Abstract
The lowest fingerings of the saxophone can lead to several different regimes, depending on the musician’s control and the characteristics of the instrument. This is explored in this paper through a physical model of saxophone. The harmonic balance method shows that for many combinations of musician control parameters, several regimes are stable. Time-domain synthesis is used to show how different regimes can be selected through initial conditions and the initial evolution (rising time) of the blowing pressure, which is explained by studying the attraction basin of each stable regime. These considerations are then applied to study how the produced regimes are affected by properties of the resonator. The inharmonicity between the first two resonances is varied in order to find the value leading to the best suppression of unwanted overblowing. Overlooking multistability in this description can lead to biased conclusions. Results for all the lowest fingerings show that a slightly positive inharmonicity, close to that measured on a saxophone, leads to first register oscillations for the greatest range of control parameters. A perfect harmonicity (integer ratio between the first two resonances) decreases first register production, which adds nuance to one of Benade’s guidelines for understanding sound production. Thus, this study provides some a posteriori insight into empirical design choices relative to the saxophone.
Highlights
A classic endeavor in musical acoustics consists in the systematic study of sound production features of a musical instrument
A simple test-case of scenario number two is presented to study sound production, where the blowing pressure increases from 0 to its final value over different durations. We show how this duration can influence the final regime in multistability regions, and explain these results by presenting the attraction basin of each regime
The regularization controlled by parameter g is necessary for the system to fit the quadratic formalism required by the implementation of the harmonic balance method and asymptotic numerical continuation in the MANLAB software, which produces the bifurcation diagrams of the present article
Summary
A classic endeavor in musical acoustics consists in the systematic study of sound production features of a musical instrument. Artificial mouths have been robotized to provide a complete mapping of the instrument’s behavior, aiming at understanding how the instrument must be acted on to produce different sounds [6, 7] or describing the influence of an acoustical parameter of the resonator on sound production [8] The objective of this last study is shared by other works using a rather different approach to systematic description of the instrument’s behavior: using a physical model. We show how this duration can influence the final regime in multistability regions, and explain these results by presenting the attraction basin of each regime. This provides an interpretation to the inharmonicity value measured on the saxophone by showing that it corresponds to an optimum in periodic regime production
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