Semi-Automatic Flute Robot and Its Acoustic Sensing

Abstract

Flute performance requires mastery of complex fingering combinations and register-dependent embouchure control, particularly jet offset adjustment for low-register production. Existing haptic and semi-automated systems do not address both aspects simultaneously through mechanical actuation. To our knowledge, no prior system fully automates fingering while mechanically assisting low-register tone production without requiring embouchure control. We developed a semi-automatic flute robot with an automatic fingering mechanism: fourteen servo motors actuate all keys via wire-based and rack-and-pinion drives in response to MIDI input, enabling performers to produce complete musical pieces through airflow alone. A jet offset assist mechanism rotates the head joint by a calibrated $22^\circ$ during low-register passages, shifting the jet offset toward a low-register configuration without modifying the instrument or embouchure. Fundamental frequency estimation confirmed correct pitch production across the chromatic range (C4--C7) and during musical performance. All key and lever movements were completed within 77.50~ms, corresponding to tempo capacity exceeding standard requirements. Harmonic analysis ($Δ\mathrm{SPL} = \mathrm{SPL}_2 - \mathrm{SPL}_3$) showed a consistent increase in $Δ$SPL for all low-register notes when activated, consistent with the intended jet offset shift. Head joint rotation completed within 40.00~ms. These results demonstrate mechanical feasibility of integrating automated fingering and register-dependent jet offset assistance under controlled conditions.

Figures (20)

• Figure 1: The flute has three main sections: the head joint, middle joint, and foot joint. The head joint features a lip plate with a central embouchure hole. The body and foot joint are equipped with multiple keys and levers; pressing a key closes its tone hole, while pressing a lever opens the corresponding key.
• Figure 2: Semi-automatic flute robot. (a) Overview of the system. Red highlights: automatic fingering mechanism (middle and foot joints). Blue highlights: jet offset assist mechanism (head and middle joints). (b) Control flow of the system. Both mechanisms are driven by servo motors controlled via MIDI messages from a PC.
• Figure 3: Schematic of wire-based key actuation. The wire connects the key cover to the servo horn; motor rotation pulls the wire and presses the key.
• Figure 4: Automatic fingering mechanism. (a) Front view: servo motors are mounted on an acrylic body, with the flute secured on top. (b) Rear view: a hand-placement grip is positioned to support a natural playing posture.
• Figure 5: Key cover structure. (a) Cover attached to key. (b) Underside: three locking tabs for attachment; wire passes through one tab and is fixed with a crimp bead.