let L1, L2 be Real; :: thesis: ( ex Intf being PartFunc of REAL,REAL st

( dom Intf = right_closed_halfline a & ( for x being Real st x in dom Intf holds

Intf . x = integral (f,a,x) ) & Intf is convergent_in+infty & L1 = lim_in+infty Intf ) & ex Intf being PartFunc of REAL,REAL st

( dom Intf = right_closed_halfline a & ( for x being Real st x in dom Intf holds

Intf . x = integral (f,a,x) ) & Intf is convergent_in+infty & L2 = lim_in+infty Intf ) implies L1 = L2 )

assume ex Intf1 being PartFunc of REAL,REAL st

( dom Intf1 = right_closed_halfline a & ( for x being Real st x in dom Intf1 holds

Intf1 . x = integral (f,a,x) ) & Intf1 is convergent_in+infty & L1 = lim_in+infty Intf1 ) ; :: thesis: ( for Intf being PartFunc of REAL,REAL holds

( not dom Intf = right_closed_halfline a or ex x being Real st

( x in dom Intf & not Intf . x = integral (f,a,x) ) or not Intf is convergent_in+infty or not L2 = lim_in+infty Intf ) or L1 = L2 )

then consider Intf1 being PartFunc of REAL,REAL such that

A3: dom Intf1 = right_closed_halfline a and

A4: for x being Real st x in dom Intf1 holds

Intf1 . x = integral (f,a,x) and

Intf1 is convergent_in+infty and

A5: L1 = lim_in+infty Intf1 ;

assume ex Intf2 being PartFunc of REAL,REAL st

( dom Intf2 = right_closed_halfline a & ( for x being Real st x in dom Intf2 holds

Intf2 . x = integral (f,a,x) ) & Intf2 is convergent_in+infty & L2 = lim_in+infty Intf2 ) ; :: thesis: L1 = L2

then consider Intf2 being PartFunc of REAL,REAL such that

A6: dom Intf2 = right_closed_halfline a and

A7: for x being Real st x in dom Intf2 holds

Intf2 . x = integral (f,a,x) and

Intf2 is convergent_in+infty and

A8: L2 = lim_in+infty Intf2 ;

( dom Intf = right_closed_halfline a & ( for x being Real st x in dom Intf holds

Intf . x = integral (f,a,x) ) & Intf is convergent_in+infty & L1 = lim_in+infty Intf ) & ex Intf being PartFunc of REAL,REAL st

( dom Intf = right_closed_halfline a & ( for x being Real st x in dom Intf holds

Intf . x = integral (f,a,x) ) & Intf is convergent_in+infty & L2 = lim_in+infty Intf ) implies L1 = L2 )

assume ex Intf1 being PartFunc of REAL,REAL st

( dom Intf1 = right_closed_halfline a & ( for x being Real st x in dom Intf1 holds

Intf1 . x = integral (f,a,x) ) & Intf1 is convergent_in+infty & L1 = lim_in+infty Intf1 ) ; :: thesis: ( for Intf being PartFunc of REAL,REAL holds

( not dom Intf = right_closed_halfline a or ex x being Real st

( x in dom Intf & not Intf . x = integral (f,a,x) ) or not Intf is convergent_in+infty or not L2 = lim_in+infty Intf ) or L1 = L2 )

then consider Intf1 being PartFunc of REAL,REAL such that

A3: dom Intf1 = right_closed_halfline a and

A4: for x being Real st x in dom Intf1 holds

Intf1 . x = integral (f,a,x) and

Intf1 is convergent_in+infty and

A5: L1 = lim_in+infty Intf1 ;

assume ex Intf2 being PartFunc of REAL,REAL st

( dom Intf2 = right_closed_halfline a & ( for x being Real st x in dom Intf2 holds

Intf2 . x = integral (f,a,x) ) & Intf2 is convergent_in+infty & L2 = lim_in+infty Intf2 ) ; :: thesis: L1 = L2

then consider Intf2 being PartFunc of REAL,REAL such that

A6: dom Intf2 = right_closed_halfline a and

A7: for x being Real st x in dom Intf2 holds

Intf2 . x = integral (f,a,x) and

Intf2 is convergent_in+infty and

A8: L2 = lim_in+infty Intf2 ;

now :: thesis: for x being Element of REAL st x in dom Intf1 holds

Intf1 . x = Intf2 . x

hence
L1 = L2
by A3, A5, A6, A8, PARTFUN1:5; :: thesis: verumIntf1 . x = Intf2 . x

let x be Element of REAL ; :: thesis: ( x in dom Intf1 implies Intf1 . x = Intf2 . x )

assume A9: x in dom Intf1 ; :: thesis: Intf1 . x = Intf2 . x

hence Intf1 . x = integral (f,a,x) by A4

.= Intf2 . x by A3, A6, A7, A9 ;

:: thesis: verum

end;assume A9: x in dom Intf1 ; :: thesis: Intf1 . x = Intf2 . x

hence Intf1 . x = integral (f,a,x) by A4

.= Intf2 . x by A3, A6, A7, A9 ;

:: thesis: verum