JP3991449B2 - Tone parameter change control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a timbre parameter change control device used for an electronic musical instrument or the like.
[0002]
[Prior art]
In the sound effect device, there are several means for changing the value of a timbre parameter, which is an element that determines the timbre of a musical tone to be generated during the performance of an electronic musical instrument.
[0003]
For example, the volume or pitch of the operation information is detected from the operation information on the performance operator of the user input to the sound effect device, and the value of the predetermined timbre parameter is changed according to the detected volume or physical quantity of the pitch. There is something to do. As a typical acoustic effect, there is an auto-wah that changes the cutoff frequency of the digital control filter in accordance with the volume of the input performance signal.
[0004]
When the sound effect device automatically changes the cut-off frequency of the digital control filter according to the volume of the input performance signal as in this auto wah, the performer particularly operates the sound effect device. Since the value of the timbre parameter can be automatically changed without operating the child, there is an advantage that it is possible to concentrate on the performance.
[0005]
[Problems to be solved by the invention]
As in the case of auto wah described above, the volume or pitch value is detected from the tone signal generated by the user's performance, and the timbre parameter value is automatically changed based on the detected value. In the conventional sound effect device, once the timbre parameter value change control mode is set, the timbre parameter value control circuit always follows the performance, and the user sets the timbre parameter value. Even when it is not desired to change the value, the value of the timbre parameter has changed. For example, in the case of auto wah, when the effect is turned off and when it is turned on, the tone of the generated musical tone will be completely different, especially in the second half of the note in the performance of a single note. Even if it is desired to change the cutoff frequency of the digital control filter, it is very unnatural to perform such on / off switching during performance.
[0006]
Therefore, in the conventional sound effect device, either the control to always change the value of the timbre parameter automatically following the performance, or no acoustic effect is given at all. However, it was not possible to realize a performance with rich expressive power that the performer wanted.
[0007]
An object of the present invention is not to always interlock, but to provide a variety of sound effects to musical sounds only when the player desires.
[0008]
[Means for Solving the Problems]
  In order to solve the above-mentioned problems, the present invention provides a timbre changing means for changing and outputting a timbre of a musical tone signal inputted based on a value of a timbre parameter stored in advance, and the input Parameter detecting means for detecting a characteristic parameter from the musical tone signal to be performed, switch means for instructing execution of timbre parameter change control, and the characteristic parameter detected by the parameter detecting means at the timing of execution instruction by the switch means An initial value storage means for storing a value as an initial value; a characteristic parameter value detected by the parameter detection means at a predetermined timing period after the start of an execution instruction by the switch means; and a storage by the initial value storage means Displacement amount calculation for calculating the displacement amount of the feature parameter based on the initial value Each time the displacement amount is calculated by the displacement amount calculating means, a new timbre parameter value is calculated based on the displacement amount and the previously stored timbre parameter value and supplied to the timbre changing means. Parameter calculating means.
[0009]
  According to a second aspect of the present invention, the parameter detecting means detects an envelope from the input musical sound signal as a characteristic parameter.
[0010]
  The invention according to claim 3 is characterized in that the parameter detecting means detects a pitch from the inputted tone signal as a characteristic parameter.
[0011]
  According to a fourth aspect of the present invention, the displacement amount calculating means calculates a characteristic parameter value detected by the parameter detecting means at a predetermined timing period and an initial value stored in the initial value storage means. A magnitude relation discriminating means for discriminating the magnitude relation is included, and the calculation form of the displacement amount of the characteristic parameter is varied based on the magnitude relation discriminated by the magnitude relation discriminating means.
[0012]
  According to a fifth aspect of the present invention, the displacement amount calculating means calculates a characteristic parameter value detected by the parameter detecting means at a predetermined timing period and an initial value stored in the initial value storage means. The displacement amount of the feature parameter is calculated based on the difference.
[0013]
According to a sixth aspect of the present invention, there is provided a tone color changing means for changing and outputting a tone color of a tone signal inputted based on a value of a tone color parameter stored in advance, and a parameter for detecting a characteristic parameter from the tone signal inputted. The value of the detected characteristic parameter is stored in the storage means as an initial value at the timing of the execution instruction by the switch means for instructing the computer applied to the timbre parameter change control apparatus having the detection means to execute the timbre parameter change control. Based on the initial value storage function to be stored, the value of the characteristic parameter detected at a predetermined timing period after the start of the execution instruction by the switch means, and the initial value stored in the storage means, The displacement amount calculation function for calculating the displacement amount and every time this displacement amount is calculated, Characterized in that by calculating the value of a new tone color parameter to realize, and the parameter calculation functions to be supplied to the tone color changing means based on the amount and the value of the previously stored tone color parameter.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiments of the present invention set a plurality of change control modes, timbre parameters, timbre change control parameters (change control parameters) values, and the like in an acoustic effect device for an electric guitar capable of selecting a plurality of effects simultaneously. A setting switch is prepared, and a pitch value and a volume envelope value are extracted from operation information (hereinafter referred to as an input signal) relating to the performance operator of the user input to the sound effect device, and the pitch value and the volume envelope value are extracted. The predetermined timbre parameter value is changed and controlled in accordance with the change control parameter value, the change control mode, and the on / off instruction from the foot controller.
[0016]
A system configuration of a sound effect device (hereinafter referred to as an effector) 1 to which a timbre parameter change control device according to an embodiment of the present invention is applied will be described with reference to FIG.
[0017]
The envelope detection unit 2 is a detection circuit including a first low-pass filter 21, a full-wave rectification circuit 23, and a second low-pass filter 25 described later, and a volume envelope from an input signal i input from the input terminal 17. Detect information.
[0018]
A detailed configuration of the envelope detector 2 will be described with reference to FIG.
The envelope detector 2 is a first low-pass filter 21 that removes unnecessary frequency band components from the input signal i, and a full-wave rectification that extracts the absolute value of the wave height of the signal input from the first low-pass filter 21. The circuit 23 includes a second low-pass filter 25 having a predetermined characteristic and extracting a so-called envelope obtained by averaging the absolute levels of the output waveform of the full-wave rectifier circuit 23.
[0019]
In the envelope detector 2 having the above-described configuration, unnecessary frequency band components are removed from the input signal i by the first low-pass filter 21, and an output waveform 22 is obtained. The output waveform 22 is a full-wave rectifier circuit. The full-wave rectifier circuit 23 generates an output waveform 24 that is an absolute value of the wave height of the output waveform 22.
[0020]
Then, the output waveform 24 passes through a second low-pass filter 25 having a predetermined characteristic, so that the level of the output waveform 24 is averaged from the second low-pass filter 25, so-called envelope (volume envelope information). ) Is output.
[0021]
Returning to the description of the system configuration of the effector 1 in FIG.
The pitch-voltage converter 3 is a pitch detection circuit including a third low-pass filter 31, a comparator 33, a monostable multivibrator 35, and a fourth low-pass filter 37, which will be described later. Is detected.
[0022]
A detailed configuration of the pitch-voltage conversion unit 3 will be described with reference to FIG.
The pitch-voltage converter 3 includes a third low-pass filter 31 that removes unnecessary frequency band components from the input signal i, and the amplitude of the signal input from the third low-pass filter 31 and a preset amplitude value. For example, when the amplitude of the input signal is larger than a preset amplitude value, “1” is output, and when the amplitude of the input signal is equal to or smaller than the preset amplitude value, “0” is output. Then, the comparator 33 for generating a periodic waveform in which one period of the waveform input from the third low-pass filter 31 has one binary value, and once per period from the periodic waveform at a constant interval A monostable multivibrator 35 that outputs a pulse wave, and a fourth low-pass filter 37 that functions as an integrator that integrates the pulse waveform and outputs a signal indicating how many times the pulse wave exists within a unit time. Made.
[0023]
In the pitch-voltage converter 3 having the above-described configuration, the output waveform 32 obtained by removing unnecessary frequency band components from the input signal i is obtained by the third low-pass filter 31. Is input. The comparator 33 compares the amplitude of the output waveform 32 with a preset amplitude value. For example, when the amplitude of the output waveform 32 is larger than the preset amplitude value, the output waveform 32 is “1”. When the amplitude of 32 is equal to or smaller than a preset amplitude value, by outputting “0”, an output waveform 34 in which one cycle of the waveform has one binary value is generated.
[0024]
Then, when the output waveform 34 is input to the monostable multivibrator 35, an output waveform 36 for generating a pulse wave of a constant interval is output from the monostable multivibrator 35 once a period. When the wave output waveform 36 is integrated by the fourth low-pass filter 37, an output waveform 38 that is pitch information proportional to the frequency of the output waveform 36 of the pulse wave is output from the fourth low-pass filter 37. The
[0025]
Returning to the description of the system configuration of the effector 1 in FIG.
The analog multiplexer 4 is detected by the volume envelope information of the analog signal detected by the envelope detector 2 and the pitch-voltage detector 3 under the control of an I / O port I / F (I / O port interface) 6. The pitch information of the analog signal is time-divided and output to the A / D converter 5.
[0026]
The A / D converter 5 converts the analog signal of the volume envelope information or the pitch information input from the analog multiplexer 4 into a digital signal and outputs the digital signal onto the bus 16.
[0027]
The I / O port I / F 6 is an input / output interface between the switch panel 7 and the bus 16.
The switch panel 7 has various settings such as setting a timbre parameter value, setting a change control parameter value, and setting a change control mode (the change control mode is also one of the change control parameters in this embodiment). It consists of a switch that performs.
[0028]
An example of the appearance of the switch panel 7 is shown in FIG.
The configuration of the switch panel 7 will be described with reference to FIG.
The switch panel 7 includes a parameter selection switch group 42 including a parameter UP switch 42-1 and a parameter DOWN switch 42-2, a value entry switch group 43 including a value UP switch 43-1 and a value DOWN switch 43-2, and a mode switching switch. 44, a patch memory number display section 45, a bank changeover switch group 46 comprising a bank UP switch 46-1 and a bank DOWN switch 46-2, a patch changeover switch group 47 comprising a patch switch a47-1 to a patch switch d47-4, A foot controller 48 and a liquid crystal display (hereinafter referred to as LCD) 49 are included.
[0029]
The bank changeover switch group 46 and the foot controller 48 on the switch panel 7 are foot switches that can be operated with feet so that the performer can operate them while playing the electric guitar, but is limited to such a configuration. It is not something.
[0030]
The parameter selection switch group 42 includes a parameter UP switch 42-1 and a parameter DOWN switch 42-2. When in the play mode described in detail later, nothing is operated even when pressed, and in the edit mode described in detail later. It is used for setting the value of the change control parameter and setting the change control mode.
[0031]
The value entry switch group 43 includes a value UP switch 43-1 and a value DOWN switch 43-2. In the play mode, pressing the value UP switch 43-1 once switches to the next patch number, and pressing the value DOWN switch 43-2 once switches to the previous patch number. In the edit mode, the value of the currently selected parameter can be increased or decreased by “one” by pressing the value UP switch 43-1 and the value DOWN switch 43-2.
[0032]
The mode changeover switch 44 exclusively switches between the play mode and the edit mode.
The patch memory number display unit 45 is operated by operating the bank UP switch 46-1 or the bank DOWN switch 46-2 of the bank changeover switch group 46 and the patch switches a47-1 to d47-4 of the patch changeover switch group 47. The currently selected bank number or patch number is displayed.
[0033]
Each patch has one timbre data composed of a combination of values of a plurality of parameters (comprising timbre parameters and change control parameters) edited in the edit mode. Each patch has its storage area (bank area, bank area). A unique patch number is assigned according to the patch area.
[0034]
The bank changeover switch group 46 includes a bank UP switch 46-1 and a bank DOWN switch 46-2. Bank numbers “1” to “8” are assigned to the eight types of banks a 62-1 to h 62-8, respectively, which are selected every time the bank UP switch 46-1 is pressed. Each time the bank number is incremented and the bank DOWN switch 46-2 is pressed, the selected bank number is decremented by one.
[0035]
The patch changeover switch group 47 includes patch switches a47-1 to d47-4 that designate patch numbers "1" to "4" in the bank, and pushes the patch switch a47-1 to patch switch d47-4. As a result, it is possible to directly select a patch in the currently selected bank.
