Tolerance relation explained

In universal algebra and lattice theory, a tolerance relation on an algebraic structure is a reflexive symmetric relation that is compatible with all operations of the structure. Thus a tolerance is like a congruence, except that the assumption of transitivity is dropped.^[1] On a set, an algebraic structure with empty family of operations, tolerance relations are simply reflexive symmetric relations. A set that possesses a tolerance relation can be described as a tolerance space.^[2] Tolerance relations provide a convenient general tool for studying indiscernibility/indistinguishability phenomena. The importance of those for mathematics had been first recognized by Poincaré.^[3]

Definitions

(A,F)

is usually defined to be a reflexive symmetric relation on

that is compatible with every operation in

. A tolerance relation can also be seen as a cover of

that satisfies certain conditions. The two definitions are equivalent, since for a fixed algebraic structure, the tolerance relations in the two definitions are in one-to-one correspondence. The tolerance relations on an algebraic structure

(A,F)

form an algebraic lattice

\operatorname{Tolr}(A)

under inclusion. Since every congruence relation is a tolerance relation, the congruence lattice

\operatorname{Cong}(A)

is a subset of the tolerance lattice

\operatorname{Tolr}(A)

, but

\operatorname{Cong}(A)

is not necessarily a sublattice of

\operatorname{Tolr}(A)

.^[4]

As binary relations

(A,F)

is a binary relation

\sim

that satisfies the following conditions.

(Reflexivity)

a\sima

for all

a\inA

(Symmetry) if

a\simb

then

b\sima

for all

a,b\inA

(Compatibility) for each

-ary operation

f\inF

and

a_1,...,a_n,b_1,...,b_n\inA

, if

a_i\simb_i

for each

i=1,...,n

then

f(a_1,...,a_n)\simf(b_1,...,b_n)

. That is, the set

\{(a,b)\colona\simb\}

is a subalgebra of the direct product

A²

of two

. A congruence relation is a tolerance relation that is also transitive.

As covers

(A,F)

is a cover

that satisfies the following three conditions.^[5]

For every

C\inlC

and

lS\subseteqlC

, if

styleC\subseteqcuplS

, then

stylecaplS\subseteqC

- In particular, no two distinct elements of

are comparable. (To see this, take

lS=\{D\}

For every

S\subseteqA

, if

is not contained in any set in

, then there is a two-element subset

\{s,t\}\subseteqS

such that

\{s,t\}

is not contained in any set in

For every

-ary

f\inF

and

C_1,...,C_n\inlC

, there is a

(f/{\sim})(C_1,...,C_n)\inlC

such that

\{f(c_1,...,c_n)\colonc_i\inC_{i\}\subseteq(f/{\sim})(C}_1,...,C_n)

. (Such a

(f/{\sim})(C_1,...,C_n)

need not be unique.)Every partition of

satisfies the first two conditions, but not conversely. A congruence relation is a tolerance relation that also forms a set partition.

Equivalence of the two definitions

Let

\sim

be a tolerance binary relation on an algebraic structure

(A,F)

. Let

A/{\sim}

be the family of maximal subsets

C\subseteqA

such that

c\simd

for every

c,d\inC

. Using graph theoretical terms,

A/{\sim}

is the set of all maximal cliques of the graph

(A,\sim)

. If

\sim

is a congruence relation,

A/{\sim}

is just the quotient set of equivalence classes. Then

A/{\sim}

is a cover of

and satisfies all the three conditions in the cover definition. (The last condition is shown using Zorn's lemma.) Conversely, let

be a cover of

and suppose that

forms a tolerance on

. Consider a binary relation

\sim_lC

for which

a\sim_lCb

if and only if

a,b\inC

for some

C\inlC

. Then

\sim_lC

is a tolerance on

as a binary relation. The map

{\sim}\mapstoA/{\sim}

is a one-to-one correspondence between the tolerances as binary relations and as covers whose inverse is

lC\mapsto{\sim_lC

}. Therefore, the two definitions are equivalent. A tolerance is transitive as a binary relation if and only if it is a partition as a cover. Thus the two characterizations of congruence relations also agree.

Quotient algebras over tolerance relations

Let

(A,F)

be an algebraic structure and let

\sim

be a tolerance relation on

. Suppose that, for each

-ary operation

f\inF

and

C_1,...,C_n\inA/{\sim}

, there is a unique

(f/{\sim})(C_1,...,C_n)\inA/{\sim}

such that

\{f(c_1,...,c_n)\colonc_i\inC_{i\}\subseteq(f/{\sim})(C}_1,...,C_n)

Then this provides a natural definition of the quotient algebra

(A/{\sim},F/{\sim})

(A,F)

over

\sim

. In the case of congruence relations, the uniqueness condition always holds true and the quotient algebra defined here coincides with the usual one.

