (dom (sin / (cos ^2 ))) by A1, VALUED_1:def 4;
then B1: ( Z c= dom (exp_R * sec ) & Z c= dom (sin / (cos ^2 )) ) by XBOOLE_1:18;
then A3: exp_R * sec is_differentiable_on Z by FDIFF_9:16;
B2: for x being Real st x in Z holds
f . x = ((exp_R . (sec . x)) * (sin . x)) / ((cos . x) ^2 )
proof
let x be Real; :: thesis: ( x in Z implies f . x = ((exp_R . (sec . x)) * (sin . x)) / ((cos . x) ^2 ) )
assume B3: x in Z ; :: thesis: f . x = ((exp_R . (sec . x)) * (sin . x)) / ((cos . x) ^2 )
((exp_R * sec ) (#) (sin / (cos ^2 ))) . x = ((exp_R * sec ) . x) * ((sin / (cos ^2 )) . x) by VALUED_1:5
.= (exp_R . (sec . x)) * ((sin / (cos ^2 )) . x) by B3, FUNCT_1:22, B1
.= (exp_R . (sec . x)) * ((sin . x) / ((cos ^2 ) . x)) by RFUNCT_1:def 4, B1, B3
.= (exp_R . (sec . x)) * ((sin . x) / ((cos . x) ^2 )) by VALUED_1:11
.= ((exp_R . (sec . x)) * (sin . x)) / ((cos . x) ^2 ) ;
hence f . x = ((exp_R . (sec . x)) * (sin . x)) / ((cos . x) ^2 ) by A1; :: thesis: verum
end;
A4: for x being Real st x in dom ((exp_R * sec ) `| Z) holds
((exp_R * sec ) `| Z) . x = f . x
proof
let x be Real; :: thesis: ( x in dom ((exp_R * sec ) `| Z) implies ((exp_R * sec ) `| Z) . x = f . x )
assume x in dom ((exp_R * sec ) `| Z) ; :: thesis: ((exp_R * sec ) `| Z) . x = f . x
then A5: x in Z by A3, FDIFF_1:def 8;
then ((exp_R * sec ) `| Z) . x = ((exp_R . (sec . x)) * (sin . x)) / ((cos . x) ^2 ) by B1, FDIFF_9:16
.= f . x by B2, A5 ;
hence ((exp_R * sec ) `| Z) . x = f . x ; :: thesis: verum
end;
dom ((exp_R * sec ) `| Z) = dom f by A1, A3, FDIFF_1:def 8;
then (exp_R * sec ) `| Z = f by A4, PARTFUN1:34;
hence integral f,A = ((exp_R * sec ) . (upper_bound A)) - ((exp_R * sec ) . (lower_bound A)) by A1, A2, A3, INTEGRA5:13; :: thesis: verum