let S, T be complete LATTICE; :: thesis: for g being infs-preserving Function of S,T
for X being Scott TopAugmentation of T
for Y being Scott TopAugmentation of S
for V being open Subset of X holds (LowerAdj g) .: V = (rng (LowerAdj g)) /\ (uparrow ((LowerAdj g) .: V))
let g be infs-preserving Function of S,T; :: thesis: for X being Scott TopAugmentation of T
for Y being Scott TopAugmentation of S
for V being open Subset of X holds (LowerAdj g) .: V = (rng (LowerAdj g)) /\ (uparrow ((LowerAdj g) .: V))
let X be Scott TopAugmentation of T; :: thesis: for Y being Scott TopAugmentation of S
for V being open Subset of X holds (LowerAdj g) .: V = (rng (LowerAdj g)) /\ (uparrow ((LowerAdj g) .: V))
let Y be Scott TopAugmentation of S; :: thesis: for V being open Subset of X holds (LowerAdj g) .: V = (rng (LowerAdj g)) /\ (uparrow ((LowerAdj g) .: V))
A1: RelStr(# the carrier of X, the InternalRel of X #) = RelStr(# the carrier of T, the InternalRel of T #) by YELLOW_9:def 4;
A2: RelStr(# the carrier of Y, the InternalRel of Y #) = RelStr(# the carrier of S, the InternalRel of S #) by YELLOW_9:def 4;
then reconsider d = LowerAdj g as Function of X,Y by A1;
let V be open Subset of X; :: thesis: (LowerAdj g) .: V = (rng (LowerAdj g)) /\ (uparrow ((LowerAdj g) .: V))
reconsider A = uparrow ((LowerAdj g) .: V) as Subset of Y by A2;
d .: V = A /\ (rng d)
proof
A3: d .: V c= A by WAYBEL_0:16;
d .: V c= rng d by RELAT_1:144;
hence d .: V c= A /\ (rng d) by A3, XBOOLE_1:19; :: according to XBOOLE_0:def 10 :: thesis: A /\ (rng d) c= d .: V
let t be set ; :: according to TARSKI:def 3 :: thesis: ( not t in A /\ (rng d) or t in d .: V )
assume A4: t in A /\ (rng d) ; :: thesis: t in d .: V
then A5: t in A by XBOOLE_0:def 4;
A6: t in rng d by A4, XBOOLE_0:def 4;
reconsider t = t as Element of S by A5;
consider x being Element of S such that
A7: x <= t and
A8: x in (LowerAdj g) .: V by A5, WAYBEL_0:def 16;
consider u being set such that
A9: u in the carrier of T and
A10: u in V and
A11: x = (LowerAdj g) . u by A8, FUNCT_2:115;
dom d = the carrier of T by FUNCT_2:def 1;
then consider v being set such that
A12: v in the carrier of T and
A13: t = d . v by A6, FUNCT_1:def 5;
reconsider u = u, v = v as Element of T by A9, A12;
A14: (LowerAdj g) . (u "\/" v) = x "\/" t by A11, A13, WAYBEL_6:2
.= t by A7, YELLOW_0:24 ;
reconsider V9 = V as Subset of T by A1;
V is upper by WAYBEL11:def 4;
then A15: V9 is upper by A1, WAYBEL_0:25;
u <= u "\/" v by YELLOW_0:22;
then u "\/" v in V9 by A10, A15, WAYBEL_0:def 20;
hence t in d .: V by A14, FUNCT_2:43; :: thesis: verum
end;
hence (LowerAdj g) .: V = (rng (LowerAdj g)) /\ (uparrow ((LowerAdj g) .: V)) ; :: thesis: verum