let X be non empty set ; :: thesis: for Y, Z being non empty Subset of ExtREAL st Y c= REAL & Z c= REAL holds
for F1 being Function of X,Y
for F2 being Function of X,Z st F1 is bounded_above & F2 is bounded_above holds
F1 + F2 is bounded_above
let Y, Z be non empty Subset of ExtREAL ; :: thesis: ( Y c= REAL & Z c= REAL implies for F1 being Function of X,Y
for F2 being Function of X,Z st F1 is bounded_above & F2 is bounded_above holds
F1 + F2 is bounded_above )
assume ( Y c= REAL & Z c= REAL ) ; :: thesis: for F1 being Function of X,Y
for F2 being Function of X,Z st F1 is bounded_above & F2 is bounded_above holds
F1 + F2 is bounded_above
let F1 be Function of X,Y; :: thesis: for F2 being Function of X,Z st F1 is bounded_above & F2 is bounded_above holds
F1 + F2 is bounded_above
let F2 be Function of X,Z; :: thesis: ( F1 is bounded_above & F2 is bounded_above implies F1 + F2 is bounded_above )
assume A2: ( F1 is bounded_above & F2 is bounded_above ) ; :: thesis: F1 + F2 is bounded_above
A4: ( not sup F1 = +infty & not sup F2 = +infty ) by A2, Def11;
A5: ( sup F1 in REAL & sup F2 in REAL implies (sup F1) + (sup F2) < +infty ) A7: ( sup F1 in REAL & sup F2 = -infty implies (sup F1) + (sup F2) < +infty ) by XXREAL_0:7, XXREAL_3:def 2;
A8: ( sup F1 = -infty & sup F2 in REAL implies (sup F1) + (sup F2) < +infty ) by XXREAL_0:7, XXREAL_3:def 2;
A9: ( sup F1 = -infty & sup F2 = -infty implies (sup F1) + (sup F2) < +infty ) by XXREAL_0:7, XXREAL_3:def 2;
sup (F1 + F2) < +infty hence F1 + F2 is bounded_above by Def11; :: thesis: verum