An electronic percussion device has a plurality of triggerable actuators, in the form of any of pads, external trigger inputs or foot switches, that may be organized into synchronized groups, and has an operational mode in which triggering of any actuator within the synchronized group initiates playback of audio events or execution of control functions associated with other of the actuators within the synchronized group in one of multiple different synchronization orders, e.g. one at a time, all simultaneously, random or in a predefined or user-defined consecutive order.

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.

A telescopically adjustable board for mounting musical instrument pedals includes a first inner rail-outer rail pair. The outer rail has a tubular shape defining a hollow track and the inner rail is slidably received within the hollow track with the outer rail circumscribing the inner rail. Each of the inner rail and outer rail is configured to fixably attach to a musical effects pedal. The board may include a second inner rail-outer rail pair substantially parallel to and spaced from the first inner rail-outer rail pair. The inner rails are slidable relative to the outer rails between a fully extended position and a fully retracted position to adjust the longitudinal length of the board.

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 telescopically adjustable board for mounting musical instrument pedals includes a first inner rail-outer rail pair. The outer rail has a tubular shape defining a hollow track and the inner rail is slidably received within the hollow track with the outer rail circumscribing the inner rail. Each of the inner rail and outer rail is configured to fixably attach to a musical effects pedal. The board may include a second inner rail-outer rail pair substantially parallel to and spaced from the first inner rail-outer rail pair. The inner rails are slidable relative to the outer rails between a fully extended position and a fully retracted position to adjust the longitudinal length of the board.

A step sequencer with a four by sixteen grid of buttons is disclosed. The sequencer is used to generate patterns of sounds on different channels. The sequencer can be used as a hardware controller to control music production software. The grid of the sequencer emulates the virtual grid generated in a graphical user interface by the music production software. The grid of the hardware controller is used to control the corresponding grid on the graphical user interface.

A percussion instrument with a plurality of sound zones comprising a main body defining an inner space containing a volume of air, the main body including an upper surface and a lower surface that are joined along their perimeters by a side wall, the upper surface including a sound hole and functioning as a soundboard, and an inner bracing attached directly to an inner face of the soundboard, the inner bracing configured to define a plurality of sound zones across the soundboard, each sound zone having a specific tonal quality related to the surface area comprising the sound zone.

The object of the invention is a device for digital control of analogue sound processing, the purpose of which is an upgrade of a classic analogue sound processing device. The device comprises at least one external regulation element, an analogue effect, at least one digital regulation element, at least one control button, at least one memory location for storing positions of the external regulation elements, and a control circuit with a pre-downloaded software. The device according to the invention digitally controls analogue sound processing, wherein the external appearance of the device and its handling are as similar to the existing known devices as possible and the sound processing is identical, analogue, as with the existing devices. It has additional options enabled: a) the device may be set from pre-set memory locations that contain combinations of positions of the regulation elements which determine sound alteration; b) storage of combinations of positions of the regulation elements into the memory for subsequent use; c) remote control of the device by an external device, for instance by an adequate application downloaded onto a phone, tablet or computer; d) downloading of combinations of positions of the regulation elements to the memory of the device according to the invention by an external device.

Embodiments are directed to a musical instrument having buttons, where the buttons determine the magnitude of the interval by which the melody will jump from the last note played. With a small number of interval buttons and an up/down strum bar, embodiments can play almost any melody and more notes than a piano. One embodiment is directed to an interval-based guitar including fret buttons whose input signals are used to calculate the interval by which to change the pitch of the prior note. Providing input via a strum bar or a sensor, a new note is generated by adding or subtracting the interval to/from the prior note to generate a new note.

Embodiments are directed to a musical instrument having buttons, where the buttons determine the magnitude of the interval by which the melody will jump from the last note played. With a small number of interval buttons and an up/down strum bar, embodiments can play almost any melody and more notes than a piano. One embodiment is directed to an interval-based guitar including fret buttons whose input signals are used to calculate the interval by which to change the pitch of the prior note. Providing input via a strum bar or a sensor, a new note is generated by adding or subtracting the interval to/from the prior note to generate a new note.