[0036]
Here, an example of the configuration of the patch memory 61 provided in the RAM 8 and the contents of the patch will be described with reference to FIGS.
FIG. 5 is a diagram illustrating an example of the configuration of the patch memory 61.
[0037]
The patch memory 61 includes eight banks 62 including a bank a 62-1 to a bank h 62-8, and each of the banks a 62-1 to h 62-8 includes four patches. The bank a62-1 has a patch aa63-1 to a patch ad63-4, and the bank b62-2 has a patch bd63-5 to a patch bd63-8. The same applies to the following. For example, the bank h62-8 includes a patch ha63-29 to a patch hd63-32.
[0038]
These banks a62-1 to h62-8 are selected by operating the bank UP switch 46-1 and the bank DOWN switch 46-2 of the bank changeover switch group 46 as described above.
[0039]
Further, the patches aa 63-1 to hd 63-32 in the banks a 62-1 to h 62-8 are respectively operated by operating the patch switches a 47-1 to d 47-4 of the patch changeover switch group 47. Directly selected. That is, by operating the patch switch a47-1 to patch switch d47-4, the patches xa63-1 to xd63-32 (where x is “a”, “b” in the banks a62-1 to h62-8, respectively). ”,“ C ”,...“ H ”) can be directly selected.
[0040]
Each patch 63-selected by operating the bank UP switch 46-1 and the bank DOWN switch 46-2 of the bank changeover switch group 46 and the patch switch a47-1 to patch switch d47-4 of the patch changeover switch group 47 described above. n (n = 1 to 32) is configured as shown in FIG. 7 in the memory.
[0041]
Any one patch 63-n shown in FIG. 7 selected by operating the bank changeover switch group 46 and the patch changeover switch group 47 is copied as a temporary patch to the temporary memory 71 shown in FIG. 7 having the same capacity. The temporary patch is referred to when the values of the timbre parameter and the change control parameter are confirmed when the timbre control is performed in the play mode.
[0042]
FIG. 6 is a diagram illustrating an example of the contents of the patch 63-n (n = 1 to 32).
The patch 63-n has a plurality of parameter storage areas. In the parameter storage area, a plurality of timbre parameter values set by a timbre parameter setting process (S11) described later, an envelope follower setting process (S12), and The values of a plurality of change control parameters set by the pitch follower setting process (S13) are set. Accordingly, by selecting one patch by operating the bank change switch group 46 and the patch change switch group 47, it is possible to select a plurality of preset tone color parameter values and change control parameter values.
[0043]
Returning to the detailed configuration of the switch panel 7 of FIG.
The foot controller 48 operates to be off while not being pressed and to be on while being pressed. In response to the switching of the on / off state, in some play modes described later, change control is executed or change control is stopped.
[0044]
The LCD 49 displays the name and current value of the tone color change control parameter currently selected in the play mode. In the edit mode, the name of the currently edited parameter and its current value are displayed.
[0045]
Returning to the description of the system configuration of the effector 1 in FIG.
The RAM 8 has storage areas such as various registers and flags used by the CPU 10, the patch memory 61, the temporary memory 71, and a work area (work area).
[0046]
The ROM 9 stores a program executed by the CPU 10 for executing the control operation of the present embodiment.
The CPU 10 executes a program stored in the ROM 9 or the storage medium 10a loaded on the RAM 8, thereby using the RAM 8 as a work memory, and setting the timbre and timbre parameter values set by operating the switch panel 7. Envelope information input from the A / D converter 5 in real time based on the change control mode, the value of the change control parameter, and the contents of the patches aa 63-1 to hd 63-32 stored in the temporary memory 71 In accordance with each digital signal of the pitch information, necessary processing is performed in the effector 1, such as processing for changing the timbre parameter value.
[0047]
The low-pass filter 11 removes unnecessary frequency bands from the input signal i.
The input waveform A / D converter 12 converts the input signal that has passed through the low-pass filter 11 from an analog signal to a digital signal.
[0048]
A digital signal processor (hereinafter referred to as DSP) 13 is based on the value of a timbre parameter generated by the CPU 10 input via a serial I / F (serial interface) 14, and an input waveform A / D converter 12. The digital input signal input from is processed to generate a digital musical tone signal with an acoustic effect.
[0049]
Functions related to the addition of the sound effect of the DSP 13 will be described with reference to FIG.
FIG. 8 is a block diagram illustrating an example of functions related to the addition of the acoustic effect of the DSP 13.
[0050]
The DSP 13 includes a compressor unit 81, a distortion unit 82, a parametric equalizer unit (hereinafter referred to as a parametric EQ unit) 83, a pitch shifter unit 84, a chorus unit 85, a delay unit 86, and an output unit 87 that add different sound effects. is doing.
[0051]
The value of the timbre parameter output from the CPU 10 is input to the DSP 13 via the serial I / F 14.
When the DSP 13 receives the timbre parameter value, the compressor 13, the distortion unit 82, the parametric EQ unit 83, the pitch shifter unit 84, the chorus unit 85, and the delay unit 86, based on the timbre parameter value, input waveform. An acoustic effect is added to the digital input signal input from the A / D converter 12.
[0052]
Here, functions of the compressor unit 81, the distortion unit 82, the parametric EQ unit 83, the pitch shifter unit 84, the chorus unit 85, and the delay unit 86 will be described.
[0053]
The compressor unit 81 increases the gain when the level of the input signal is small, and when the input signal exceeds a certain level, decreases the gain as the input signal increases to prevent the output signal from increasing. This is an acoustic effect adding unit that changes the timbre by compressing the dynamic range of the input signal.
[0054]
The distortion unit 82 is an acoustic effect adding unit that changes a timbre by distorting an input signal.
The parametric EQ unit 83 is an acoustic effect adding unit that changes a tone color by variably setting a boost / cut (emphasis / attenuation) amount, frequency, and characteristic sharpness (Q) with respect to an input signal.
[0055]
The pitch shifter 84 is an acoustic effect adding unit that changes the timbre by changing the pitch (pitch) of the input signal.
The chorus unit 85 is an acoustic effect adding unit that generates a chorus effect that adds depth and thickness to sound by mixing an input signal that is slightly delayed with respect to the input signal.
[0056]
The delay unit 86 is an acoustic effect adding unit that generates a reverb effect or the like by mixing a large number of input signals slightly delayed with respect to the input signal. The delay unit 86 mixes an input signal having a delay time larger than that of the chorus unit 85 with the input signal.
[0057]
The output unit 87 is a multiplier that adjusts the output level.
The compressor section 81, the distortion section 82, the parametric EQ section 83, the chorus section 85, the pitch shifter section 84, the chorus section 85, the delay section 86, and the output section 87 of the DSP 13 are stored in a ROM or storage medium that the DSP 13 does not particularly illustrate. It is a functional block realized by software by executing a stored program.
[0058]
Returning to the description of the system configuration of the effector 1 in FIG.
The output unit 15 converts the digital musical tone signal input from the DSP 13 into an analog musical tone signal, amplifies the analog musical tone signal, and outputs it to the output terminal 18.
[0059]
Here, FIG. 9 shows an example of a connection form when the electric guitar 91 and the guitar amplifier 93 are connected to the effector 1 of the present embodiment having the above configuration.
The output terminal of the electric guitar 91 and the input terminal 17 of the effector 1 are connected by a cable 92, and the output terminal 18 of the effector 1 and the input terminal of the guitar amplifier 93 are connected by a cable 94.
[0060]
The vibration of the string of the electric guitar 91 is converted into an analog electric signal by a pickup (not shown), and the electric signal is input from the output terminal of the electric guitar 91 to the input terminal 17 of the effector 1 through the cable 92.
[0061]
The effector 1 generates a volume envelope signal of the input electric signal (input signal) from the input electric signal by the envelope detection unit 2, and further, the pitch-voltage conversion unit 3 adjusts the pitch of the input signal. An analog signal corresponding to the value is generated.
[0062]
The effector 1 is responsive to the volume envelope signal, the pitch signal, the change control mode set by the switch panel 7, the timbre parameter value, the change control parameter value, the input signal from the electric guitar 91, and the like. Generate a musical tone signal.
[0063]
The generated musical sound signal is input from the output terminal 18 of the effector 1 to the guitar amplifier 93 through the cable 94, and the musical sound signal is amplified in the guitar amplifier 93, and is external to the speaker built in the guitar amplifier 93. Sound is emitted.
[0064]
Next, the overall schematic operation of the effector 1 having the above configuration will be described with reference to FIG.
First, in the edit mode, the setting of the mode, the setting of the timbre parameter value, the setting of the change control mode, and the value of the change control parameter are performed by operating the switch panel 7.
[0065]
Next, when switching to the play mode and starting the performance, the vibration of the stringed electric guitar 91 is converted into an electric signal by a pickup (not shown) provided on the electric guitar 91, and the electric signal is converted into an electric signal. The signal is input to the effector 1 through the cable 92.
[0066]
An input signal input to the input terminal 17 of the effector 1 is distributed to the envelope detector 2, the pitch-voltage converter 3, and the low-pass filter 11.
The envelope detector 2 generates a volume envelope signal from the input signal.
[0067]
The pitch-voltage converter 3 generates an analog signal corresponding to the pitch value from the input signal.
The analog volume envelope signal generated by the envelope detector 2 and the analog signal indicating the pitch value generated by the pitch-voltage converter 3 are both input to the analog multiplexer 4 and then time-divided into A / It is input to the D converter 5.
[0068]
The A / D converter 5 converts the input analog volume envelope signal and the analog signal indicating the pitch value into a digital volume envelope value and a digital pitch value, respectively.
[0069]
The CPU 10 executes a program stored in the ROM 9 or the storage medium 10a, so that the change control mode, the value of the change control parameter set by the operation of the switch panel 7 stored in the RAM 8, the digital volume envelope The tone color parameter value is changed and controlled using the work area in the RAM 8 in accordance with the value of the digital pitch and the digital pitch value.
[0070]
The value of the timbre parameter controlled and changed by the CPU 10 is output to the DSP 13 via the serial I / F 14.
On the other hand, the input signal input to the low-pass filter 11 is input to the input waveform A / D converter 12 after removing unnecessary frequency bands, and is converted into a digital musical tone signal by the input waveform A / D converter 12. The
[0071]
The DSP 13 adds an acoustic effect to the digital musical tone signal input from the input waveform A / D converter 12 based on the value of the timbre parameter input from the CPU 10, and the digital musical tone to which the acoustic effect is added. The signal is output to the output unit 15.
[0072]
The output unit 15 converts the digital tone signal to which the sound effect is added into an analog tone signal, amplifies it, and outputs it to the output terminal 18.
The analog musical sound signal output from the output unit 15 is transmitted to the guitar amplifier 93 shown in FIG. 9, etc., where it is amplified to a signal of a predetermined magnitude and emitted to the outside through the built-in speaker or the like.
[0073]
Next, the operation of the effector 1 will be described in detail.
Before describing the overall processing of the effector 1, first, setting processing in the edit mode (S5), input processing in the play mode (S7), envelope follower processing (S8), and pitch follower processing (S9) constituting the overall processing. The flags and registers used in each process of parameter processing (S10) will be described.
[0074]
First, flags used in each process of the overall process will be described.
“SAME F” (same flag) is set to “1” when the parameter number stored in “PARAMETER E” to be described later is the same as the parameter number stored in “PARAMETER P” to be described later, and to “0” if the parameter number is different. "Is set.
[0075]
“FT F” (foot controller on flag) is set to “1” when the state of the foot controller 48 is on, and is set to “0” when it is off.
[0076]
“FFT F” (FT flag storage flag) is set to the contents of the previous “FT F”.
“ET” (envelope threshold flag) is “1” when the value of the envelope detected from the input signal by the envelope detector 2 is larger than the envelope threshold set by the envelope follower setting process described later. It is set, and when it is small, “0” is set.
[0077]
“HE F” (change control status flag) is set to “1” when changing the value of the timbre parameter to be changed according to the value of the envelope, and set to “0” when changing control is not performed. Is done.
[0078]
“IN FE” and “IN FP” (initial change control execution flag) perform the above change control in the initial state when the mode is switched to the mode 3 of envelope follower processing and pitch follower processing described later, respectively. This flag is set to “1” when mode 3 is selected in the envelope follower process and the pitch follower process.
