Some varieties containing relation algebras

Abstract: ABSTRACT. Three varieties of algebras are introduced which extend the variety RA of relation algebras. They are obtained from RA by weakening the associative law for relative product, and are consequently called nonassociative, weakly-associative and semiassociative relation algebras, or NA, WA, and SA, respectively. Each of these varieties arises naturally in solving various problems concerning relation algebras. We show, for example, that WA is the only one of these varieties which is closed under the format… Show more

“…We show that the class of all strongly representable relation algebra atom structures is not closed under ultraproducts and is therefore not elementary. This answers a question of Maddux (1982).Our proof is based on the following construction. From an arbitrary undirected, loop-free graph Γ, we construct a relation algebra atom structure α(Γ) and prove, for infinite Γ, that α(Γ) is strongly representable if and only if the chromatic number of Γ is infinite.…”

“…We show that the class of all strongly representable relation algebra atom structures is not closed under ultraproducts and is therefore not elementary. This answers a question of Maddux (1982).…”

Strongly representable atom structures of relation algebras

“…We show that the class of all strongly representable relation algebra atom structures is not closed under ultraproducts and is therefore not elementary. This answers a question of Maddux (1982).Our proof is based on the following construction. From an arbitrary undirected, loop-free graph Γ, we construct a relation algebra atom structure α(Γ) and prove, for infinite Γ, that α(Γ) is strongly representable if and only if the chromatic number of Γ is infinite.…”

“…We show that the class of all strongly representable relation algebra atom structures is not closed under ultraproducts and is therefore not elementary. This answers a question of Maddux (1982).…”

Strongly representable atom structures of relation algebras

“…It follows that (x;y)U = yU ;x u . By (13), (8), and the IL, we have l'u = I'u; l'uu = (I'U; I')U = l'uu = I', and hence, by (10), O'U= (-l')U = _l'u= -1'= 0'. Thus (14) holds.…”

“…For (8) We get x Uu = x by first replacingy by -x, and then by _X UU . Note that 1 = 1 + I U , so by (6) and (8) we get (9) as follows: 1 = 1 + I U = I UU + I U = (IU + I)u = I U • For (10) we first get -x . x Uu = 0 from -x' x = 0 by (8), and then (-x)U 'x u = 0 by 1.11.…”

“…(11) follows from (6) and (10), and (12) follows from (6) and (8 Let z = _(x;y)U , and then let z = _(yU ;X U ). It follows that (x;y)U = yU ;x u .…”

Some Varieties Containing Relation Algebras

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