An electronic percussion instrument and sound production control method thereof are provided. In an electronic cymbal, the output of a musical sound is controlled in accordance with the results of detection from a strike sensor when the strike sensor detects a strike on a striking surface. While the musical sound is output, if a user touches the striking surface, an electrostatic capacitance sensor outputs an output value in accordance with the contact condition so that the musical sound is attenuated in accordance with the output value while being output. Therefore, the user can attenuate the musical sound being output in accordance with the contact conditions on the striking surface, thereby silencing the musical sound by way of the action similar to that of the acoustic cymbal choke that is the action of touching the striking surface.

Provided is an electronic percussion instrument that can facilitate determination of contact of a detection target conductor with a head. An electronic percussion instrument includes: a tubular body portion with an end surface in an axial direction open; a head that covers the open end surface in the axial direction of the body portion and has a front surface adapted to be hit; and a capacitive sensor that has an electrode disposed on a rear surface side of the head, in which the head includes an electrically isolated conductive head, and no conductor connected to a reference potential point is provided between the front surface of the head and the electrode. In this manner, it is possible to facilitate determination of contact of the detection target conductor with the head.

An electronic stringed instrument includes: at least one linear string member to be plucked by a user; a plurality of string support members each supporting the string member at different positions in a longitudinal direction of the string member, each of the string support members being individually deformable in accordance with a plucking of the string member by the user; a plurality of sensors that output signals indicating respective deformation states of the plurality of string support members, wherein the respective deformation states of the plurality of string support members may be different from each other depending on a way the string member is plucked; and at last one processor configured to generate a musical tone control signal based on the signals output from the plurality of sensors.

Provided is an electronic percussion instrument that is capable of simulating a playing technique for an acoustic percussion instrument. A tubular body part is opened on an axial end surface, and a head is attached to the axial end surface to be struck on the front surface. A capacitance sensor includes an electrode that generates a capacitance with respect to a detected conductor, such as a human body, positioned on the front surface side of the head. Because the capacitance sensor detects a change of a capacitance corresponding to a distance between the electrode and the detected conductor, whether the detected conductor approaches (contacts) the head or presses the head can be determined. As a result, the playing technique for the acoustic percussion instrument is simulated.

A stringed musical instrument includes: a musical instrument body configured such that a string is attached thereto; a pickup configured to: i) detect vibration of the string and ii) output a string vibration signal according to the vibration; a detection sensor that is: i) attached to the musical instrument body and ii) configured to output a detection signal according to a force applied to the musical instrument body; and a controller that is attached to the musical instrument body, and is configured to output, based on the detection signal, a control signal configured to control an operation of an effector configured to impart an effect to the string vibration signal.

A musical instrument, for example, a keyboard guitar, includes a body, an elongated neck coupled to the body, neck keys disposed on the elongated neck, and an output for transmitting an electrical signal generated by the musical instrument. Activation of each neck key generates an electrical signal at the output representing a pitch associated with a musical note. The musical instrument may also include body keys disposed on the body, and a strum bar that generates an electrical signal at the output representing a pitch associated with a musical note based on which of the body keys are activated during activation of the strum bar. Further, the musical instrument may include a continuous graphic image spanning the front face of the body and the body keys, forming a continuous pattern that is unbroken across a transition between key surfaces of the body keys and the front face of the body.

A pickup unit for an electrical stringed instrument, such as an electric guitar, includes a housing structured to be connected to the stringed instrument and a number of pickups provided within the housing, each pickup being structured to produce signals corresponding to vibration of one or more strings of the stringed instrument. The pickup unit also includes a number of capacitive touch electrodes provided on or within the housing, wherein the pickup unit is structured to generate control signals in response to a user of the pickup unit touching one or more of the number of capacitive touch electrodes, the control signal being configured to control processing of the signals produced by the number of pickups.

A keyboard apparatus according to an embodiment includes a keyboard and a mutual capacitance proximity sensor. The keyboard includes a first key and a second key arranged in an array direction with respect to the first key. The proximity sensor includes a first electrode having a portion extending from at least a first area below the first key to a second area below the second key, a second electrode arranged in the first area, and a third electrode arranged in the second area. The proximity sensor is a mutual capacitance type sensor and is configured to use a change in capacitance between the first electrode and the second electrode and a change in capacitance between the first electrode and the third electrode.

A button unit is suspended vertically and has a button body with an actuating surface and a shaft extending downwardly therefrom. An X-Y sensor unit is arranged below the button body for detecting X-Y positions on the actuating surface. The X-Y sensor unit has one opening such that the shaft can move therethrough. One transfer element is elastically suspended below the shaft and moved downwardly upon downward movement of the shaft. A Z sensor unit is arranged below the transfer element. The Z sensor unit has a detection element for detecting downward movement of the transfer element. The X-Y sensor unit may include a capacitive sensor. The Z sensor unit may include an inductive sensor, a capacitive sensor, or a magnetic sensor. The shaft and the extension may include a translucent material to form a light guide for illuminating the button body via a light source.

A musical instrument, for example, a keyboard guitar, includes a body, an elongated neck coupled to the body, neck keys disposed on the elongated neck, and an output for transmitting an electrical signal generated by the musical instrument. Activation of each neck key generates an electrical signal at the output representing a pitch associated with a musical note. The musical instrument may also include body keys disposed on the body, and a strum bar that generates an electrical signal at the output representing a pitch associated with a musical note based on which of the body keys are activated during activation of the strum bar. Further, the musical instrument may include a continuous graphic image spanning the front face of the body and the body keys, forming a continuous pattern that is unbroken across a transition between key surfaces of the body keys and the front face of the body.