[0079]
“HP F” (change control status flag) is set to “1” when the value of the timbre parameter to be changed is changed according to the pitch value, and set to “0” when change control is not performed. Is done.
[0080]
Next, registers used in each process of the overall process will be described.
“PARA NUM” (tone color parameter number register) stores the number of the tone color parameter selected by operating the parameter selection switch group 42.
[0081]
“Vie” (envelope / follower parameter value register) stores the value of the timbre parameter to be changed in the envelope follower setting process.
“Vip” (pitch follower parameter value register) stores the value of the timbre parameter to be changed in the pitch follower setting process.
[0082]
“Li” (envelope initial value register) stores an initial value of the envelope.
“Lc” (envelope current value register) stores the current value of the envelope.
[0083]
“Pi” (pitch initial value register) stores an initial value of the pitch.
“Pc” (pitch current value register) stores the current value of the pitch.
“ME” (envelope follower displacement amount register) stores the displacement amount related to the envelope obtained by the envelope follower processing.
[0084]
“MP” (pitch follower displacement amount register) stores a displacement amount related to the pitch obtained by the pitch follower processing.
Now, the overall processing of the effector 1 will be described.
[0085]
FIG. 10 is a flowchart of the overall processing of the effector 1.
When a power switch (not shown) is turned on, initialization processing such as clearing the registers in the CPU 10 and clearing the contents of the RAM 8 is performed. In this embodiment, there are two modes: an edit mode in which the values of the timbre parameters and the change control parameters are set by operating the switch panel 7 and a play mode in which the timbre parameters are changed and controlled during performance. The currently selected mode is determined (S1).
[0086]
If it is the edit mode (S1, edit mode), the process proceeds to step S2, and edit mode processing is performed. If it is the play mode (S1, play mode), the process proceeds to step S3 and play mode processing is performed.
[0087]
First, the processing of the effector 1 in the edit mode will be described.
FIG. 11 is a flowchart showing the processing of the effector 1 in the edit mode.
[0088]
In the operation standby state of the switch panel 7, when the user operates the mode change switch 44 to select the edit mode and operate the switch panel 7 of the effector 1 to perform various settings, the operation contents of the switch panel 7 are displayed. Based on this, various setting processes are performed (S5).
[0089]
The operation of the switch panel 7 can be confirmed by scanning the key matrix circuit (not shown) built in the switch panel 7 at regular intervals to detect the status of each switch provided on the switch panel 7. Is done by doing. Based on the status information, it is detected which switch of the switch panel 7 is operated, and a setting process is performed based on the operation content of the operated switch.
[0090]
Details of the setting process in step S5 will be described with reference to the flowchart of FIG.
As values (information) selected or set by operating the switch panel 7, the bank UP switch 46-1 and the bank DOWN switch 46-2 of the bank changeover switch group 46, and the patch switches a47-1 to 47-1 of the patch changeover switch group 47 are shown. Information indicating a patch selected by operating the patch switch d47-4, the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42, and the value UP switch 43-1 of the value entry switch group 43 The value of the timbre parameter set by the value DOWN switch 43-2 (S11), the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42, and the value U of the value entry switch group 43 Various parameter setting processing related to envelope follower processing (S12), various parameter setting processing related to pitch follower processing (S13), and copy processing to a temporary patch (set by the switch 43-1 and value DOWN switch 43-2) S14).
[0091]
First, the details of the timbre parameter setting process (S11) will be described with reference to the flowchart of FIG.
The timbre parameter setting process (S11) is a process for setting values of timbre parameters relating to various effects to be added to the musical sound generated based on the performance operation.
[0092]
First, by operating the bank change switch group 46 and the patch change switch group 47, a patch 63-n (n = 1 to 32) that stores the value of the tone color parameter to be set is selected (S21).
[0093]
In order to determine whether or not a timbre parameter has been selected, it is determined whether or not the UP switch 42-1 or DOWN switch 42-2 of the parameter selection switch group 42 has been operated for a predetermined time (S22).
[0094]
If the UP switch 42-1 or the parameter DOWN switch 46-2 of the parameter selection switch group 42 is operated (S22, YES), the number of the timbre parameter selected by the operation is set to “PARA NUM” (S23). ).
[0095]
If it is determined in step S22 that the UP switch 42-1 or the parameter DOWN switch 46-2 of the parameter selection switch group 42 has not been operated for a predetermined time (S22, NO), the process proceeds to step S5 in FIG. Return.
[0096]
Next, in step S24, the UP switch 43-1 or the DOWN switch 43-2 of the value entry switch group 43 is used to determine whether or not to change the value of the timbre parameter whose number is set to “PARA NUM”. It is determined whether or not the value of the timbre parameter is designated by the operation (S24).
[0097]
If the value of the timbre parameter is specified by the operation of the UP switch 43-1 or the DOWN switch 43-2 of the value entry switch group 43 (S24, YES), the timbre parameter whose number is set to “PARA NUM” The value is changed (S25), and the changed timbre parameter value is selected in step S21 to the patch 63-n (n = 1 to 32) selected by the operation of the bank changeover switch group 46 and the patch changeover switch group 47. The area is set in the patch 63-n (n = 1 to 32) (S26), and the process returns to step S22.
[0098]
If it is determined in step S24 that the value of the timbre parameter is not designated by the operation of the UP switch 43-1 or the DOWN switch 43-2 of the value entry switch group 43 (S24, NO), the process proceeds to step S22. Return.
[0099]
Here, the types of tone color parameters (tone color control parameters) and ranges of the values will be described with reference to FIG.
As shown in FIG. 15, the timbre parameter is prepared for a type corresponding to each of the sound effect addition function units 81 to 87 of the DSP 13.
[0100]
Parameters prepared for the compressor unit 81 are tone parameters that specify the sustain, attack, and level of the volume envelope, and these parameters are set in the range of 0 (minimum) to 100 (maximum). it can.
[0101]
Parameters prepared for the distortion unit 82 are tone parameters that specify the amount of overdrive (drive amount), tone, and level of distortion, and these parameters range from 0 (minimum) to 100 (maximum). A value can be set within the range.
[0102]
Parameters prepared for the parametric EQ unit 83 are timbre parameters that specify the frequency to be boosted / cut (emphasized / attenuated), the sharpness (Q) of the characteristic, and the amount (gain) thereof. , 0 (minimum) to 100 (maximum) can be set, and the amount (gain) can be set to -100 (minimum) to 100 (maximum).
[0103]
Parameters prepared for the pitch shifter unit 84 are tone parameters that specify chorus, fine (fineness of change in shift amount), and balance. The chorus parameters range from -12 (minimum) to +12 (maximum). The fine parameter can be set in the range of -50 (the coarsest compared to the standard value) to +50 (the finest compared to the standard value), and the balance parameter is 0 ( Values can be set in the range of (minimum) to 100 (maximum).
[0104]
The parameters prepared for the chorus unit 85 are tone color parameters that specify the rate, depth, and balance, and these parameters can be set in the range of 0 (minimum) to 100 (maximum).
[0105]
The parameters prepared for the delay unit 86 are timbre parameters that specify delay time, feedback amount, and balance, and these parameters can be set in the range of 0 (minimum) to 100 (maximum). .
[0106]
A parameter prepared for the output unit 87 is a timbre parameter for designating an output level, and the parameter can be set in a range of 0 (minimum) to 100 (maximum).
[0107]
By repeating the processes in steps S22 to S26, the value of the change control parameter set by the performer is set in the currently selected patch 63-n (n = 1 to 32).
[0108]
For example, by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42, the parameter of the frequency to be boosted / cut (emphasized / attenuated) of the parametric EQ unit 83 is selected, and the value entry switch group 43 If the value of the parameter is set to “70” by the value UP switch 43-1 and the value DOWN switch 43-2, the parameter number of the frequency to be boosted / cut (emphasized / attenuated) is “PARA NUM”. The designated value “70” of the parameter is set in the corresponding area in the currently selected patch 63-n (n = 1 to 32).
[0109]
A predetermined number is assigned to each timbre parameter in advance.
Note that the timbre parameters are not limited to the parameters raised here, and the timbre parameter values relating to other acoustic effects such as reverberation and expression may be set.
[0110]
Next, details of the envelope follower setting process (S12) will be described.
The envelope follower setting process (S12) is used to change and control the value of the timbre parameter set by the timbre parameter setting process of step S11 based on the volume envelope value of the input signal detected by the envelope detector 2. This is a process for setting the value of the change control parameter.
[0111]
Before describing the envelope follower setting process (S12), details of the types of change control parameters for the envelope follower set by the envelope follower setting process (S12) and the value ranges of these parameters will be described with reference to FIG. explain.
[0112]
As shown in FIG. 16, the change control parameters for the envelope follower set by the envelope follower setting process (S12) include a first mode selection parameter “MODE E”, a first parameter designation parameter “PARAMETER E”, There is a first range designation parameter “Lr”, a first depth designation parameter “DEPTH E”, and a first threshold designation parameter “THE”.
[0113]
The first mode selection parameter “MODE E” is a parameter that specifies a change control mode of the value of a first change target tone color parameter, which will be described later, and specifies one of the first mode 0 to the first mode 7. To do.
[0114]
The first mode 0 is an off mode and does not perform any change control of the value of the first change target tone color parameter.
The first mode 1 is a constant change control mode in which change control of the value of the first change target tone color parameter is always performed.
[0115]
The first mode 2 is a foot controller / alternate / on mode, and when the foot controller 48 of the switch panel 7 is pressed from the state where the change control of the value of the first change target timbre parameter is not performed (OFF). When the first to-be-changed tone parameter value is controlled to change, the envelope value of the input signal is set by the first threshold value designation parameter “THE”. If the value is lower than the value, the change value of the first change target timbre parameter is restored. Further, when the foot controller 48 of the switch panel 7 is pressed when the value of the first change target timbre parameter is currently in the change control state, the value of the first change target timbre parameter at that time point. Hold. If the foot controller 48 is pressed again, the first change target timbre is based on the value of the first change target timbre parameter at that time as when the foot controller 48 is first pressed. In this mode, parameter value change control is always performed.
[0116]
The first mode 3 is a foot controller / alternate / off mode, which starts from a state in which the change control of the value of the first change target timbre parameter is performed. In this state, the foot controller 48 of the switch panel 7 is pressed. If it has been turned on (if turned on from off), the value of the first change target timbre parameter at that time is held. Further, when the foot controller 48 of the switch panel 7 is pressed again in this state, the change control of the value of the first change target timbre parameter is always performed. Further, when the level of the envelope value (volume envelope value) of the input signal falls below the value set by the first threshold value designation parameter “THE”, the value of the first change target timbre parameter is changed. In this mode, control is always performed.
[0117]
The first mode 4 is a foot controller / momentary on mode, and only when the foot controller 48 of the switch panel 7 is pressed (only while it is turned on), the first change target tone parameter is changed. In this mode, when the value change control is performed and the foot controller 48 is released (turned off from on), the value at that time is held.
[0118]
The first mode 5 is a foot controller / momentary / off mode, and usually controls the change of the value of the first change target timbre parameter, and only while the foot controller 48 of the switch panel 7 is pressed. In this mode, change control of the value of the first change target timbre parameter is prohibited.
[0119]
The first mode 6 is a level trigger momentary on mode. The first mode 6 is the first mode only when the level of the envelope value of the input signal is not less than the value set by the first threshold value designation parameter “THE”. When the level of the envelope value of the input signal falls below the value set by the first threshold value specifying parameter “THE”, the change control of the timbre parameter to be changed is performed. In this mode, the value of the timbre parameter to be changed is held. This mode is used, for example, when it is desired to change and control the value of the first change target tone color parameter only when the string of the electric guitar 91 is strongly played.
[0120]
The first mode 7 is a level trigger momentary off mode, and the first mode 7 is only in the state where the level of the envelope value of the input signal is not less than the value set by the first threshold designation parameter “THE”. If the level change of the envelope value of the input signal falls below the value set by the first threshold value designation parameter “THE” without performing the change control of the value of the first timbre parameter to be changed, the first change is made. In this mode, the value of the target timbre parameter is changed and controlled. This mode is used, for example, when it is desired to cancel the parameter change control only when the string of the electric guitar 91 is strongly played.
