An electronic wind instrument and a control method thereof are provided. The electronic wind instrument includes an acquisition unit which acquires an operation performed on a playing operator, a breathing detection unit which detects breathing, and a control unit which generates a musical sound signal on the basis of at least one of the breathing that has been detected and the operation acquired by the acquisition unit, in which the control unit switches a first mode for generating a musical sound signal with a detection of the breathing as a condition and a second mode for generating the musical sound signal on the basis of the operation regardless of whether or not the breathing has been detected, on the basis of a detection result of the breathing.

The present invention discloses a silent digital practice horn, useable with or without a mouthpiece, characterized by a processor and communicating means enabling wireless connection with DAW application via MIDI-USB or Bluetooth modules, and thereby connection with computers or smartphones, speakers or headphones thereof. The invention also discloses a digital practice shortened either Saxophone-like or Clarinet-like horn, wherein one or more of the following is held true: octave key is configured to change range; High E key (Eb-like horn) is configured to shift tonal range up; C key is configured to shift to normal tonal range; Bb key (Bb-like horn) is configured to shift tonal range down; at least one of the following, F key, E/F♯ key and D key is configured to facilitate or change MIDI Channel; Additional F♯ key is configured to power the horn Off; Eb/D3 Key and low C key, when pressed together, enters the processor to a “Command Mode”. The present invention further discloses a practice horn that comprises a siphon which causes saliva and moisture to run down a pipe inside the instrument and to drip out of a “Moisture Outlet” in a bottom cap located at the distal most portion of the horn.

The presence of saxophonists furthering their musical horizons by playing keyboard instruments inspires the invention of a novel device to connect a light-weight keyboard or MIDI grid controller to a saxophone to facilitate the convenient and rapid switching between playing either instrument. Battery power and Bluetooth technology combine with innovations in plastics technology to facilitate the creation of strong, lightweight structures to facilitate such a device. With the addition of looping software on a laptop computer, a saxophonist so equipped can create music to accompany themselves, obviating the need for other musicians to function as a musical ensemble. This innovation may be the harbinger for other musicians on other single note instruments—trumpet, trombone, violin, etc. to join this trend using either instrument-attached, strap-on or wearable keyboards. This could blend the boundaries between acoustic and electronic instruments, and increase the enjoyment and musical enrichment of musicians and audiences alike.

An electronic instrument includes at least one processor, and the at least one processor is configured to determine, based on previously acquired fingering time information relating to a time required for a fingering operation performed by a performer, a delay set time for confirming a new fingering operation in response to the new fingering operation.

An electronic wind instrument and key operation detection method are provided. The electronic wind instrument includes an instrument body and a plurality of keys which have an operation surface operated by a player's finger and are provided on an external surface of the instrument body. Among the plurality of keys, at least two keys disposed to sandwich or surround a predetermined region comprise restriction parts formed on the operation surfaces. The restriction parts restrict escape of the player's finger from between the at least two keys having the restriction parts formed thereon.

An electronic musical instrument includes an instrument body and a plurality of keys, each of which has an operation surface operated by a player's finger is provided on an external surface of the instrument body. Among the plurality of keys, at least two keys are disposed to be adjacent to each other, and the operation surfaces of the at least two keys are configured to be inclined to descend toward between the at least two keys when viewed from a left-right direction of the electronic musical instrument.

An electronic wind instrument includes a tonguing sensor which detects tonguing, a breath sensor which detects a breath value, a loudspeaker which outputs a musical sound and a processor which controls the musical sound, in which the processor acquires a tonguing value which depends on a tonguing time which is the time which has elapsed after start of the tonguing which is detected by the tongue sensor, decides a silencing effect value which indicates a degree of volume reduction depending on the tonguing value, acquires the breath value which depends on a magnitude of a breath sensor signal which indicates a result of detection by the breath sensor and makes the loudspeaker emit the musical sound whose volume which depends on the breath value is reduced depending on the silencing effect value.

To provide an electronic wind instrument capable of accurately detecting the amount of rotation of a transmission member. An electronic wind instrument whereby contact with an optical sensor by a flat surface of a rear section can be suppressed even when at least a prescribed amount of a reed is bitten, as a result of the flat surface rotating in a direction away from the optical sensor when the rear section of the transmission member rotates in conjunction with displacement of the reed. As a result, the spacing between the facing flat surface and the optical sensor can be set comparatively narrowly in the initial state and the detection sensitivity at the optical sensor increased, thereby enabling accurate detection of the rotation amount of the transmission member (the amount of the reed that is bitten).

A displacement amount detecting apparatus is provided and includes: transmission member, transmitting a displacement on one end side thereof to a displacement on the other end side thereof; a sensor, disposed to face the other end side of the transmission member, and configured to output a value according to a distance between the sensor and the other end side of the transmission member; a calculation device, calculating a value for indicating the distance based on the value output by the sensor and a reference value; and a correction device, correcting the reference value. When the one end side is displaced in a first direction, the other end side is displaced in a second direction opposite to the first direction and away from the sensor. The correction) device is configured to correct the reference value based on the value for indicating the distance calculated by the calculation device.

To provide an electronic wind instrument capable of accurately detecting the amount of rotation of a transmission member. An electronic wind instrument whereby contact with an optical sensor by a flat surface of a rear section can be suppressed even when at least a prescribed amount of a reed is bitten, as a result of the flat surface rotating in a direction away from the optical sensor when the rear section of the transmission member rotates in conjunction with displacement of the reed. As a result, the spacing between the facing flat surface and the optical sensor can be set comparatively narrowly in the initial state and the detection sensitivity at the optical sensor increased, thereby enabling accurate detection of the rotation amount of the transmission member (the amount of the reed that is bitten).