A musical sound signal generation device continuously connects any one of a connected zeroth delay unit and a connected second delay unit to a fractional delay block and connects at least any one of a new zeroth delay unit and a new second delay unit to at least any one of the fractional delay block other than the fractional delay block connected to a new first delay unit in response to setting any one of the connected zeroth delay unit and the connected second delay unit as the new first delay unit, setting a delay unit in a preceding stage of the new first delay unit as the new zeroth delay unit, and setting a delay unit in a subsequent stage of the new first delay unit as the new second delay unit in accordance with a change in a designated tone pitch.

Methods and digital circuits providing frequency correction to frequency synthesizers are disclosed. An FLL digital circuit is provided that is configured to handle a reference frequency that is dynamic and ranges over a multi-decade range of frequencies. The FLL circuit includes a digital frequency iteration engine that allows for detection of disappearance of a reference frequency. When the digital frequency iteration engine detects that the reference frequency signal is not available, the oscillator generated frequency is not corrected, and the last value of the oscillator generated frequency is held until the reference frequency signal becomes available again. This FLL circuit is also preceded by a low-pass filter which is dynamically tuned to the frequency to which the FLL locks, eliminating harmonic components in the original signal which might otherwise cause errors in frequency estimation.

A filter effect imparting device includes a characteristic-variable filter that has a variable filter characteristic corresponding to a coefficient group composed of a plurality of filter coefficients, and a control circuit that changes the coefficient group from a first coefficient group that is set as a start point to a second coefficient group that is set as an end point. The control circuit retains the coefficient group during the change and, in newly setting a third coefficient group as the end point, the control circuit sets the retained coefficient group as the start point.

An effects device for a musical instrument, comprising: an input (18) for receiving a signal from a musical instrument; a control input (7) for receiving a control signal; an output (8, 9) for connecting the device to a sound reproduction device; a memory (30) configured to record the input signal; and a processor (29) configured, upon receiving a control signal, to select a section of the recorded input signal from the memory (30) and to loop it, wherein the processor (29) is configured to overlap a start and end regions of the selected section when looping. A method is also provided for producing an effect for a musical instrument, comprising the steps: a) recording an input signal from a musical instrument into memory (30), b) selecting a section of the recorded input signal and looping it, wherein a start and end regions of the selected segment are overlapping when looping.

An effects device for a musical instrument, comprising: an input (18) for receiving a signal from a musical instrument; a control input (7) for receiving a control signal; an output (8, 9) for connecting the device to a sound reproduction device; a memory (30) configured to record the input signal; and a processor (29) configured, upon receiving a control signal, to select a section of the recorded input signal from the memory (30) and to loop it, wherein the processor (29) is configured to overlap a start and end regions of the selected section when looping. A method is also provided for producing an effect for a musical instrument, comprising the steps: a) recording an input signal from a musical instrument into memory (30), b) selecting a section of the recorded input signal and looping it, wherein a start and end regions of the selected segment are overlapping when looping.

There is provided a post processing technique or method for separation algorithms to separate vocals from monaural music recordings. The method comprises detecting traces of pitched instruments in a magnitude spectrum of a separated voice using Hough transform and removing the detected traces of pitched instruments using median filtering to improve the quality of the separated voice and to form a new separated music signal. The method further comprises applying adaptive median filtering techniques to remove the identified Hough regions from the vocal spectrogram producing separated pitched instruments harmonics and new vocals while adding the separated pitched instruments harmonics to a music signal separated using any separation algorithm to form the new separated music signal.

There is provided a post processing technique or method for separation algorithms to separate vocals from monaural music recordings. The method comprises detecting traces of pitched instruments in a magnitude spectrum of a separated voice using Hough transform and removing the detected traces of pitched instruments using median filtering to improve the quality of the separated voice and to form a new separated music signal. The method further comprises applying adaptive median filtering techniques to remove the identified Hough regions from the vocal spectrogram producing separated pitched instruments harmonics and new vocals while adding the separated pitched instruments harmonics to a music signal separated using any separation algorithm to form the new separated music signal.

A musical sound signal generation device continuously connects any one of a connected zeroth delay unit and a connected second delay unit to a fractional delay block and connects at least any one of a new zeroth delay unit and a new second delay unit to at least any one of the fractional delay block other than the fractional delay block connected to a new first delay unit in response to setting any one of the connected zeroth delay unit and the connected second delay unit as the new first delay unit, setting a delay unit in a preceding stage of the new first delay unit as the new zeroth delay unit, and setting a delay unit in a subsequent stage of the new first delay unit as the new second delay unit in accordance with a change in a designated tone pitch.

Methods and digital circuits providing frequency correction to frequency synthesizers are disclosed. An FLL digital circuit is provided that is configured to handle a reference frequency that is dynamic and ranges over a multi-decade range of frequencies. The FLL circuit includes a digital frequency iteration engine that allows for detection of disappearance of a reference frequency. When the digital frequency iteration engine detects that the reference frequency signal is not available, the oscillator generated frequency is not corrected, and the last value of the oscillator generated frequency is held until the reference frequency signal becomes available again. This FLL circuit is also preceded by a low-pass filter which is dynamically tuned to the frequency to which the FLL locks, eliminating harmonic components in the original signal which might otherwise cause errors in frequency estimation.

An audio signal processing apparatus comprises at least one controllable element 90, 91, 92 for performing an analogue audio processing function. The controllable element is operable with a digital controller 58 that controls the analogue audio processing function performed by the controllable element 90, 91, 92. At least one audio processing module 52, 54 comprises a partial audio processing circuit for an audio processing operation. The module 52, 54 is operable with the controllable element 90, 91, 92 to complete the audio processing circuit and thus to enable the audio processing operation. In this way the audio processing operation is controllable by the digital controller. A switching array 96 selectively couples audio processing modules 52, 54 and the controllable elements 90, 91, 92. A power supply 66 is operable to supply power selectively for audio processing circuit of the or each module 52, 54.