[0121]
The first parameter designation parameter “PARAMETER E” designates a tone color parameter (the above-mentioned first alteration target tone color parameter) to be changed in an envelope follower process or a pitch follower process, which will be described later. Any one of 19 kinds of tone parameters from the sustain for the compressor 81 shown to the level for the output 87 is designated.
[0122]
The first range designation parameter “Lr” determines the sensitivity with which range the envelope value level (input envelope level) of the input signal is read. As the value of this parameter approaches 100, which is the maximum input level, the dynamic range becomes wider and the sensitivity decreases. When the input envelope level is saturated, it is clipped to the maximum value.
[0123]
The first depth designation parameter “DEPTH E” determines the depth of change control. The change control is performed within a variable range of values that can be taken by the timbre parameter that is the first change target (the first change target timbre parameter). When the depth value is positive, It is changed so as to approach the maximum value of the change target timbre parameter, and when the depth value is negative, it is changed so as to approach the minimum value of the first change target timbre parameter. Further, the value of the first change target timbre parameter is the maximum value of the first change target timbre parameter when the input envelope level is maximum when the depth value is +100. Thus, when the depth value is −100, control is performed so that the first change target tone color parameter becomes the minimum value when the input envelope level is maximum.
[0124]
The first threshold value designation parameter “THE” is a parameter that determines the threshold value of the input envelope level value.
Details of the envelope follower setting process (S12) will be described with reference to the flowchart of FIG.
[0125]
First, in the edit mode, in order to set the change control mode, it is determined whether or not the mode selection parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42. (S31) If the mode selection parameter is selected (S31, YES), the mode (change control mode) selected by operating the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43. ) Is set to “MODE E” of the currently selected patch 63-n (n = 1 to 32) (S32).
[0126]
Then, it is determined whether the mode number of the mode selected by the operation of the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 is “3” (S33), and the mode number is “3”. "In other words, if the first mode 3 is selected as the change control mode (S33, YES)," 0 "is set to" IN FE "(S34). If the mode number is not “3” (S33, NO), the process proceeds directly to step S35.
[0127]
If the mode selection parameter is not selected in step S31 (S31, NO), the process proceeds to step S35 as it is.
Next, in order to set the timbre parameter of the first change control target, the first parameter designation parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42. If the first parameter designation parameter is selected (S35, YES), the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 are operated. Is set in “PARAMETER E” of the currently selected patch 63-n (n = 1 to 32) (S36), and is set in the timbre parameter setting process in step S11, Currently selected patch 63-n (n = 1 to 32) It is set to "Vie" the value of the tone color parameter corresponding to the set to the "PARAMETER E" stored parameter number (S37).
[0128]
If the first parameter setting parameter is not selected (S35, NO), the process proceeds to step S38.
Next, whether or not the first range designation parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42 in order to set the value of the first range. If the first range specification parameter is selected (S38, YES), it is set by operating the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43. The value of the first range is set to “Lr” of the currently selected patch 63-n (n = 1 to 32) (S39).
[0129]
If the first range designation parameter is not selected (S38, NO), the process proceeds to step S40 as it is.
Next, in order to set the first depth value, is the first depth designation parameter selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42? If the first depth designation parameter is selected (S40, YES), the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 are operated. The value of the first depth set by is set in “DEPTH E” of the currently selected patch 63-n (n = 1 to 32) (S41).
[0130]
If the first depth designation parameter has not been selected (S40, NO), the process proceeds directly to step S42.
Next, in order to set the first threshold value, is the first threshold value designation parameter selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42? If the first threshold designation parameter is selected (S42, YES), the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 are determined. The first threshold value set by the operation is set to “THE” of the currently selected patch 63-n (n = 1 to 32) (S43).
[0131]
If the first threshold designation parameter is not selected (S42, NO), the process returns to the envelope follower setting process (S12) of FIG. Then, a pitch follower setting process (S13) is performed in the edit mode.
[0132]
The pitch follower setting process (S13) is a process for designating a change control parameter used in the pitch follower process described later.
As shown in FIG. 16, the change control parameters for the pitch follower set by the pitch follower setting process (S13) include a second mode selection parameter “MODE P”, a second parameter designation parameter “PARAMETER P”, It consists of a second range designation parameter “Pr”, a second depth designation parameter “DEPTHP”, and a second threshold designation parameter “TH P”.
[0133]
The second mode selection parameter “MODE P” is a parameter for designating a change control mode of the value of a second change target tone color parameter to be described later, and designates one of the second mode 0 to the second mode 7. To do.
[0134]
The second mode 0 is an off mode and is a mode in which no change control of the value of the second change target timbre parameter is performed.
The second mode 1 is a constant change control mode in which change control of the value of the second change target timbre parameter is always performed.
[0135]
The second mode 2 is a foot controller / alternate / on mode, and when the foot controller 48 of the switch panel 7 is pressed (OFF) from the state in which the change control of the second to-be-changed tone color parameter is not performed. The second change target tone parameter value change control is always performed, and the envelope value (volume envelope value) of the input signal is set to the second threshold value designation parameter “TH”. If the value is lower than the value set in P ″, the changed value is restored. Further, when the foot controller 48 of the switch panel 7 is pressed from the current state where the value of the second change target timbre parameter is subjected to change control, the value of the second change target timbre parameter at that time is held. To do. Further, if the foot controller 48 is pressed again, the second change target is changed based on the value of the second change target tone parameter at that time, as when the foot controller 48 is first pressed. In this mode, change control of the timbre parameter value is always performed.
[0136]
The second mode 3 is a foot controller / alternate / off mode. When the foot controller 48 of the switch panel 7 is pressed (turned on) from the state in which the change control of the second to-be-changed tone color parameter is performed. The current value of the second change target timbre parameter is held. Further, when the foot controller 48 of the switch panel 7 is pressed again in this state, the change control of the value of the second change target timbre parameter is always performed. Further, even when the level of the envelope value of the input signal falls below the value set in the second threshold value designation parameter “TH P”, the change control of the value of the second change target tone color parameter is always performed. It is a mode to become.
[0137]
The second mode 4 is a foot controller / momentary on mode, in which the change control of the value of the second to-be-changed tone color parameter is performed only while the foot controller 48 of the switch panel 7 is being pressed. When 48 is released, the second change target timbre parameter value is held at that time.
[0138]
The second mode 5 is a foot controller / momentary / off mode, which normally controls the change of the value of the second change target timbre parameter and only while the foot controller 48 of the switch panel 7 is being pressed. In this mode, change control of the value of the second change target timbre parameter is prohibited.
[0139]
  The second mode 6 is a level trigger momentary on mode, and the second mode 6 is the second trigger only while the pitch of the input signal exceeds the value set in the second threshold value designation parameter “TH P”. Controls changing the value of the target timbre parameter and changes the input signalpitchIs less than the value set in the second threshold value designation parameter “TH P”, the mode holds the value of the second change target timbre parameter at that time. This mode is used when it is desired to change and control the value of the second to-be-changed tone color parameter only when the pitch is raised to some extent by choking or the like during sound generation. If the second threshold value designation parameter “TH P” is set lower than the initial value of the pitch at the time of sound generation, conversely, the second change is made when the pitch is lowered than at the time of sound generation. It is possible not to change and control the value of the target tone color parameter.
[0140]
The second mode 7 is a level trigger momentary off mode, and only when the pitch of the input signal exceeds the value set in the second threshold designation parameter “TH P”, If the pitch of the input signal falls below the value set in the second threshold designation parameter “TH P” without changing the value of the change target tone color parameter, the second change target at that time Holds the value of the timbre parameter. This mode is used when it is desired to cancel the effect of the control of changing the value of the second change target timbre parameter only when the pitch of the input signal is raised to some extent by choking or the like during sound generation. If the second threshold value designation parameter “TH P” is set lower than the initial value at the time of sound generation, conversely, when the pitch of the input signal is lowered than at the time of sound generation, the second threshold value designation parameter “TH P” is set. The value of the change target tone color parameter can be changed and controlled.
[0141]
The second parameter specifying parameter “PARAMTER P” is used to specify a tone color parameter (the second change target tone color parameter) that is subject to change control in pitch follower processing, which will be described later. From the sustain shown in FIG. One of 19 kinds of timbre parameters up to the level is designated.
[0142]
The second range designation parameter “Pr” determines the sensitivity (sensitivity) of how much (full range) the change in the pitch value level (input pitch level) of the input signal is read. When “1” is “1”, a 100% change is treated as a full range. As the value of this parameter approaches the maximum value of 24 (2 octaves), the dynamic range becomes wider and the sensitivity decreases. When the change in the input pitch level is greater than the full range, it is clipped to the maximum value.
[0143]
The second depth designation parameter “DEPTH P” determines the depth of change control. The change control is performed within a variable range of values that can be taken by the timbre parameter to be changed (second change target timbre parameter). When the depth value is positive, the second change target timbre is changed. When the depth value is negative, the parameter is changed so as to approach the minimum value of the second change target tone color parameter. When the depth value is +100, when the change in the input pitch level is maximum, the value of the second change target timbre parameter is the maximum value, and the depth value is large. Is -100, the value of the second change target timbre parameter becomes the minimum value when the change of the input pitch level is the maximum.
[0144]
The second threshold value designation parameter “TH P” is a parameter that determines the threshold value of the input pitch level value.
Details of the pitch follower setting process (S13) will be described with reference to the flowchart of FIG.
[0145]
In order to set the second change control mode, it is determined whether or not the second mode selection parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42. (S51) If the second mode selection parameter is selected (S51, YES), the second set by the operation of the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 is set. Is set to “MODE P” of the currently selected patch 63-n (n = 1 to 32) (S52).
[0146]
If the second mode selection parameter has not been selected (S51, NO), the process proceeds directly to step S55.
Then, it is determined whether or not the mode number of the mode selected by the operation of the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 is “3” (S53), and the mode number is “3”. In other words, if the second mode 3 is selected as the change control mode (S53, YES), “0” is set to “IN FP” (S54). If the mode number is not “3” (S53, NO), the process proceeds to step S55.
[0147]
Next, whether or not the second parameter designation parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42 in order to set the second change target timbre parameter. If the second parameter designation parameter is selected (S55, YES), it is set by operating the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43. The selected parameter number is set in “PARAMETER P” of the currently selected patch 63-n (n = 1 to 32) (S56).
[0148]
If the second parameter designation parameter is not selected (S55, NO), the process proceeds to step S61.
Next, the parameter number set in “PARAMETER P” is compared with the parameter number set in “PARAMETER E” by the envelope follower setting process described above (S57), and “PARAMETER E” and “PARAMETER P” are compared. (S57, YES), the parameter change amount obtained by the envelope follower process described later and the parameter change amount obtained by the pitch follower process described later in the parameter change process described later. In order to control to change the value of the timbre parameter having the parameter number by the summed value, the first change target timbre parameter set by the envelope follower setting process and the second change set by the pitch follower setting process are used. Target tone color parameter is set to "1" (the same) in the flag "SAME F" indicating whether or not the same (S58).
[0149]
If the parameter numbers set in “PARAMETER E” and “PARAMETER P” are not the same (S57, NO), the flag “SAME F” is set to “0” (not the same) (S59), The change target having the parameter number set in “PARAMETER P” stored in the currently selected patch 63-n (n = 1 to 32) set in the timbre parameter setting process in step S11. The parameter value is set to “Vip” (S60).
[0150]
Next, whether or not the second range designation parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42 in order to set the value of the second range. If the second range designation parameter is selected (S61, YES), it is set by operating the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43. The value of the second range is set to “Pr” of the currently selected patch 63-n (n = 1 to 32) (S62).
[0151]
If the second range designation parameter is not selected (S61, NO), the process proceeds to step S63 as it is.
Next, in order to set the depth value, it is determined whether or not the second depth designation parameter is selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42. If it is determined (S63) and the second depth designation parameter is selected (S63, YES), it is set by operating the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43. The second depth value is set to “DEPTHP” of the currently selected patch 63-n (n = 1 to 32) (S64).
[0152]
If the second depth designation parameter is not selected (S63, NO), the process proceeds to step S65 as it is.
[0153]
Next, in order to set the second threshold, is the second threshold designation parameter selected by operating the parameter UP switch 42-1 and the parameter DOWN switch 42-2 of the parameter selection switch group 42? If the second threshold designation parameter is selected (S65, YES), the value UP switch 43-1 and the value DOWN switch 43-2 of the value entry switch group 43 are determined. The second threshold value set by the operation is set to “TH P” of the currently selected patch 63-n (n = 1 to 32) (S66), and the process returns to step S13 in FIG.
