The present invention provides an acoustic apparatus which can be attached to the musical instrument without adding processing to reproduce. After the acoustic apparatus is detached, the user can enjoy playing the musical instrument itself same as before the acoustic apparatus is attached. An acoustic apparatus 1 has a vibration generator 2, a support body 3, a locking portion 4 and a drive circuit 5. The acoustic apparatus 1 is locked to a neck holder 301 of a stand 300, and a diaphragm 201 of the vibration generator 2 is arranged to face a sound hole 109 of a guitar 100. The drive circuit 5 drives the vibration generator 2 according to the inputted sound signal to resonate a sound box 103. Thus, rich sound can be reproduced.

The present invention provides an acoustic apparatus which can be attached to the musical instrument without adding processing to reproduce. After the acoustic apparatus is detached, the user can enjoy playing the musical instrument itself same as before the acoustic apparatus is attached. An acoustic apparatus 1 has a vibration generator 2, a support body 3, a locking portion 4 and a drive circuit 5. The acoustic apparatus 1 is locked to a neck holder 301 of a stand 300, and a diaphragm 201 of the vibration generator 2 is arranged to face a sound hole 109 of a guitar 100. The drive circuit 5 drives the vibration generator 2 according to the inputted sound signal to resonate a sound box 103. Thus, rich sound can be reproduced.

Embodiment apparatus and associated methods relate to adapting an actuator to adjust the tension of a musical instrument string, configuring a sensor to detect vibration propagated through the musical instrument body, configuring a noise removal filter to remove an undesired signal from vibration propagated through the musical instrument body, and automatically tuning the musical instrument based on adjusting the musical instrument string tension by the actuator while removing the undesired signal, until the fundamental frequency propagated through the instrument body by the vibration of the musical instrument string is within a predetermined tolerance of a reference frequency. In an illustrative example, the undesired signal may be actuator vibration. In some embodiments, actuator vibration spectral content may vary as a function of actuator torque, and, the noise removal filter may be adapted in real time. Various examples may advantageously provide faster and more accurate stringed musical instrument tuning.

Embodiment apparatus and associated methods relate to adapting an actuator to adjust the tension of a musical instrument string, configuring a sensor to detect vibration propagated through the musical instrument body, configuring a noise removal filter to remove an undesired signal from vibration propagated through the musical instrument body, and automatically tuning the musical instrument based on adjusting the musical instrument string tension by the actuator while removing the undesired signal, until the fundamental frequency propagated through the instrument body by the vibration of the musical instrument string is within a predetermined tolerance of a reference frequency. In an illustrative example, the undesired signal may be actuator vibration. In some embodiments, actuator vibration spectral content may vary as a function of actuator torque, and, the noise removal filter may be adapted in real time. Various examples may advantageously provide faster and more accurate stringed musical instrument tuning.

Processing implemented by computer means of sound data output by at least one sensor and activation of at least one actuator of an acoustically radiating structure. The sensor senses an acoustic signal output by the vibration of the radiating structure. The radiating structure bears at least one actuator controlled by the computer means and is thus involved in the vibration of the radiating structure. In particular, the method comprises the steps of: a) measuring a transfer function of the actuator, radiating structure and sensor assembly, b) controlling activation of the actuator so as to make the radiating structure vibrate, according to a selected setpoint: taking account of the transfer function measured, and taking account of the acoustic signal sensed by the sensor in feedback mode.

Processing implemented by computer means of sound data output by at least one sensor and activation of at least one actuator of an acoustically radiating structure. The sensor senses an acoustic signal output by the vibration of the radiating structure. The radiating structure bears at least one actuator controlled by the computer means and is thus involved in the vibration of the radiating structure. In particular, the method comprises the steps of: a) measuring a transfer function of the actuator, radiating structure and sensor assembly, b) controlling activation of the actuator so as to make the radiating structure vibrate, according to a selected setpoint: taking account of the transfer function measured, and taking account of the acoustic signal sensed by the sensor in feedback mode.

A stringed instrument pickup with multiple selectable coils can be utilized in a system to provide a diverse range of sound characteristics from at least one moving string under tension. A first wire can be connected to a first terminal of a first bobbin body prior to the first wire being wound around the first bobbin body a first number of times and then connecting the first wire to a second terminal of the first bobbin body. A second wire may be connected to the second terminal of the first bobbin body before winding the second wire around the first bobbin body a second number of times and then connecting the second wire to a third terminal of the first bobbin body. The first bobbin body is subsequently mounted onto a stringed instrument.

A stringed instrument pickup with multiple selectable coils can be utilized in a system to provide a diverse range of sound characteristics from at least one moving string under tension. A first wire can be connected to a first terminal of a first bobbin body prior to the first wire being wound around the first bobbin body a first number of times and then connecting the first wire to a second terminal of the first bobbin body. A second wire may be connected to the second terminal of the first bobbin body before winding the second wire around the first bobbin body a second number of times and then connecting the second wire to a third terminal of the first bobbin body. The first bobbin body is subsequently mounted onto a stringed instrument.

The musical instrument includes: a pickup that acquires an electric sound signal corresponding to a sound performed on the musical instrument; effector circuitry that imparts an effect to the acquired electric sound signal; a vibrator that produces mechanical vibration corresponding to the effect-imparted sound signal; and a transmission device that transmits the mechanical vibration, produced by the vibrator, to the body of the musical instrument with a characteristic having a fundamental frequency region of the musical instrument suppressed. The electric sound signal corresponding to the performed sound is imparted with an effect, the vibrator is driven by the effect-imparted sound signal, and a mechanical vibration sound is generated from the body of the musical instrument. The thus-generated mechanical vibration sound is audibly generated from the body as a vibration sound additional to the performed sound, which allows a user to experience a performance feeling that has never existed before.

A transducer apparatus for a labrosone is disclosed, the labrosone having a labrosone resonant chamber. A labrosone speaker delivers a sound signal to the labrosone resonant chamber. A labrosone microphone receives a resultant sound from the labrosone resonant chamber. A mouthpiece microphone receives sound from a labrosone mouthpiece. An electronic processor is connected to the labrosone speaker, and receives signals from the labrosone microphone and the mouthpiece microphone. The electronic processor generates an excitation signal which is delivered as an acoustic excitation signal to the labrosone resonant chamber by the labrosone speaker. The electronic processor uses the signals from the labrosone microphone and the mouthpiece microphone to determine a desired musical note which a player of the labrosone wishes to play. The electronic processor then synthesizes and outputs the desired musical note to an output device, whereby the musical note is played audibly and/or displayed visually to the player.