let N be complete Lawson meet-continuous TopLattice; for S being Scott TopAugmentation of N
for x being Element of N holds { (inf A) where A is Subset of S : ( x in A & A in sigma S ) } = { (inf J) where J is Subset of N : ( x in J & J in lambda N ) }
let S be Scott TopAugmentation of N; for x being Element of N holds { (inf A) where A is Subset of S : ( x in A & A in sigma S ) } = { (inf J) where J is Subset of N : ( x in J & J in lambda N ) }
let x be Element of N; { (inf A) where A is Subset of S : ( x in A & A in sigma S ) } = { (inf J) where J is Subset of N : ( x in J & J in lambda N ) }
set l = { (inf A) where A is Subset of N : ( x in A & A in lambda N ) } ;
set s = { (inf J) where J is Subset of S : ( x in J & J in sigma S ) } ;
thus
{ (inf J) where J is Subset of S : ( x in J & J in sigma S ) } c= { (inf A) where A is Subset of N : ( x in A & A in lambda N ) }
by Th33; XBOOLE_0:def 10 { (inf J) where J is Subset of N : ( x in J & J in lambda N ) } c= { (inf A) where A is Subset of S : ( x in A & A in sigma S ) }
let k be object ; TARSKI:def 3 ( not k in { (inf J) where J is Subset of N : ( x in J & J in lambda N ) } or k in { (inf A) where A is Subset of S : ( x in A & A in sigma S ) } )
assume
k in { (inf A) where A is Subset of N : ( x in A & A in lambda N ) }
; k in { (inf A) where A is Subset of S : ( x in A & A in sigma S ) }
then consider A being Subset of N such that
A1:
k = inf A
and
A2:
x in A
and
A3:
A in lambda N
;
A4:
RelStr(# the carrier of N, the InternalRel of N #) = RelStr(# the carrier of S, the InternalRel of S #)
by YELLOW_9:def 4;
then reconsider J = A as Subset of S ;
A is open
by A3, Th12;
then
uparrow J is open
by Th15;
then A5:
uparrow J in sigma S
by WAYBEL14:24;
A6:
J c= uparrow J
by WAYBEL_0:16;
inf A =
inf J
by A4, YELLOW_0:17, YELLOW_0:27
.=
inf (uparrow J)
by WAYBEL_0:38, YELLOW_0:17
;
hence
k in { (inf A) where A is Subset of S : ( x in A & A in sigma S ) }
by A5, A1, A2, A6; verum