[0154]
If the second threshold setting parameter is not selected (S65, NO), the process returns to step S13 in FIG.
Next, processing of the effector 1 in the play mode will be described.
[0155]
  FIG. 12 is a flowchart showing processing of the effector 1 in the play mode. When the mode is switched to the play mode, the value of the timbre parameter set for the selected patch 63-n (n = 1 to 32) and the envelope follower are set by the operation of the bank switch group 46 and the patch switch group 47. The value of the change control parameter and the value of the change control parameter for the pitch follower are read into the temporary memory 71 as a temporary patch.(S6).
[0156]
When performance is started, input processing (S7) is performed.
Details of the input process (S7) will be described with reference to the flowchart of FIG.
[0157]
It is determined whether or not the envelope value (input envelope value) of the input performance information (input signal) is an initial value (S71).
If the value of the input envelope level is the initial value (S71, YES), the ratio (%) of the value of the envelope level to the maximum value of the input envelope level is set to “Li” (S72). On the other hand, if the value of the input envelope level is not the initial value (S71, NO), the ratio (%) of the value (current value) of the input envelope level to the maximum value of the input envelope level is set to “Lc” (%). S73).
[0158]
The reason why the values of the input envelope level are divided into the initial value and the current value and set in the registers “Li” and “Lc”, respectively, is that the initial value and the current value of the input envelope level in the envelope follower processing of FIG. This is because the displacement amount ME is obtained using the difference from the value.
[0159]
Next, it is determined whether the pitch value (input pitch) of the input performance information is an initial value (S74).
If the value of the input pitch is an initial value (S74, YES), the value (cent) of the input pitch is set to “Pi” (S75), and the value of “FT F” is set to “FFT F” ( S77). If the input pitch value is not the initial value (S74, NO), the value (current value) (cent) of the input pitch with respect to the maximum value of the input pitch level is set to “Pc” (S76). The value of “FT F” is set in FFT F ”(S77).
[0160]
The reason why the input pitch value is divided into the initial value and the current value and set in the registers “Pi” and “Pc” is the same as the input envelope level value in the pitch follower processing of FIG. This is because the displacement amount “MP” is obtained using the initial value and the current value of the input pitch.
[0161]
Next, it is determined whether or not the foot controller 48 of the panel switch 7 is pressed (S78), the foot controller 48 of the panel switch 7 is pressed, and the state of the foot controller 48 of the panel switch 7 is turned ON. If there is (S78, ON), "1" is set to "FT F" (S79), and the process proceeds to step S8 in FIG. If the foot controller 48 of the panel switch 7 is not pressed and the state of the foot controller 48 of the panel switch 7 is OFF (S78, OFF), “0” is set to “FT F” (S80). ), The process proceeds to step S8 in FIG.
[0162]
By the processing in steps S78 to S80, “1” (ON) or “0” (OFF) is set in the flag “FT F” indicating the ON / OFF state of the foot controller 48 of the panel switch 7.
[0163]
  Returning to the description of the overall processing in FIG.
  When the above-described patch selection process (S6) and input process (S7) are completed, the patch selection process(S6)Accordingly, the displacements “ME” and “MP” are determined based on the value of the timbre parameter, the value of the change control parameter set in the temporary memory 71, the value of the input envelope level obtained by the input process (S7), the value of the input pitch, and the like. Envelope follower processing (S8) and pitch follower processing (S9), which are processes for obtaining "".
[0164]
In the envelope follower process (S8), the first change control mode and the first threshold value set in the envelope follower setting process (S12), and the initial value of the input envelope level obtained in the input process (S7) “ This is a process for obtaining the displacement amount “ME” used for change control of the first change target timbre parameter based on “Li” and the current value “Lc”.
[0165]
Details of the envelope follower process (S8) will be described with reference to flowcharts (No. 1 to No. 3) of FIGS.
The first modes 0 to 7 described below are determined by referring to the value of the mode designation parameter set in “MODE E” of the temporary memory 71.
[0166]
Further, the value of the first change target timbre parameter described below is set in the patch 63-n (n = 1 to 32) by the performer in the envelope follower setting process (S12) and is currently set in the temporary memory 71. It is what has been.
[0167]
First, the envelope follower process (S8) in the first mode 0 will be described with reference to the flowchart (part 1) of the envelope follower process of FIG.
[0168]
Since the first mode 0 is a mode in which change control is not performed regardless of whether the foot controller 48 of the panel switch 7 is on or off, it is determined whether or not it is the first mode 0 (S91). If it is 1 mode 0 (S91, YES), the process directly returns to step S8 in FIG. 12, and the process ends without performing the process of obtaining the displacement amount “ME” of the value of the change control parameter. On the other hand, if it is not the first mode 0 (S91, NO), the process proceeds to step S92.
[0169]
Next, the envelope follower process (S8) in the case of the first mode 1 will be described with reference to the flowchart (part 1) of the envelope follower process of FIG.
[0170]
In the first mode 1, change control is performed regardless of whether the foot controller 48 of the panel switch 7 is on or off. Therefore, it is determined whether or not it is the first mode 1 (S92). If it is mode 1 (YES in S92), “1” is set to “HE F” in step 100, and the initial value “Li” (%) and current value “Lc” (%) of the input envelope level are set in step 102. And the displacement amount “ME” is calculated from step S103 to step S107.
[0171]
Based on the magnitude relationship between the initial value “Li” (%) of the input envelope level and the current value “Lc” (%), the value of the displacement “ME” is obtained as follows.
When Lc> Li (S103)
ME = (Lc-Li) / (Lr-Li) (1)
When Lc = Li (S104)
ME = 0 (2)
When Lc <Li (S105)
ME = −Lc / Li (3)
Note that Lr (%) is the value of the range designation parameter “Lr” of the temporary memory 71.
[0172]
Further, in order to prevent the absolute value of the displacement amount “ME” from becoming an extremely large value and causing an unnatural timbre change, the value of the displacement amount “ME” is greater than 1 or the displacement amount “ME”. Is determined to be smaller than −1 (S106). If the displacement amount “ME” is greater than 1 (S106, YES), the displacement amount “ME” is forcibly set to 1 ( S107) If the value of the displacement “ME” is smaller than −1 (S106, YES), the value of the displacement “ME” is forcibly set to −1 (S107), and the process returns to step S8 in FIG. To do.
[0173]
Further, when the value of the displacement “ME” is not larger than 1 or when the value of the displacement “ME” is not smaller than −1, the value of the displacement “ME” is not changed and the process proceeds to step S8 in FIG. Return.
[0174]
Next, the envelope follower process (S8) when the first mode is 2, 3, 4, or 5 will be described.
If it is determined in step S92 that the first mode is not 1 (S92, NO), it is determined in step S93 whether it is equal to the first mode 6 or 7. If “NO” is determined in the step S93, the process proceeds to a step S111 in the flowchart of FIG.
[0175]
The envelope follower process (S8) in the first mode 2 will be described with reference to the flowchart (part 2) of the envelope follower process of FIG.
[0176]
If it is the first mode 2, “YES” is determined when it is determined in step S111 whether or not the mode is the first mode 2.
The first mode 2 starts from a state where the change control of the value of the first change target timbre parameter is not performed, and the first change is made every time the foot controller 48 of the switch panel 7 is pressed (turned on). Since the state of changing and controlling the value of the target tone color parameter is alternately repeated, in order to determine whether or not the state of the foot controller 48 of the switch panel 7 has changed, first, “FFT F” ≠ “FT F Is determined (S112).
[0177]
If “FFT F” ≠ “FT F” (S112, YES), that is, if the state of the foot controller 48 of the switch panel 7 has changed, is the state of the foot controller 48 of the switch panel 7 changed from OFF to ON? In order to determine whether or not, “FT F” = “1” is determined (S113).
[0178]
   If “FT F” = “1” (S113, YES), that is, if the state of the foot controller 48 of the switch panel 7 changes from OFF to ON, whether or not “HEF” is “0” (change for the first time) Do you want the amount ME or already change amount METheIt is determined whether the change control is performed (S115). Envelope follower processing (S8) and pitch follower processing (S9).
[0179]
If “HE F” = “0” (S115, YES), the process proceeds to step S100 in FIG. 20, “1” is set to “HE F”, and the change amount “ME” is obtained in steps S102 to S107 described above. Process. That is, the state shifts from the state where the value of the first change target timbre parameter is not subjected to change control to the state where change control is performed.
[0180]
If "HE F" is not "0" (S115, NO), "0" is set to "HE F" (S117), and the process returns to step S8 in FIG. That is, the state is changed from the state in which the value of the first change target timbre parameter is change-controlled to the state in which no change control is performed.
[0181]
If it is determined in step S113 that “FT F” = “1” is not satisfied (S113, NO), that is, if the state of the foot controller 48 of the switch panel 7 is changed from on to off, “HE F”. It is determined whether or not “1” (S116).
[0182]
If “HE F” = “1” (YES in S116), the control of changing the value of the first change target timbre parameter is continued, so the process proceeds to step S102 ”in FIG. 20, and the change is made in steps S102 to S107 described above. A process for obtaining the quantity “ME” is performed.
[0183]
If “HE F” = “1” is not satisfied (S116, NO), the process returns to step S8 in FIG. 12 in order to maintain the state where the value of the first change target timbre parameter is not changed.
[0184]
If “FFT F” ≠ “FT F” is not satisfied in step S112 (S112, NO), that is, if there is no change in the state of the foot controller 48 of the switch panel 7, “HE F” = “1” or not. Is determined (S114).
[0185]
If “HE F” = “1” (S114, YES), whether or not the envelope value (input envelope level value) of the input signal is lower than the value of the first threshold parameter “THE” in the temporary memory 71. To determine whether or not “LC” <“THE” (S118).
[0186]
If “LC” <“THE” (S118, YES), that is, if the envelope value of the input signal falls below the value of the first threshold parameter “THE”, the first change target timbre parameter 12 is set to “HE F” (S119), “ME” is set to “0” (S120), and step S8 in FIG. 12 is performed. Return to
[0187]
If “LC” <“THE” is not satisfied (S118, NO), that is, if the envelope value of the input signal is not less than the value of the first threshold parameter “THE”, the first Since control for changing the value of the change target tone color parameter is continued, the process proceeds to step S102 "in FIG.
[0188]
If “HE F” = “1” is not satisfied in step S114 (S114, NO), the process returns to step S8 in FIG. 12 in order to maintain the state where the value of the first change target timbre parameter is not changed.
[0189]
Next, the envelope follower process (S8) in the case of the first mode 3 will be described with reference to the flowchart (part 3) of the envelope follower process of FIG.
[0190]
The first mode 3 is “YES” when it is determined in step S131 whether or not it is the first mode 3.
The first mode 3 performs change control of the value of the first change target timbre parameter from the initial stage, and every time the foot controller 48 of the switch panel 7 is pressed (turned on), the first change target is changed. Since the state of changing and controlling the timbre parameter value is alternately repeated, in order to determine whether or not the state of the foot controller 48 of the switch panel 7 has changed, first, “FFT F” ≠ “FT F” Whether or not (S132).
[0191]
If “FFT F” ≠ “FT F” (S132, YES), that is, if the state of the foot controller 48 of the switch panel 7 has changed, is the state of the foot controller 48 of the switch panel 7 changed from OFF to ON? In order to determine whether or not, “FT F” = “1” is determined (S133).
[0192]
If “FT F” = “1” (S133, YES), that is, if the state of the foot controller 48 of the switch panel 7 changes from OFF to ON, whether “HEF” = “1” (change for the first time) Do you want the amount ME or already change amount “ME”TheIt is determined whether the change control is performed (S135).
[0193]
If “HE F” = “1” (S135, YES), “0” is set to “HE F” (S137), and the process returns to step S8 in FIG. That is, if the value of the first change target timbre parameter is currently under change control, the state shifts to a state in which no change control is performed.
[0194]
If “HE F” is not “1” (S135, NO), the process proceeds to step S100 in FIG. 20, “1” is set to “HE F”, and the change amount “from step S102 to S107 described above” The process for obtaining ME "is performed. That is, if the value of the first change target timbre parameter is not currently changed and controlled, the process shifts to the change control state.
