Disclosed is an electronic device including: a display; a detector that detects contact or proximity between an operating body and a detection surface; multiple light emitters that are provided at a position corresponding to the detector, and cause the detection surface to emit light; and at least one processor. The processor performs control to link displaying regarding at least part of a content on the display with light emission of at least part of the light emitters.

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.

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.

A keyless synthesizer t can stimulate all three senses (hearing, muscle movement and visual) at once in patients born with C.H.A.R.G.E. syndrome while they play and, at the same time, enjoy and have fun with the device. A keyless synthesizer operational by a single hand of the user includes an ultrasound range sensor responsive to the distance d of a user's hand from the sensor for generating a sensor signal corresponding to the distance d. A programmable microcontroller programmed to convert the sensor signal to one of a plurality of discrete signals. A synthesizer is responsive to each discrete signal for generating a discrete tone. A multi-color generator is responsive to each discrete signal for generating a discrete color so that for each discrete signal corresponding to a distance d both a discreet tone and an associated discreet color are generated.

A capacitive musical instrument includes an instrument body having a space, the space including at least one plate to separate the space into at least two areas for holding ingredients of a food object, a plurality of inputs that each receive a capacitive signal from a corresponding one of the ingredients of the food object when the ingredients are touched by a user, a touch capacitive shield connected to the plurality of inputs, a memory that stores audio signal data that corresponds to each of the plurality of inputs, a controller that receives the capacitive signals from the plurality of inputs, converts the capacitive signals into audio signals based on the audio signal data stored in the memory, and outputs the audio signals to an output that generates sound based on the audio signals.

Described herein are embodiments of sensorized spherical input and output devices, systems, and methods for capturing gestural input from a user's physical interactions with a spherical device, including tossing, bouncing and spinning. In one embodiment, the spherical input and output device includes force sensors in a configuration to capture a variety of user gestures with the sphere. A microprocessor receives sensor input and transmits the sensor data to receiving devices which include computer software to translate the sensor signals to audio output, visual output, or various functions on receiving devices. Embodiments of the invention include the integration of inertial measurement units (IMUs), which may include a combination of accelerometers, gyroscopes and magnetometers to capture complex user gestures involving motion, direction and spin of the sensorized sphere in three dimensional space.

Described herein are embodiments of electronic sensorized spherical input and output devices, systems, and methods for capturing gestural input from a user's physical interactions with a spherical device. In one embodiment, the spherical input and output device includes a number of sensors along the surface area of the sphere in a configuration conforming to a user's fingers and hands. A microprocessor receives sensor input and transmits the sensor signals to receiving devices which include computer software to translate the sensor signals to audio output, visual output, or various functions on receiving devices. Additional embodiments of the invention include binary modifier functions which allow the user to trigger a number of different outputs for the sensorized sphere, such as volume control, tempo, sample playback, LED lights, game modes, and other functions. Other embodiments include the integration of inertial measurement units (IMUs), which may include a combination of accelerometers, gyroscopes and magnetometers to capture complex user gestures involving motion, direction and spin of the sensorized sphere to provide unique output signals.

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.

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.

The invention relates to the field of plucked string musical instruments, specifically to designs of electric musical instruments which transform mechanical vibration of strings into electrical signals, more particularly to compact electronic guitars, and can be used in portable electronic guitars. The application of the invention claimed allows to create a compact electronic guitar that can be quickly assembled/disassembled, while the string elasticity level remains the same in both disassembled and assembled states (making the guitar immediately available for use once the parts of the body have been connected) and to provide the possibility to obtain information about vibrations and excursions of the strings located on the neck occurring as a result of using various playing techniques requiring certain actions to be taken in relation to the strings located on the neck, such as hitting, displacing the pressed string sideward, sudden pressing down of the string and sudden releasing of the pressed string, moving the finger along the string, either pressed or not. This provides the possibility to use a larger number of events occurring with the string to generate acoustic oscillations.