let f be PartFunc of REAL,REAL; :: thesis: for I being non empty Interval
for a being Real ex F being PartFunc of REAL,REAL st
( dom F = REAL & ( for x being Real st x in I holds
F . x = integral (f,a,x) ) )
let I be non empty Interval; :: thesis: for a being Real ex F being PartFunc of REAL,REAL st
( dom F = REAL & ( for x being Real st x in I holds
F . x = integral (f,a,x) ) )
let a be Real; :: thesis: ex F being PartFunc of REAL,REAL st
( dom F = REAL & ( for x being Real st x in I holds
F . x = integral (f,a,x) ) )
deffunc H1( Real) -> Element of NAT = 0 ;
defpred S1[ set ] means $1 in I;
deffunc H2( Real) -> object = integral (f,a,$1);
consider F being Function such that
A1: ( dom F = REAL & ( for x being Element of REAL holds
( ( S1[x] implies F . x = H2(x) ) & ( not S1[x] implies F . x = H1(x) ) ) ) ) from PARTFUN1:sch 4();
now :: thesis: for y being object st y in rng F holds
y in REAL
let y be object ; :: thesis: ( y in rng F implies y in REAL )
assume y in rng F ; :: thesis: y in REAL
then consider x being object such that
A2: x in dom F and
A3: y = F . x by FUNCT_1:def 3;
reconsider x = x as Element of REAL by A1, A2;
A4: now :: thesis: ( not x in I implies y in REAL )
assume not x in I ; :: thesis: y in REAL
then F . x = In (0,REAL) by A1;
hence y in REAL by A3; :: thesis: verum
end;
now :: thesis: ( x in I implies y in REAL )
assume x in I ; :: thesis: y in REAL
then F . x = integral (f,a,x) by A1;
hence y in REAL by A3, XREAL_0:def 1; :: thesis: verum
end;
hence y in REAL by A4; :: thesis: verum
end;
then rng F c= REAL ;
then reconsider F = F as PartFunc of REAL,REAL by A1, RELSET_1:4;
take F ; :: thesis: ( dom F = REAL & ( for x being Real st x in I holds
F . x = integral (f,a,x) ) )
thus ( dom F = REAL & ( for x being Real st x in I holds
F . x = integral (f,a,x) ) ) by A1; :: thesis: verum