let L be sup-Semilattice; for x being Element of L holds uparrow x is join-closed
let x be Element of L; uparrow x is join-closed
reconsider x1 = x as Element of L ;
now for y, z being Element of L st y in the carrier of (subrelstr (uparrow x)) & z in the carrier of (subrelstr (uparrow x)) & ex_sup_of {y,z},L holds
sup {y,z} in the carrier of (subrelstr (uparrow x))let y,
z be
Element of
L;
( y in the carrier of (subrelstr (uparrow x)) & z in the carrier of (subrelstr (uparrow x)) & ex_sup_of {y,z},L implies sup {y,z} in the carrier of (subrelstr (uparrow x)) )assume that A1:
y in the
carrier of
(subrelstr (uparrow x))
and
z in the
carrier of
(subrelstr (uparrow x))
and
ex_sup_of {y,z},
L
;
sup {y,z} in the carrier of (subrelstr (uparrow x))
y in uparrow x
by A1, YELLOW_0:def 15;
then A2:
y >= x1
by WAYBEL_0:18;
y "\/" z >= y
by YELLOW_0:22;
then
y "\/" z >= x1
by A2, YELLOW_0:def 2;
then
y "\/" z in uparrow x
by WAYBEL_0:18;
then
sup {y,z} in uparrow x
by YELLOW_0:41;
hence
sup {y,z} in the
carrier of
(subrelstr (uparrow x))
by YELLOW_0:def 15;
verum end;
then
subrelstr (uparrow x) is join-inheriting
by YELLOW_0:def 17;
hence
uparrow x is join-closed
by Def2; verum