From Topologies of a Set to Subrings of Its Power Set

Abstract: Let $X$ be a nonempty set and ${\mathcal{P}}(X)$<… Show more

“…In contrast to the setting of the preceding paragraph, [19] studied rings R that are exquisitely commutative, specifically, rings of the form R = P(S) for some (usually nonempty, often finite) set S. As is well known (and easy to see), P(S) is a Boolean ring, with symmetric difference playing the role of addition and intersection playing the role of multiplication, so that S is the multiplicative identity element of P(S). If |S| ≥ 2, we will identify {∅, S} with F 2 , so that F 2 ⊆ P(S).…”

“…If |S| ≥ 2, we will identify {∅, S} with F 2 , so that F 2 ⊆ P(S). We next discuss the first of the results from [19] that we are generalizing here. Apart from a topologically formulated equivalent condition that we will mention later, [19,Theorem 2.3] can be stated as follows.…”

“…We next discuss the first of the results from [19] that we are generalizing here. Apart from a topologically formulated equivalent condition that we will mention later, [19,Theorem 2.3] can be stated as follows. Let S be a nonempty set and R := P(S).…”

“…The first goal of this work is to generalize some recent results from [19] to a noncommutative setting and thereby deepen our understanding of finite Boolean rings. Accomplishing the first goal will involve extending the context for the FIP, FCP and FMC concepts to noncommutative ring extensions.…”

“…The next paragraph announces some conventions and notation. After that, four paragraphs provide some relevant background, then one paragraph states the results from [19] that we are generalizing, then one paragraph gives details about our first main result (Theorem 2.2) and explains some ways in which it generalizes the above-mentioned results from [19], and then two paragraphs describe our results for arbitrary prime characteristic p, including a catenarian conclusion (Corollary 2.10 (b)) that strengthens an inequality that had been observed in [19] in the Boolean context.…”

Characterizing finite Boolean rings by using finite chains of subrings

“…In contrast to the setting of the preceding paragraph, [19] studied rings R that are exquisitely commutative, specifically, rings of the form R = P(S) for some (usually nonempty, often finite) set S. As is well known (and easy to see), P(S) is a Boolean ring, with symmetric difference playing the role of addition and intersection playing the role of multiplication, so that S is the multiplicative identity element of P(S). If |S| ≥ 2, we will identify {∅, S} with F 2 , so that F 2 ⊆ P(S).…”

“…If |S| ≥ 2, we will identify {∅, S} with F 2 , so that F 2 ⊆ P(S). We next discuss the first of the results from [19] that we are generalizing here. Apart from a topologically formulated equivalent condition that we will mention later, [19,Theorem 2.3] can be stated as follows.…”

“…We next discuss the first of the results from [19] that we are generalizing here. Apart from a topologically formulated equivalent condition that we will mention later, [19,Theorem 2.3] can be stated as follows. Let S be a nonempty set and R := P(S).…”

“…The first goal of this work is to generalize some recent results from [19] to a noncommutative setting and thereby deepen our understanding of finite Boolean rings. Accomplishing the first goal will involve extending the context for the FIP, FCP and FMC concepts to noncommutative ring extensions.…”

“…The next paragraph announces some conventions and notation. After that, four paragraphs provide some relevant background, then one paragraph states the results from [19] that we are generalizing, then one paragraph gives details about our first main result (Theorem 2.2) and explains some ways in which it generalizes the above-mentioned results from [19], and then two paragraphs describe our results for arbitrary prime characteristic p, including a catenarian conclusion (Corollary 2.10 (b)) that strengthens an inequality that had been observed in [19] in the Boolean context.…”

Characterizing finite Boolean rings by using finite chains of subrings

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