Diatonic Modes can be modeled through automorphisms of the free group F2 stemming from special Sturmian morphisms. Following [1] and [2] we associate special Sturmian morphisms f with linear maps E(f) on a vector space of lattice paths. According to [2] the adjoint linear map E(f)* is closely related to the linear map E(f*), where f and f* are mutually related under Sturmian involution. The comparison of these maps is music-theoretically interesting, when an entire family of conjugates is considered. If one applies the linear maps E(f1),...,E(f6) (for the six authentic modes) to a fixed path of length 2, one obtains six lattice paths, describing a family of authentic common finalis modes (tropes). The images of a certain path of length 2 under the application of the adjoint maps E(f1)*,...,E(f6)* properly matches the desired folding patterns as a family, which, on the meta-level, forms the folding of Guido's hexachord. And dually, if one applies the linear maps E(f1*),...,E(f6*) (for the foldings of the six authentic modes) to a fixed path of length 2, one obtains six lattice paths, describing a family of authentic common origin modes ("white note" modes). The images of a certain path of length 2 under the application of the adjoint maps E(f1*)*,...,E(f6*)* properly match the desired step interval patterns as a family, which, on the meta-level, forms the step interval pattern of Guido's hexachord. This result conforms to Zarlino's re-ordering of Glarean's dodecachordon. © 2013 Springer-Verlag.
CITATION STYLE
Noll, T., & Montiel, M. (2013). Glarean’s dodecachordon revisited. In Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics) (Vol. 7937 LNAI, pp. 151–166). https://doi.org/10.1007/978-3-642-39357-0_12
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