A main difference from congruence relations is that for a tolerance relation the uniqueness condition may fail, and even if it does not, the quotient algebra may not inherit the identities defining the variety that

(A,F)

belongs to, so that the quotient algebra may fail to be a member of the variety again. Therefore, for a variety

of algebraic structures, we may consider the following two conditions.

(Tolerance factorability) for any

(A,F)\inlV

and any tolerance relation

\sim

(A,F)

, the uniqueness condition is true, so that the quotient algebra

(A/{\sim},F/{\sim})

is defined.

(Strong tolerance factorability) for any

(A,F)\inlV

and any tolerance relation

\sim

(A,F)

, the uniqueness condition is true, and

(A/{\sim},F/{\sim})\inlV

.Every strongly tolerance factorable variety is tolerance factorable, but not vice versa.

Examples

Sets

A set is an algebraic structure with no operations at all. In this case, tolerance relations are simply reflexive symmetric relations and it is trivial that the variety of sets is strongly tolerance factorable.

Groups

On a group, every tolerance relation is a congruence relation. In particular, this is true for all algebraic structures that are groups when some of their operations are forgot, e.g. rings, vector spaces, modules, Boolean algebras, etc.^[6] Therefore, the varieties of groups, rings, vector spaces, modules and Boolean algebras are also strongly tolerance factorable trivially.

Lattices

For a tolerance relation

\sim

on a lattice

, every set in

L/{\sim}

is a convex sublattice of

. Thus, for all

A\inL/{\sim}

, we have

A=\uparrowA\cap\downarrowA

In particular, the following results hold.

a\simb

if and only if

a\veeb\sima\wedgeb

a\simb

and

a\lec,d\leb

, then

c\simd

(L,\vee_L,\wedge_L)

and any tolerance relation

\sim

, for each

A,B\inL/{\sim}

there exist unique

A\vee_L/{\sim

}B,A\wedge_B\in L/ such that

\{a\vee_Lb\colona\inA, b\inB\}\subseteqA\vee_L/{\sim

\{a\wedge_Lb\colona\inA, b\inB\}\subseteqA\wedge_L/{\sim

}Band the quotient algebra

(L/{\sim},\vee_L/{\sim

},\wedge_)is a lattice again.^[7] ^[8] ^[9]

In particular, we can form quotient lattices of distributive lattices and modular lattices over tolerance relations. However, unlike in the case of congruence relations, the quotient lattices need not be distributive or modular again. In other words, the varieties of distributive lattices and modular lattices are tolerance factorable, but not strongly tolerance factorable. Actually, every subvariety of the variety of lattices is tolerance factorable, and the only strongly tolerance factorable subvariety other than itself is the trivial subvariety (consisting of one-element lattices). This is because every lattice is isomorphic to a sublattice of the quotient lattice over a tolerance relation of a sublattice of a direct product of two-element lattices.

Notes and References

Book: Keith. Kearnes. Emil W.. Kiss. The Shape of Congruence Lattices. 2013. American Mathematical Soc.. 978-0-8218-8323-5. 20.
Sossinsky. Alexey. 1986-02-01. Tolerance space theory and some applications. Acta Applicandae Mathematicae. 5. 2. 137–167. 10.1007/BF00046585. 119731847 .
Book: Poincare. H.. Science and Hypothesis. 1905. The Walter Scott Publishing Co., Ltd.. with a preface by J.Larmor. New York: 3 East 14th Street. 22-23.
2014. 10.14232/actasm-012-861-x. Ivan. Sándor. 0001-6969. 3-4. Acta Scientiarum Mathematicarum. en. Chajda. Radeleczki. 3307031. 389–397. 85560830. Notes on tolerance factorable classes of algebras. 80. 1321.08002.
1976. 10.21136/CMJ.1976.101403. Ivan. Josef. Bohdan. 0011-4642. 101. Czechoslovak Mathematical Journal. en. Chajda. Niederle. Zelinka. 0401561. 304–311. On existence conditions for compatible tolerances. 26. 0333.08006. free.
1987. 10.1016/0012-365X(87)90194-4. Boris M.. 0012-365X. Discrete Mathematics. en. Schein. 0887364. 253–262. Semigroups of tolerance relations. 64. 0615.20045. free.
1982. Gábor. 0001-6969. Acta Scientiarum Mathematicarum. en. Czédli. 0660510. 35–42. Factor lattices by tolerances. 44. 0484.06010.
George. Grätzer. G. H.. Wenzel. Notes on tolerance relations of lattices. en. Acta Scientiarum Mathematicarum. 54. 3-4. 229–240. 1990. 0001-6969. 1096802. 0727.06011.
Book: George. Grätzer. Lattice Theory: Foundation. en. Springer. Basel. 2011. 978-3-0348-0017-4. 10.1007/978-3-0348-0018-1. 2768581. 1233.06001. 2011921250.

Tolerance relation explained

Definitions

As binary relations

As covers

Equivalence of the two definitions

Quotient algebras over tolerance relations

Examples

Sets

Groups

Lattices

See also

Further reading

Notes and References