[0195]
If it is determined in step S133 that "FT F" is not "1" (S133, NO), that is, if the state of the foot controller 48 of the switch panel 7 is changed from on to off, "HE F" Is determined to be “1” (S136).
[0196]
If “HE F” = “1” (YES in S136), the control for changing the value of the first change target timbre parameter is continued, so the process proceeds to step S102 ”in FIG. 20, and the change is made in steps S102 to S107 described above. A process for obtaining the quantity “ME” is performed.
[0197]
If “HE F” = “1” is not satisfied (S136, NO), the process returns to step S8 in FIG. 12 in order to maintain the state where the value of the first change target timbre parameter is not changed.
[0198]
If “FFT F” ≠ “FT F” is not satisfied in step S132 (S132, NO), that is, if there is no change in the state of the foot controller 48 of the switch panel 7, “IN FE” is “0” or not. Is determined (S134).
[0199]
If “IN FE” is “0” (S134, YES), it is an initial state in which the mode is switched to the first mode 3, and change control of the value of the first change target timbre parameter is started, so “IN FE”. After “1” is set (S138), the process proceeds to step S102 in FIG. 20, and processing for obtaining the change amount “ME” is performed in steps S102 to S107 described above.
[0200]
If “IN FE” is not “0” (S134, NO), it is determined whether “HE F” is “0” (S139).
If “HE F” is “0” (S139, YES), the process returns to step S8 in FIG. 12 in order to maintain the state where the value of the first change target timbre parameter is not changed.
[0201]
If “HE F” is not “0” (S139, NO), the control of changing the value of the first change target timbre parameter is continued. Therefore, the process proceeds to step S102 in FIG. In S107, a process for obtaining the change amount “ME” is performed.
[0202]
Next, the envelope follower process (S8) in the case of the first mode 4 will be described with reference to the flowchart (part 4) of the envelope follower process of FIG.
[0203]
The first mode 4 is “YES” when it is determined in step S151 whether or not it is the first mode 4.
In the first mode 4, the change control of the value of the first change target timbre parameter is performed only while the foot controller 48 of the panel switch 7 is being pressed (only while the foot controller 48 is turned on), and the foot controller 48 of the panel switch 7 is controlled. When the button is released (turned off), the current value of the first change target timbre parameter is held, so that “FT F” is set to “1” when the state of the foot controller 48 of the switch panel 7 is on. It is determined whether or not “1” (S152).
[0204]
If “FT F” is “1” (S152, YES), that is, if the foot controller 48 of the switch panel 7 is pressed and change control of the value of the first change target timbre parameter is performed, FIG. The process proceeds to step S100 in step 20, where “1” is set in “HE F”, and the process of obtaining the change amount “ME” is performed in steps S102 to S107 described above, that is, the value of the first change target timbre parameter value Start or continue change control.
[0205]
If “FT F” is “0” (S152, NO), “HE F” is set to “0” (S153), and the process returns to step S8 in FIG. That is, the state shifts to the state where the change control of the value of the first change target timbre parameter is stopped or the state where the change control is not performed is continued.
[0206]
Next, the envelope follower process (S8) in the first mode 5 will be described with reference to the flowchart (part 4) of the envelope follower process of FIG.
[0207]
The first mode 5 is “NO” when it is determined in step S151 whether or not it is the first mode 4, and the process proceeds to step S154.
In the first mode 5, the value of the first change target timbre parameter is controlled from the initial stage, and the value of the first change target timbre parameter is changed only while the foot controller 48 of the panel switch 7 is being pressed. Since the control is stopped, it is determined whether or not “FT F”, which is set to “1” when the state of the foot controller 48 of the switch panel 7 is ON, is “0” (S154).
[0208]
If the foot controller 48 of the switch panel 7 is not operated and “FT F” is “0” (S154, YES), that is, the foot controller 48 of the switch panel 7 is not pressed, and the first change target tone parameter is changed. If the value change control is to be performed, the process proceeds to step S100 in FIG. The change control of the value of the first change target timbre parameter is started or continued.
[0209]
If “FT F” is “1” (S154, NO), “HE F” is set to “0” (S155), and the process returns to step S8 in FIG. That is, the state where the change control of the value of the first change target timbre parameter is stopped or the state where the change control is not performed is continued.
[0210]
Next, the envelope follower process (S8) in the first mode 6 or 7 will be described with reference to the flowchart (part 1) of the envelope follower process of FIG.
[0211]
In the first mode 6 or 7, change control is performed or stopped depending on whether or not the current value “Lc” of the input envelope level is greater than the value of the first threshold parameter “THE” in the temporary memory 71. If it is determined in step S93 that the mode is 6 or 7 (S93, YES), is the current value “Lc” of the input envelope level greater than the value of the first threshold parameter “THE”? (S94), if the value of the first threshold parameter “THE” is greater than the current value “Lc” of the input envelope level (S94, YES), the flag “ET” is set to “1”. Is set (S95).
[0212]
If the value of the first threshold parameter “THE” is smaller than the current value “Lc” of the input envelope level (S94, NO), “0” is set to the flag “ET” (S96).
[0213]
Then, it is determined whether the first mode is 6 or 7 (S97).
If it is the first mode 6 (S97, YES), change control is performed when the current value “Lc” of the input envelope level is equal to or greater than the value of the first threshold parameter “THE” in the temporary memory 71. It is determined whether “ET” is “1” (the current value “Lc” of the input envelope level is equal to or greater than the first threshold parameter “THE” in the temporary memory 71) (S99). If “1” (S99, YES), “1” is set to “HE F” (S100).
[0214]
Then, processing for obtaining the change amount “ME” is performed in steps S102 to S107 described above.
If “ET” is not “1” (S99, NO), “HE” is set to “0” without performing the process for obtaining the change amount “ME” (S101), and step S8 in FIG. Return to
[0215]
In the first mode 7 (S97, NO), the change control is performed when the current value “Lc” of the input envelope level is smaller than the value of the first threshold parameter “THE” in the temporary memory 71. It is determined whether “ET” is “0” (the current value “Lc” of the input envelope level is smaller than the value of the first threshold parameter “THE” in the temporary memory 71) (S98). If “ET” is “0” (S98, YES), “1” is set in “HE F” (S100).
[0216]
Then, processing for obtaining the change amount “ME” is performed in steps S102 to S107 described above.
If “ET” is not “0” (S98, NO), the process for obtaining the change amount “ME” is not performed, “0” is set in “HE F” (S101), and step S8 in FIG. 12 is performed. Return to
[0217]
As described above, the envelope follower processing in the first modes 1, 2, 3, 4, 5, 6, and 7 is executed.
Here, FIG. 24 shows an example of a change in the displacement “ME” obtained by the envelope follower process (S8) described above with respect to the value of the input envelope level.
[0218]
The characteristic function 101 indicating the value of the displacement “ME” with “Lc”, “Li”, and “Lr” as variables is −Lc / Li in the range of Lc <Li, as can be seen from the processing in step S105. The value of “ME” varies within the range of 0% to −100%.
[0219]
  At the point of Lc = Li, the value (= “ME”) of the characteristic function 101 is 0, as can be seen from the processing in step S104. In the range of Lc> Li, as can be seen from the processing in step S103, the characteristic function 101 is (Lc−Li) / (Lr−Li) And the value of “ME” varies within the range of 0% to 100%.
[0220]
If the characteristic function 101 of the “ME” value is larger than 1 or smaller than “−1”, the characteristic function 101 of the “ME” value is compulsorily processed by the process of step S107. Is set to “1” or “−1”.
[0221]
Returning to the description of the overall processing in FIG.
Next, the pitch is set using the initial value of the input pitch (expressed as “Pi” for convenience) and the current value (expressed as “Pc” for convenience) set to “Pi” or “Pc” by the input process (S7). Follower processing (S9) is performed.
[0222]
The pitch follower process (S9) is based on the change control mode set by the pitch follower setting process (S12) and the initial value “Pi” and the current value “Pc” of the input pitch set by the input process (S7). In this process, the displacement amount “MP” is obtained.
[0223]
The details of the pitch follower process (S9) will be described with reference to the flowcharts (No. 1 to No. 4) of the pitch follower process of FIGS.
The second modes 0 to 7 described below are determined by referring to the value of the mode designation parameter set in “MODE P” of the temporary memory 71.
[0224]
Further, the value of the second change target timbre parameter described below is set by the player in the pitch follower setting process (S13) and is currently set in the temporary memory 71.
[0225]
First, the pitch follower process (S9) in the case of the second mode 0 will be described with reference to the flowchart (part 1) of the pitch follower process of FIG.
Since the second mode 0 is a mode in which the change control of the value of the second change target timbre parameter is not performed regardless of the state of the foot controller 48 of the panel switch 7, it is determined whether or not it is the second mode 0 ( If the second mode is 0 (S161), the process returns to step S10 in FIG. 12 as it is.
[0226]
Next, the pitch follower process (S9) in the case of the second mode 1 will be described with reference to the flowchart (part 1) of the pitch follower process of FIG.
The second mode 1 is a mode in which the value of the second change target timbre parameter is constantly changed regardless of the state of the foot controller 48 of the panel switch 7, so it is determined whether or not it is the second mode 1. If it is the second mode 1 (S162, YES), “1” is set to “HP F” (S170), and the displacement “MP” is calculated from step 172 to step S174.
[0227]
From the initial value “Pi” and the current value “Pc” of the input pitch, the displacement amount “MP” is obtained as follows (S172).
MP = (Pc−Pi) / (100 × Pr) (4)
In order to prevent an unnatural timbre change due to an extremely large displacement amount “MP”, the displacement amount “MP” is greater than 1 or the displacement amount “MP” is It is determined whether or not it is smaller than −1 (S173). If the displacement amount “MP” is greater than 1 (S173, YES), the displacement amount “MP” is forcibly set to 1 (S174). If the value of the displacement “MP” is smaller than −1 (S173, YES), the value of the displacement “MP” is forcibly set to −1 (S174), and the process returns to step S9 in FIG.
[0228]
When the displacement amount “MP” is not greater than 1 or when the displacement amount “MP” is not less than −1 (S173, NO), the displacement amount “MP” is left as it is.
[0229]
Next, the pitch follower process (S9) when the second mode is 2, 3, 4, and 5 will be described with reference to the flowcharts (No. 2 to No. 4) of the pitch follower process of FIGS. To do.
[0230]
The pitch follower process (S9) in the second mode 2 will be described with reference to the pitch follower process flowchart (part 2) in FIG.
If it is the second mode 2, it is “YES” when it is determined in step S181 whether or not it is the second mode 2.
[0231]
The second mode 2 starts from a state in which the change control of the value of the second change target timbre parameter is not performed, and every time the foot controller 48 of the switch panel 7 is pressed (turned on), the second mode 2 Since the state of changing and changing the value of the timbre parameter to be changed is alternately repeated, in order to determine whether or not the state of the foot controller 48 of the switch panel 7 has changed, first, “FFT F” ≠ “FT It is determined whether or not F ″ (S182).
[0232]
If “FFT F” ≠ “FT F” (S182, YES), that is, if the state of the foot controller 48 of the switch panel 7 has changed, has the state of the foot controller 48 of the switch panel 7 been changed from OFF to ON? In order to determine whether or not, “FT F” = “1” is determined (S183).
[0233]
If “FT F” = “1” (S183, YES), that is, if the state of the foot controller 48 of the switch panel 7 is changed from OFF to ON, whether “HP F” is “0” (already already). The change amount “MP” is obtained to determine whether change control is being performed) (S185).
[0234]
If “HP F” = “0” (S185, YES), the process proceeds to step S170 in FIG. 25, “1” is set in “HP F”, and the change amount “MP” is set in steps S172 to S174 described above. That is, the process shifts to a state in which change control of the value of the second change target timbre parameter is started or resumed.
[0235]
If “HP F” = “0” is not satisfied (S185, NO), “HP F” is set to “0” (S187), and the process returns to step S9 in FIG. That is, the state of changing the value of the second change target timbre parameter is shifted to the state of not changing.
[0236]
If it is determined in step S183 that "FT F" is not "1" (S183, NO), that is, if the state of the foot controller 48 of the switch panel 7 is changed from on to off, "HP F" It is determined whether or not “1” (S186).
