for L being non empty reflexive RelStr
for b₂ being Relation of L holds
( b₂ = L -waybelow iff for x, y being Element of L holds
( [x,y] in b₂ iff x << y ) );

for L being RelStr holds IntRel L = the InternalRel of L;

for L being RelStr
for R being Relation of L holds
( R is auxiliary(i) iff for x, y being Element of L st [x,y] in R holds
x <= y );

for L being RelStr
for R being Relation of L holds
( R is auxiliary(ii) iff for x, y, z, u being Element of L st u <= x & [x,y] in R & y <= z holds
[u,z] in R );

for L being non empty RelStr
for R being Relation of L holds
( R is auxiliary(iii) iff for x, y, z being Element of L st [x,z] in R & [y,z] in R holds
[(x "\/" y),z] in R );

for L being non empty RelStr
for R being Relation of L holds
( R is auxiliary(iv) iff for x being Element of L holds [(Bottom L),x] in R );

for L being non empty RelStr
for R being Relation of L holds
( R is auxiliary iff ( R is auxiliary(i) & R is auxiliary(ii) & R is auxiliary(iii) & R is auxiliary(iv) ) );

for L being lower-bounded sup-Semilattice
for b₂ being set holds
( b₂ = Aux L iff for a being set holds
( a in b₂ iff a is auxiliary Relation of L ) );

for L being non empty RelStr
for b₂ being Relation of L holds
( b₂ = AuxBottom L iff for x, y being Element of L holds
( [x,y] in b₂ iff x = Bottom L ) );

for L being non empty RelStr
for x being Element of L
for AR being Relation of the carrier of L holds AR -below x = { y where y is Element of L : [y,x] in AR } ;

for L being non empty RelStr
for x being Element of L
for AR being Relation of the carrier of L holds AR -above x = { y where y is Element of L : [x,y] in AR } ;

for L being lower-bounded sup-Semilattice
for AR being auxiliary(ii) auxiliary(iii) auxiliary(iv) Relation of L
for b₃ being Function of L,(InclPoset (Ids L)) holds
( b₃ = AR -below iff for x being Element of L holds b₃ . x = AR -below x );

for L being non empty Poset
for b₂ being strict RelStr holds
( b₂ = MonSet L iff for a being set holds
( ( a in the carrier of b₂ implies ex s being Function of L,(InclPoset (Ids L)) st
( a = s & s is monotone & ( for x being Element of L holds s . x c= downarrow x ) ) ) & ( ex s being Function of L,(InclPoset (Ids L)) st
( a = s & s is monotone & ( for x being Element of L holds s . x c= downarrow x ) ) implies a in the carrier of b₂ ) & ( for c, d being set holds
( [c,d] in the InternalRel of b₂ iff ex f, g being Function of L,(InclPoset (Ids L)) st
( c = f & d = g & c in the carrier of b₂ & d in the carrier of b₂ & f <= g ) ) ) ) );

for L being lower-bounded sup-Semilattice
for b₂ being Function of (InclPoset (Aux L)),(MonSet L) holds
( b₂ = Rel2Map L iff for AR being auxiliary Relation of L holds b₂ . AR = AR -below );

for L being lower-bounded sup-Semilattice
for b₂ being Function of (MonSet L),(InclPoset (Aux L)) holds
( b₂ = Map2Rel L iff for s being set st s in the carrier of (MonSet L) holds
ex AR being auxiliary Relation of L st
( AR = b₂ . s & ( for x, y being set holds
( [x,y] in AR iff ex x', y' being Element of L ex s' being Function of L,(InclPoset (Ids L)) st
( x' = x & y' = y & s' = s & x' in s' . y' ) ) ) ) );

for L being Semilattice
for I being Ideal of L
for b₃ being Function of L,(InclPoset (Ids L)) holds
( b₃ = DownMap I iff for x being Element of L holds
( ( x <= sup I implies b₃ . x = (downarrow x) /\ I ) & ( not x <= sup I implies b₃ . x = downarrow x ) ) );

for L being non empty RelStr
for AR being Relation of L holds
( AR is approximating iff for x being Element of L holds x = sup (AR -below x) );

for L being non empty Poset
for mp being Function of L,(InclPoset (Ids L)) holds
( mp is approximating iff for x being Element of L ex ii being Subset of L st
( ii = mp . x & x = sup ii ) );

for L being complete LATTICE
for b₂ being set holds
( b₂ = App L iff for a being set holds
( a in b₂ iff a is auxiliary approximating Relation of L ) );

for L being RelStr
for AR being Relation of L holds
( AR is satisfying_SI iff for x, z being Element of L st [x,z] in AR & x <> z holds
ex y being Element of L st
( [x,y] in AR & [y,z] in AR & x <> y ) );

for L being RelStr
for AR being Relation of L holds
( AR is satisfying_INT iff for x, z being Element of L st [x,z] in AR holds
ex y being Element of L st
( [x,y] in AR & [y,z] in AR ) );

for L being RelStr
for X being Subset of L
for R being Relation of the carrier of L holds
( X is_directed_wrt R iff for x, y being Element of L st x in X & y in X holds
ex z being Element of L st
( z in X & [x,z] in R & [y,z] in R ) );

for X, x being set
for R being Relation holds
( x is_maximal_wrt X,R iff ( x in X & ( for y being set holds
( not y in X or not y <> x or not [x,y] in R ) ) ) );

for L being RelStr
for X being set
for x being Element of L holds
( x is_maximal_in X iff x is_maximal_wrt X,the InternalRel of L );

for X, x being set
for R being Relation holds
( x is_minimal_wrt X,R iff ( x in X & ( for y being set holds
( not y in X or not y <> x or not [y,x] in R ) ) ) );

for L being RelStr
for X being set
for x being Element of L holds
( x is_minimal_in X iff x is_minimal_wrt X,the InternalRel of L );