2009
DOI: 10.1515/forum.2009.006
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The catenary and tame degree of numerical monoids

Abstract: We construct an algorithm which computes the catenary and tame degree of a numerical monoid. As an example we explicitly calculate the catenary and tame degree of numerical monoids generated by arithmetical sequences in terms of their first element, the number of elements in the sequence and the di¤erence between two consecutive elements of the sequence.

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Cited by 53 publications
(67 citation statements)
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“…The present paper will focus on the three closely related invariants, namely the set of distances, the (H) The study of these arithmetical invariants (in settings ranging from numerical monoids to Mori rings with zero-divisors) has attracted a lot of attention in the recent literature (for a sample see [10,9,24,14,25,7,11,8]). Our main focus here will be on Krull monoids with finite class group G such that each class contains a prime divisor.…”
Section: Introduction and Main Resultsmentioning
confidence: 99%
“…The present paper will focus on the three closely related invariants, namely the set of distances, the (H) The study of these arithmetical invariants (in settings ranging from numerical monoids to Mori rings with zero-divisors) has attracted a lot of attention in the recent literature (for a sample see [10,9,24,14,25,7,11,8]). Our main focus here will be on Krull monoids with finite class group G such that each class contains a prime divisor.…”
Section: Introduction and Main Resultsmentioning
confidence: 99%
“…An algorithm which computes the catenary degree of a finitely generated monoid can be found in [6], and a more specific version for numerical monoids in [5]. We shift from considering particular factorizations to analyzing their lengths.…”
Section: Definitions and Backgroundmentioning
confidence: 99%
“…, a + b with integers a, b such that 0 < b < a. Write r as in formula (4), that is, r = h(r) + is an ordered amenable set, and thus by Theorem 46 an optimal configuration for r = #M . As D(M ∪ {m + a + b − 1}) = D(M ) ∪ {m + a + b − 1}, the set M ∪ {m + a + b − 1} is an optimal configuration of cardinality r + 1, whose shadow fills the whole ground.…”
Section: Corollary 36 the Shadows Of Ordered (S M R)-amenable Setsmentioning
confidence: 99%