set N = L opp+id ;
thus L opp+id is antitone :: thesis: L opp+id is eventually-filtered
proof
reconsider f = id L as Function of (L ~ ),L ;
reconsider g = f as Function of L,(L ~ ) ;
g is antitone by YELLOW_7:40;
then A1: ( RelStr(# the carrier of L,the InternalRel of L #) = RelStr(# the carrier of L,the InternalRel of L #) & f is antitone ) by YELLOW_7:41;
( netmap (L opp+id ),L = id L & RelStr(# the carrier of (L opp+id ),the InternalRel of (L opp+id ) #) = RelStr(# the carrier of (L ~ ),the InternalRel of (L ~ ) #) ) by Def6, Th11;
hence netmap (L opp+id ),L is antitone by A1, Th2; :: according to WAYBEL_0:def 10 :: thesis: verum
end;
for i being Element of (L opp+id ) ex j being Element of (L opp+id ) st
for k being Element of (L opp+id ) st j <= k holds
(L opp+id ) . i >= (L opp+id ) . k
proof
let i be Element of (L opp+id ); :: thesis: ex j being Element of (L opp+id ) st
for k being Element of (L opp+id ) st j <= k holds
(L opp+id ) . i >= (L opp+id ) . k
take j = i; :: thesis: for k being Element of (L opp+id ) st j <= k holds
(L opp+id ) . i >= (L opp+id ) . k
A2: ( the mapping of (L opp+id ) = id L & the InternalRel of (L opp+id ) = the InternalRel of L ~ ) by Def6;
let k be Element of (L opp+id ); :: thesis: ( j <= k implies (L opp+id ) . i >= (L opp+id ) . k )
assume j <= k ; :: thesis: (L opp+id ) . i >= (L opp+id ) . k
then [i,k] in the InternalRel of (L opp+id ) by ORDERS_2:def 9;
then A3: [k,i] in the InternalRel of (L opp+id ) ~ by RELAT_1:def 7;
reconsider i1 = i, k1 = k as Element of L by Def6;
( (id L) . i1 = i1 & (id L) . k1 = k1 ) by FUNCT_1:35;
hence (L opp+id ) . i >= (L opp+id ) . k by A2, A3, ORDERS_2:def 9; :: thesis: verum
end;
hence L opp+id is eventually-filtered by WAYBEL_0:12; :: thesis: verum