In scale (music) theory, a maximally even set (scale) is one in which every generic interval has either one or two consecutive integers specific intervals-in other words a scale whose notes (pcs) are "spread out as much as possible." This property was first described by John Clough and Jack Douthett.[1] Clough and Douthett also introduced the maximally even algorithm. For a chromatic cardinality c and pc-set cardinality d a maximally even set is
where k ranges from 0 to d − 1 and m, 0 ≤ m ≤ c − 1 is fixed and the bracket pair is the floor function. A discussion on these concepts can be found in Timothy Johnson's book on the mathematical foundations of diatonic scale theory.[2] Jack Douthett and Richard Krantz introduced maximally even sets to the mathematics literature.[3][4]
Second-order maximal evenness is maximal evenness of a subcollection of a larger collection that is maximally even. Diatonic triads and seventh chords possess second-order maximal evenness, being maximally even in regard to the maximally even diatonic scale—but are not maximally even with regard to the chromatic scale. (ibid, p.115) This nested quality resembles Fred Lerdahl's[6] "reductional format" for pitch space from the bottom up:
Carey, Norman and Clampitt, David (1989). "Aspects of Well-Formed Scales", Music Theory Spectrum 11: 187–206.
References
^Clough, John; Douthett, Jack (1991). "Maximally Even Sets". Journal of Music Theory. 35 (35): 93–173. doi:10.2307/843811. JSTOR843811.
^Johnson, Timothy (2003). Foundations of Diatonic Theory: A Mathematical Based Approach to Musical Fundamentals. Key College Publishing. ISBN1-930190-80-8.
^Douthett, Jack; Krantz, Richard (2007). "Maximally Even Sets and Configurations: Common Threads in Mathematics, Physics and Music". Journal of Combinatorial Optimization. 14 (4): 385-410. doi:10.1007/s10878-006-9041-5. S2CID41964397.
^Douthett, Jack; Krantz, Richard (2007). "Dinner Tables and Concentric Circles: A harmony of Mathematics, Music, and Physics". College Mathematics Journal. 39 (3): 203-211. doi:10.1080/07468342.2008.11922294. S2CID117686406.
^Carey, Norman; Clampitt, David (1989). "Aspects of Well-Formed Scales". Music Theory Spectrum. 11 (2): 187–206. doi:10.2307/745935. JSTOR745935.
^Douthett, Jack (2008). "Filter Point-Symmetry and Dynamical Voice-Leading". Music and Mathematics:Chords, Collections, and Transformations. Eastman Studies in Music: 72-106. Ed. J. Douthett, M. Hyde, and C. Smith. University of Rochester Press, NY. doi:10.1017/9781580467476.006. ISBN9781580467476. ISBN1-58046-266-9.