Finger-tracking systems and methods for virtual instruments playback. The described system tracks the position of user's ten fingers on a projection surface and can be used to play virtual instruments such as virtual piano, drums, and bells. The system tracks the movement of user's ten fingers while keeping them free of encumbrance or excessive postural constraints. More specifically, in one or more embodiments, a coded light based projector is used to send out location signal onto a flat surface, and ten light sensors are mounted on user's fingers to receive these signals and locate user's fingers. Based on their locations and relative distance to a fixed point, a printed music instrument can be used for virtual instrument music playback. With the described tracking system, various embodiments of virtual music instruments may be implemented, including a system and method for virtual piano playing as well as virtual Chinese bell playing on printed keyboard and printed Chinese bell set.

A optoelectronic pickup for a musical instrument includes at least one light source which directs light to impinge a string of the musical instrument in at least one photoreceiver located to detect the reflected light, so as to generate an electrical signal that is responsive to string vibrations. A number of dissimilar filter approaches are included to control undesired effects of spurious light, the filter approaches may be structure-based, signal processing-based, and/or optics-based.

A optoelectronic pickup for a musical instrument includes at least one light source which directs light to impinge a string of the musical instrument in at least one photoreceiver located to detect the reflected light, so as to generate an electrical signal that is responsive to string vibrations. A number of dissimilar filter approaches are included to control undesired effects of spurious light, the filter approaches may be structure-based, signal processing-based, and/or optics-based.

An optoelectronic pickup for a musical instrument includes at least one light source which directs light to impinge a sound generating element of the musical instrument in at least one photoreceiver located to detect the reflected light, so as to generate an electrical signal that is responsive to sound generating element movement.

An optoelectronic pickup for a musical instrument includes at least one light source which directs light to impinge a sound generating element of the musical instrument in at least one photoreceiver located to detect the reflected light, so as to generate an electrical signal that is responsive to sound generating element movement.

Bowing platforms are disclosed for use in playing a bowed musical instrument without reliance on strings. A bowing platform includes a support and a track that replace the strings, bridge, and tailpiece on a conventional bowed instrument, to provide an alternative vibrational bowing surface. The bowing platform can be attached to a conventional fingerboard or to the body of the instrument. In one aspect, the bowing platform is useful as a bow guide to improve bow technique by restricting the player's bow angle to be within a desirable range, while still allowing for natural arm movement. The bowing platform can be further equipped with piezoelectric sensors to sense bowing motion and to create sound electronically in response to the sensed motion. A stringless bowed instrument includes a bowing platform, bowing sensors, and pitch sensors that sense finger placement along the fingerboard.

Bowing platforms are disclosed for use in playing a bowed musical instrument without reliance on strings. A bowing platform includes a support and a track that replace the strings, bridge, and tailpiece on a conventional bowed instrument, to provide an alternative vibrational bowing surface. The bowing platform can be attached to a conventional fingerboard or to the body of the instrument. In one aspect, the bowing platform is useful as a bow guide to improve bow technique by restricting the player's bow angle to be within a desirable range, while still allowing for natural arm movement. The bowing platform can be further equipped with piezoelectric sensors to sense bowing motion and to create sound electronically in response to the sensed motion. A stringless bowed instrument includes a bowing platform, bowing sensors, and pitch sensors that sense finger placement along the fingerboard.

An optoelectronic pickup for a musical instrument includes at least one light source which directs light to impinge a sound generating element of the musical instrument in at least one photoreceiver located to detect the reflected light, so as to generate an electrical signal that is responsive to sound generating element movement.

An optoelectronic pickup for a musical instrument includes at least one light source which directs light to impinge a sound generating element of the musical instrument in at least one photoreceiver located to detect the reflected light, so as to generate an electrical signal that is responsive to sound generating element movement.

A device and method for an amplitude modulated optical pickup for a stringed instrument are disclosed. A first optical source comprising a first output signal comprising a first carrier frequency is provided and a first photodetector is in optical communication with the first optical source. A vibrating element such as a string on a musical instrument is disposed in an optical path between the first optical source and the first photodetector whereby a vibration of the element varies and modulates an amplitude of the first output signal received by the photodetector that is proportional to an element vibration amplitude and is at the same frequency as the element vibration frequency. An amplitude modulated (AM) photodetector signal output is generated from the first photodetector. The resultant signal is then demodulated with appropriate circuitry to produce a substantially noise free electronic signal representative of the element vibration frequency.