let r be Real; :: thesis: for X being non empty Subset of REAL st X is bounded_below & r <= 0 holds
r ** X is bounded_above
let X be non empty Subset of REAL ; :: thesis: ( X is bounded_below & r <= 0 implies r ** X is bounded_above )
assume that
A1: X is bounded_below and
A2: r <= 0 ; :: thesis: r ** X is bounded_above
consider b being real number such that
A3: for x being real number st x in X holds
b <= x by A1, SEQ_4:def 2;
for y being real number st y in r ** X holds
y <= r * b
proof
let y be real number ; :: thesis: ( y in r ** X implies y <= r * b )
assume y in r ** X ; :: thesis: y <= r * b
then y in { (r * x) where x is Real : x in X } by Th8;
then consider x being Real such that
A4: y = r * x and
A5: x in X ;
b <= x by A3, A5;
hence y <= r * b by A2, A4, XREAL_1:67; :: thesis: verum
end;
hence r ** X is bounded_above by SEQ_4:def 1; :: thesis: verum