A system for emulating a physical audio system comprises a user interface (UI) and a digital model of the physical audio system. The UI comprises virtual controls for changing virtual control settings (e.g., a virtual volume control for changing a virtual volume setting, etc.). A change in a virtual control setting produces a change to the output of the digital model. Because the digital model emulates the behavior of the physical audio system, changes to the model output in response to changes in the virtual control settings correspond to changes in the audio output in response to changes in the physical control settings. For example, if the physical audio system is an audio amplifier with control knobs, then the virtual controls will affect the output of the digital model like the control knobs affect the audio output of the audio amplifier.

Disclosed is a device for introducing loudspeaker harmonic nonlinearities to a signal without outputting the signal as audio or sound through a loudspeaker and recording the output audio or sound. The device includes a resistive element and an inductive element. The resistive element includes a hollow core and a first wire wound around the hollow core in a first direction. The inductive element is inserted within the hollow core of the resistive element, and includes a metal-based core and a second wire wound around the metal-based core in an opposite second direction. A signal or current is first passed through the inductive element, creating electromagnetic distortion between the resistive element and the inductive element that simulates inductance of the loudspeaker voice-coil. The electromagnetic distortion alters the signal by introducing harmonic nonlinearities into the signal.

Disclosed is a console bed mechanism to provide access to controls on console bed transported in a transport case. The console bed mechanism may include a base plate positioned in the transport case and comprising a bearing, an upper plate secured to the console bed and connected via the bearing to the base plate, a rotation arm having a lower end mounted to the base plate and an upper end mounted to the upper plate, the rotation arm configured to rotate the console bed between: a transport position in which the console bed is at least partially in the transport case, and an operation position in which the console bed is at least partially above the transport case and is positioned to be operated, and also including an elevation arm that raises the console bed and having a lower end mounted to the transport case and an upper end secured to the base plate.

An amplifier and a method of outputting a waveform of a music signal capable of outputting a waveform of a music signal exceeding a power supply voltage is provided. An amplifier includes a power supply, an input terminal for a music signal, an amplifying circuit which amplifies the music signal using the power supply, and a jumping-up circuit which is connected to an output end of the amplifying circuit and outputs a waveform exceeding a voltage value of the power supply.

A neural network is trained to digitally model a reference audio system. Training is carried out by repeatedly performing a set of operations. The set of operations includes predicting by the neural network, a model output based upon an input, where the output approximates an expected output of the reference audio system, and the prediction is carried out in the time domain. The set of operations also includes applying a perceptual loss function to the neural network based upon a determined psychoacoustic property, wherein the perceptual loss function is applied in the frequency domain. Moreover, the set of operations includes adjusting the neural network responsive to the output of the perceptual loss function. A neural model file is output that can be loaded to generate a virtualization of the reference audio system.

The method for adapting a sound converter to a reference sound converter includes the sound converter having a first linear transfer function with a first frequency response, a second linear transfer function with a second frequency response, and a trivial nonlinearity. The sound converter has a non-linear transfer function corresponding to the frequency response from combination of the first linear transfer function, the trivial nonlinearity, and the second linear transfer function. A first frequency spectrum of the reference sound converter is determined at a low input level. A second frequency spectrum of the reference sound converter is determined at a high input level. The second determined frequency spectrum is used as the second frequency response in the second linear transfer function, and the division of the first frequency spectrum by the second frequency spectrum is used as the first frequency response in the first linear transfer function.

A guitar pickup is provided that is divided into a plurality of segments that can be selectively activated by switching to produce tonal variations.

Various systems and methods are disclosed to allow users to conveniently control characteristics of sounds generated by musical instruments. Exemplary systems include a control unit in communication with any number of audio processing devices (APDs). The control unit may be operable to transmit control signals to each of the APDs, wherein the control signals include settings information relating to one or more APD processing parameter values. The control unit may be further operable to receive an audio signal generated by an instrument and transmit the same to the APDs. Accordingly, upon receiving the control signal and the audio signal from the control unit, the APDs may update their processing parameters based on relevant settings information contained in the control signal and process the audio signal into a processed audio signal, based on the updated processing parameters.

An accessory for modifying sound output of a musical instrument. The body of the instrument has a soundboard. The accessory includes a sound sensor, an actuator, a fastener, and a controller. The sound sensor engages the body and senses vibration of the body representing the sound output of the musical instrument. The actuator engages the soundboard and deforms the soundboard of the musical instrument so as to modify the sound output of the musical instrument. The sound sensor is preferably arranged distally to the actuator. The fastener engages the accessory to the musical instrument, to locate the actuator against the soundboard of the musical instrument. The controller is connected to the actuator and the sound sensor for receiving and analysing the sound output sensed by the sound sensor, and controlling the actuator in dependence on the sound output sensed by the sound sensor.

Disclosed is a configurable dual vacuum tube triode amplifier. The amplifier comprises two vacuum tube triodes and a user configurable switching component. The user configurable switching component can be positioned into at least a first position and a second position to modify an arrangement of the two vacuum tube triodes to provide varying tonal characteristics of the amplifier. Positioning the user configurable switching component in the first position arranges the two vacuum tube triodes in a cascode configuration to achieve a tonal characteristic of a vacuum tube pentode. Positioning the multi-position user switch in the second position arranges the two vacuum tube triodes in either a single vacuum tube triode configuration to achieve a tonal characteristic of a single vacuum tube triode operating alone or two vacuum tube triodes operating in a parallel configuration to achieve the tonal characteristics of two vacuum tube triodes operating in parallel.