[0237]
If “HP F” = “1” (YES in S186), control for changing the value of the second change target timbre parameter is continued, so the process proceeds to step S172 ”in FIG. 25, and the change is made in steps S172 to S174 described above. A process for obtaining the quantity “MP” is performed.
[0238]
If “HP F” = “1” is not satisfied (S186, NO), the process returns to step S9 in FIG. 12 in order to maintain the state where the change control of the value of the second change target timbre parameter is not performed.
[0239]
If “FFT F” ≠ “FT F” is not satisfied in step S182 (S182, NO), that is, if there is no change in the state of the foot controller 48 of the switch panel 7, “HP F” = “1” or not. Is determined (S184).
[0240]
If “HP F” = “1” (S184, YES), since the foot controller 48 is on, the pitch value (input pitch value) of the input signal is set by the second threshold parameter “TH P”. In order to determine whether or not the value is less than the specified value, it is determined whether or not “PC” <“TH P” (S188).
[0241]
If “PC” <“TH P” (S188, YES), that is, if the pitch value of the input signal falls below the value set by the second threshold parameter “TH P”, the second change is made. To return the value of the target tone color parameter to the value before the change, “HP” is set to “0” (S189), “MP” is set to “0” (S190), and step S9 in FIG. Return to
[0242]
If “LC” <“TH P” is not satisfied (S188, NO), that is, if the pitch value of the input signal is not less than the value set by the second threshold parameter “TH P”, Since control for changing the value of the second change target timbre parameter is continued, the process proceeds to step S172 "in FIG. 25, and processing for obtaining the change amount" MP "is performed in steps S172 to S174.
[0243]
If “HP F” = “1” is not satisfied in step S184 (S184, NO), the process returns to step S9 in FIG. 12 in order to maintain the state where the change control of the value of the second change target timbre parameter is not performed. .
[0244]
Next, the pitch follower process (S9) in the case of the second mode 3 will be described with reference to the pitch follower process flowchart (part 3) in FIG.
[0245]
The second mode 3 is “YES” when it is determined in step S201 whether or not it is the second mode 3.
In the second mode 3, change control of the value of the second change target timbre parameter is performed from the initial stage, and whenever the foot controller 48 of the switch panel 7 is pressed (turned on), the second change target is changed. Since the state of changing and controlling the timbre parameter value is alternately repeated, in order to determine whether or not the state of the foot controller 48 of the switch panel 7 has changed, first, “FFT F” ≠ “FT F” Whether or not (S202).
[0246]
If “FFT F” ≠ “FT F” (S202, YES), that is, if the state of the foot controller 48 of the switch panel 7 has changed, has the state of the foot controller 48 of the switch panel 7 changed from OFF to ON? In order to determine whether or not, “FT F” = “1” is determined (S203).
[0247]
If “FT F” = “1” (S203, YES), that is, if the state of the foot controller 48 of the switch panel 7 is changed from OFF to ON, whether “HP F” = “1” (already already). The change amount “MP” is obtained to determine whether change control is being performed) (S205).
[0248]
If “HP F” = “1” (S205, YES), “0” is set to “HP F” (S207), and the process returns to step S9 in FIG. That is, the state shifts from the state in which the value of the second change target timbre parameter is change-controlled to the state in which no change control is performed.
[0249]
If “HP F” = “1” is not satisfied (S205, NO), the process proceeds to step S170 in FIG. 25, “HP F” is set to “1”, and the change amount “from step S172 to S174 described above” MP ″ is obtained. That is, the process shifts from the state where the change control of the value of the second change target timbre parameter is not performed to the state where it is performed.
[0250]
If it is determined in step S203 that “FT F” = “1” is not satisfied (S203, NO), that is, if the state of the foot controller 48 of the switch panel 7 changes from on to off, “HP F”. Is determined to be “1” (S206).
[0251]
If “HP F” = “1” (YES in S206), the control of changing the value of the second change target timbre parameter is continued, so that the process proceeds to step S172 ”in FIG. 25 and the change amount“ from step S172 to S174 ” MP ”is obtained.
[0252]
If “HP F” = “1” is not satisfied (S206, NO), the process returns to step S9 in FIG. 12 in order to maintain the state in which the value of the second change target timbre parameter is not changed.
[0253]
If “FFT F” ≠ “FT F” is not satisfied in step S202 (S202, NO), that is, if there is no change in the state of the foot controller 48 of the switch panel 7, “IN FP” is “0” or not. Is determined (S204).
[0254]
If “IN FP” is “0” (YES in S204), it is the initial state in which the mode is switched to the second mode 3, and the change control of the value of the second change target timbre parameter is started, so “IN FP” Is set to “1” (S208), the process proceeds to step S172 in FIG. 25, and processing for obtaining the change amount “MP” is performed in steps S172 to S174 described above.
[0255]
If “IN FP” is not “0” (S204, NO), it is determined whether “HP F” is “0” (S209).
If “HP F” is “0” (S209, YES), the process returns to step S9 in FIG. 12 in order to maintain the state where the value of the second change target timbre parameter is not changed.
[0256]
If “HP F” is not “0” (S209, NO), the control of changing the value of the second to-be-changed tone color parameter is continued, so the process proceeds to step S172 in FIG. 25, and from step S172 described above. In S174, a process for obtaining the change amount “ME” is performed.
[0257]
Next, the pitch follower process (S9) in the case of the second mode 4 will be described with reference to the flowchart (part 4) of the pitch follower process of FIG.
The second mode 4 is “YES” when it is determined in step S210 whether or not it is the second mode 4.
[0258]
In the second mode 4, the control of changing the value of the second change target tone color parameter is performed only while the foot controller 48 of the panel switch 7 is being pressed (only while the foot controller 48 is on), and the foot controller 48 of the panel switch 7 is controlled. When the button is released, the value of the second to-be-changed timbre parameter at that time is held, so that “1” is set when the state of the foot controller 48 of the switch panel 7 is on. “FT F” is “1” or not Is determined (S211).
[0259]
If “FT F” is “1” (S211, YES), that is, if the foot controller 48 of the switch panel 7 is pressed and the change control of the value of the second change target timbre parameter is performed, FIG. Then, the process proceeds to step S170 in step 25, "1" is set in "HP F", and the process of obtaining the change amount "MP" is performed in steps S172 to S174 described above, that is, the value of the second change target timbre parameter value Start or continue change control.
[0260]
If “FT F” is not “1” (S211, NO), “HP F” is set to “0” (S212), and the process returns to step S9 in FIG. That is, the process shifts to a state where the change control of the value of the second change target timbre parameter is stopped, or the state where the change control is not performed is maintained.
[0261]
Next, the pitch follower process (S9) in the second mode 5 will be described with reference to the flowchart (part 4) of the pitch follower process of FIG.
The second mode 5 is “NO” when it is determined in step S210 whether the second mode 4 or not, and the process proceeds to step S213.
[0262]
In the second mode 5, the change control of the value of the second change target timbre parameter is performed from the initial stage, and the change control is stopped only while the foot controller 48 of the panel switch 7 is being pressed (while being turned on). Therefore, when the state of the foot controller 48 of the switch panel 7 is ON, it is determined whether or not “FT F” set to “1” is “0” (S213).
[0263]
If there is no operation of the foot controller 48 of the switch panel 7 and “FT F” is “0” (S213, YES), that is, the foot controller 48 of the switch panel 7 is not pressed, and the second change target timbre parameter If value change control is to be performed, the process proceeds to step S170 in Fig. 25, where "HP F" is set to "1", and processing for obtaining the change amount "MP" is performed in steps S172 to S174 described above. The control for changing the value of the second change target tone color parameter is started or continued.
[0264]
If "FT F" is not "0" (S213, NO), "HP" is set to "0" (S214), and the process returns to step S9 in FIG. That is, the process shifts to a state where the change control of the value of the second change target timbre parameter is stopped, or the state where the change control is not performed is maintained.
[0265]
Next, the pitch follower process (S9) in the second mode 6 or 7 will be described with reference to the flowchart (No. 1) of the pitch follower process of FIG.
[0266]
In the second mode 6 or 7, the value of the second change target timbre parameter depends on whether or not the current value Pc of the input pitch is larger than the value of the second threshold parameter “TH P” of the temporary memory 71. Therefore, it is determined whether or not the current value “Pc” of the input pitch is larger than the value of the second threshold parameter “TH P” (S164). If the value of the second threshold parameter “TH P” is less than or equal to the current value “Pc” of the input pitch, “1” is set to the flag “PT” (S165), and the threshold “TH P” is the pitch. If it is smaller than the current value “Pc”, “0” is set to the flag “PT” (S166).
[0267]
Then, it is determined whether the second mode is 6 or 7 (S167).
In the second mode 6, when the current value “Pc” of the input pitch is larger than the second threshold value “TH P” of the temporary memory 71, change control of the value of the second change target timbre parameter is performed. Therefore, it is determined whether or not “PT” is “1” (S169). If “PT” is “1” (YES in S169), “1” is set in “HP F” (S170), and In step 172 to step S174, the displacement amount “MP” is calculated.
[0268]
If “PT” is not “1” (S169, NO), “HP” is set to “0” without performing the process for obtaining the change amount “MP” (S171), and step S9 in FIG. 12 is performed. Return to
[0269]
In the second mode 7, when the current value “Pc” of the input pitch is equal to or smaller than the second threshold parameter “TH P” of the temporary memory 71, the value of the second change target tone color parameter is Since change control is performed, it is determined whether or not “PT” is “0” (S168). If “PT” is “0” (S168, YES), “1” is set in “HP F” (S170). ) In step 172 to step S174 described above, the displacement “MP” is calculated.
[0270]
If “PT” is not “0” (S168, NO), the process for obtaining the change amount “MP” is not performed and the process proceeds to step S171, where “HP F” is set to “0”. The process returns to step S9.
[0271]
Here, FIG. 29 shows an example of a change in the displacement “MP” obtained by the pitch follower process (S9) with respect to the input pitch value “Pc”.
The characteristic function 111 indicating the value of the displacement “MP” with “Pc”, “Pi”, and “Pr” as variables is obtained from the equation (4) in the range of −100 × Pr ≦ Pc−Pi ≦ 100 × Pr. The calculated values are all −1 for Pc−Pi <−100 × Pr, and all 1 for Pc−Pi> 100 × Pr.
[0272]
Returning to the description of the overall processing in FIG.
As described above, when the displacement amount “ME” is obtained by the envelope follower process (S8) and the displacement amount “MP” is obtained by the pitch follower process (S9), the displacement amounts “ME”, “ Based on “MP”, a change control process (S10) of the value of the change target timbre parameter is performed.
[0273]
The details of the change control process (S12) of the value of the change target timbre parameter will be described with reference to the flowchart of FIG.
When the first change target timbre parameter subject to change control in the envelope follower process (S8) and the second change target timbre parameter subject to change control in the pitch follower process (S9) are the same The case where both are different will be described separately.
[0274]
First, the first change target timbre parameter that is subject to change control in the envelope follower process (S8) and the second change target timbre parameter that is subject to change control in the pitch follower process (S9). The same case will be described.
[0275]
When both are the same, it is determined whether “SAME F”, which is set to “1”, is “1” (S221), the result is YES, and the value of displacement “ME” and the value of displacement “MP” are added together. Then, the total result is set to the displacement “ME” (S222).
[0276]
  In order to prevent an unnatural timbre change due to an extremely large displacement amount “ME”, the displacement amount “ME” is greater than 1 or the displacement amount “ME”. It is determined whether or not the value is smaller than −1 (S223). If the value of the displacement “ME” is larger than 1 (S223, YES), the displacement “ME” is forcibly set to 1 (S224). 1). When the displacement amount “ME” is smaller than −1 (S223, NO), the displacement amount “ME” is forcibly set to −1 (S224-2).
[0277]
Then, the first change target tone color is set using the first change target tone parameter setting value Vie set in the envelope follower setting processing (S12) and the displacement amount “ME” set in the envelope follower processing (S8). Change and control parameter values.
[0278]
That is, the magnitude of the displacement amount “ME” is determined (S230), and a new value Vne of the first change target timbre parameter is obtained by the following equation in accordance with the magnitude of the displacement amount “ME”.
・ When ME> 0 (S231)
Vne = Vie + (Vimaxe−Vie) × ME × DEPTH E (5)
When ME = 0 (S232)
Vne = Vie (6)
・ When ME <0 (S233)
Vne = Vie− (Vie−Vine) × ME × DEPTH E (7)
Note that Vimaxe is the maximum value that can be taken by the value Vie of the first change target tone color parameter, and Vimine is the minimum value that can be taken by the value Vie of the first change target tone color parameter. These values are shown in FIG. As shown in
[0279]
Then, the value of the first change target timbre parameter corresponding to the parameter number set in “PARAMETER E” of the temporary memory 71 is changed to Vne (S234), and the process returns to step S10 in the flowchart of FIG.
[0280]
In this way, the setting of the value Vne of the first change target timbre parameter that is controlled to change based on the value of the input envelope level and the pitch (input pitch) of the inputted performance information is completed.
[0281]
In step S230 to step S233, the value of Vne may be obtained using the value of the displacement “ME” obtained in the envelope follower process (S8) as it is. Further, the displacement amount “MP” obtained in the pitch follower process (S9) may be used in place of the displacement amount “ME” obtained by the above summation to obtain the value of Vne.
[0282]
Next, a case where the first change target timbre parameter of the envelope follower process (S8) and the second change target timbre parameter of the pitch follower process (S9) are different will be described.
[0283]
In this case, when it is determined whether or not “SAME F” is “1” (S221), NO is determined, and change control of the values of the first and second change target timbre parameters is performed in steps S225 to S234. .
[0284]
  First, the magnitude of the value of the displacement “MP” is determined (S225), and according to the magnitude of the value of the displacement “MP”,SecondA new value Vnp of the change target timbre parameter is obtained as follows.
When MP> 0 (S226)
Vnp = Vip + (Vimaxp−Vip) × MP × DEPTHP (8)
When MP = 0 (S227)
Vnp = Vip (9)
When MP <0 (S228)
Vnp = Vip− (Vip−Viminp) × MP × DEPTHP (10)
Vimaxp is the maximum value that can be taken by the value Vip of the second change target timbre parameter, and Viminp is the minimum value that can be taken by the value Vip of the second change target timbre parameter. These values are shown in FIG. As shown in
[0285]
Then, the value of the second change target timbre parameter corresponding to the parameter number set in “PARAMETER P” of the temporary memory 71 is changed to Vnp (S229).
[0286]
  Next, the processing of steps S230 to S234 described above is executed, and the first change target tone parameter setting value Vin set in the envelope follower setting processing (S12) and the displacement amount “set in the envelope follower processing (S8)”METhe change value Vne of the first change target timbre parameter is obtained using the value "".
[0287]
Here, change target timbre parameter value change control according to the amount of displacement of the input envelope level value or the input signal pitch (input pitch value) value performed by the change target timbre parameter change control process (S10). FIG. 31 shows a characteristic function 121 representing an example.
[0288]
In the figure, the vertical axis is the change value Vne or Vnp (= Vn) of the first or second change target tone color parameter, and the horizontal axis is the displacement “ME” of the input envelope level value or the pitch of the input signal. Is a multiplication value (= M × DEPTH) of the displacement amount “MP” of the value of “1” and the value of the first modulation depth parameter “DEPTH E” or the value of the second modulation depth parameter “DEPTH P”. .
[0289]
Further, in the same figure, initial values Vie and Vip of the value of the first or second change target timbre parameter are indicated by Vi.
As indicated by the characteristic function 121, the change target timbre parameter value Vn increases or decreases in proportion to the value of M × DEPTH.
[0290]
In the characteristic function 121, the absolute value of the maximum value Vmax (Vimaxe or Vimaxp) of the first or second change target timbre parameter is the absolute value of the minimum value Vmin (Vimine or Viminp) of the change target timbre parameter. Is bigger than. Therefore, when the displacement amount “ME” or “MP” is positive, the values Vne and Vnp (= Vn) of the first or second change target timbre parameter change more greatly than when the displacement amount is negative.
[0291]
The value Vn of the first or second change target timbre parameter is clipped to Vmax or Vmin when the absolute value exceeds the absolute value of Vmax or Vmin.
[0292]
An example of how the acoustic effect is changed by the effector 1 of the embodiment of the present invention is shown in FIG.
In FIG. 32, the vertical axis represents the reverberation volume value and the pitch value, and the horizontal axis represents time, and represents the temporal change in the pitch value and the reverberation volume value.
[0293]
The conditions set by the switch panel 7 are change control: pitch follower only, mode: 2, change target timbre parameter: chorus “DEPTH P”, and FIG. 32 shows the pitch value of the input signal at this time. A function 132 indicating a temporal change and a characteristic function 131 indicating a reverberant volume value are shown.
[0294]
In the second mode 2, when the parameter change control is not performed, if the foot controller 48 of the switch panel 7 is continuously pressed from a predetermined time “a”, the characteristic function 131 is generated from that time “a”. As shown, the value of the reverberation volume changes with time in the opposite polarity to the change of the pitch value.
[0295]
Returning to the description of the overall processing of the effector 1 in FIG.
When the edit mode process (S2) or the play mode process (S3) is completed, it is determined whether or not the power of the effector 1 is turned off (S4). If the power is turned off (S4, YES), the effector 1 is turned off. Thus, the entire process is completed. If the power is not turned off (S4, NO), the above-described steps S1 to S3 are executed, and the entire process is continued.
[0296]
As described above, the pitch value and the envelope level are extracted from the performance information (input signal i) generated according to the performance operation performed by the performer on the electric guitar 91, and based on the temporal displacement amount of the extracted information. The preset sound effect can be added to the musical sound emitted from the guitar amplifier 93 by temporally changing and controlling the value of the tone color parameter to be changed.
[0297]
In addition to the input envelope level value or the input signal pitch value, the time-varying control of the timbre parameter value may be controlled according to other performance operations such as key pressing of a velocity value, for example. You may make it perform based on the value of the information to generate | occur | produce.
[0298]
In addition, as described above, it is not an added value of two kinds of displacements, that is, the temporal displacement of the input envelope level value and the temporal displacement of the input signal pitch value. The value of the timbre parameter may be controlled to be changed based on the temporal displacement amount of the value of other types of information generated in response to this and the total value of these displacement amounts.
[0299]
Furthermore, by setting an arbitrary function having the various information as variables, and setting the value of the function as the value of the timbre parameter, the value of the timbre parameter may be controlled to be changed.
[0300]
【The invention's effect】
  As described above, the present invention provides a plurality of change controls for controlling the value of the timbre parameter based on at least one timbre parameter value and a plurality of operation information from one or a plurality of performance operators. Means for setting / storing timbre change control information comprising parameter values, and selecting one from the stored timbre change control informationmeansAnd means for detecting temporal displacement amounts of a plurality of performance information from one or a plurality of performance operators.
[0301]
Further, the timbre parameter value set in the timbre change control information selected by the selection means in response to an instruction from the switch means is provided for instructing execution and stop of the timbre parameter change control. On the basis of the change control parameter value, which is also set in the timbre change control information, to the temporal displacement amounts of the plurality of operation information from the one or more performance operators detected by the detecting means. Correspondingly, since the value of the timbre parameter is controlled to be changed over time, the performer can easily perform the musical tone data generated only when desired, not by the simple operation of the switch means during the performance. A variety of sound effects can be imparted.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of an embodiment of the present invention.
FIG. 2 is a configuration diagram of an envelope detection unit.
FIG. 3 is a configuration diagram of a pitch-voltage conversion unit.
FIG. 4 is an external view of a switch panel.
FIG. 5 is a diagram illustrating an example of a configuration of a patch memory.
FIG. 6 is a diagram illustrating an example of patch contents.
FIG. 7 is a diagram illustrating a relationship between a patch memory and a temporary patch.
FIG. 8 is a functional block diagram related to the addition of a DSP sound effect.
FIG. 9 is a diagram showing a connection form when an electric guitar and a guitar amplifier are connected to the sound effect device.
FIG. 10 is a flowchart illustrating an entire process of the effector according to the embodiment of this invention.
FIG. 11 is a flowchart illustrating an edit mode process.
FIG. 12 is a flowchart illustrating play mode processing.
FIG. 13 is a flowchart illustrating a setting process.
FIG. 14 is a flowchart for explaining timbre parameter setting processing;
FIG. 15 is a diagram showing types of timbre parameters and ranges of their values.
FIG. 16 is a diagram illustrating an example of a change control parameter for an envelope follower and a change control parameter for a pitch follower.
FIG. 17 is a flowchart illustrating an envelope follower setting process.
FIG. 18 is a flowchart illustrating a pitch follower setting process.
FIG. 19 is a flowchart illustrating input processing.
FIG. 20 is a flowchart (part 1) illustrating an envelope follower process;
FIG. 21 is a flowchart (part 2) illustrating the envelope follower process;
FIG. 22 is a flowchart (part 3) illustrating the envelope follower process;
FIG. 23 is a flowchart (part 4) illustrating the envelope follower process;
FIG. 24 is a diagram showing the relationship between the displacement “ME” obtained by the envelope follower process and the value of the envelope.
FIG. 25 is a first flowchart illustrating a pitch follower process;
FIG. 26 is a flowchart (part 2) for explaining the pitch follower process;
FIG. 27 is a flowchart (part 3) illustrating the pitch follower process;
FIG. 28 is a flowchart (part 4) illustrating the pitch follower process;
FIG. 29 is a diagram illustrating a correlation between a displacement “MP” obtained by pitch follower processing and a pitch value.
FIG. 30 is a flowchart for explaining change target timbre parameter change control processing;
FIG. 31 is a diagram illustrating an example of change control of a change target timbre parameter value according to a displacement amount of an input envelope level value or an input signal pitch value performed by a change target timbre parameter change control process;
FIG. 32 is a diagram illustrating an example of a change in reverberant volume with respect to a change in pitch value.
[Explanation of symbols]
1 Effector
2 Envelope detector
3 Pitch-voltage converter
4 Analog multiplexer
5 A / D converter
6 I / O port I / F
7 Switch panel
8 RAM
9 ROM
10 CPU
10a storage medium
11 Low-pass filter
12 Input waveform A / D converter
13 DSP
14 Serial I / F
15 Output section
16 Data bus
21 First low-pass filter
22 Output waveform
23 Full-wave rectifier circuit
24 Output waveform
25 Second low-pass filter
26 Output waveform
31 Third low-pass filter
32 Output waveform
33 Comparator
34 Output waveform
35 monostable multivibrator
36 Output waveform
37 Fourth low-pass filter
38 Output waveform
42 Parameter selection switches
42-1 Parameter UP switch
42-2 Parameter DOWN switch
43 Value entry switches
43-1 Value UP switch
43-2 Value DOWN switch
44 Mode selector switch
45 Patch memory number display
46 Bank selector switches
46-1 Bank UP switch
46-2 Bank DOWN switch
47 Patch switch group
47-1 to 4 patch switches a to d
48 foot controller
49 LCD
61 Patch memory
62-1-8 banks ah
63-1 to 32 patches aa to ha
71 Temporary memory
81 Compressor section
82 Distortion Department
83 Parametric EQ section
84 Pitch shifter
85 Chorus
86 Delay section
87 Output section
91 Electric guitar
92 cable
93 Guitar amplifier
94 cable
101 Characteristic function of “ME” value
111 "MP" value characteristic function
121 Characteristic function of parameter value
131 Characteristic function of reverberant volume
132 Pitch value

Claims (6)

Timbre changing means for changing and outputting a tone color of a musical tone signal input based on a value of a timbre parameter stored in advance;
Parameter detection means for detecting a characteristic parameter from the input musical sound signal;
Switch means for instructing execution of timbre parameter change control;
Initial value storage means for storing the value of the characteristic parameter detected by the parameter detection means at the timing of the execution instruction by the switch means as an initial value;
After starting the execution instruction by the switch means, based on the value of the characteristic parameter detected by the parameter detection means at a predetermined timing period and the initial value stored in the initial value storage means, A displacement amount calculating means for calculating a displacement amount;
Each time the displacement amount is calculated by the displacement amount calculation means, a parameter calculation that calculates a new timbre parameter value based on the displacement amount and the previously stored timbre parameter value and supplies the calculated timbre parameter value to the timbre change means Means,
A timbre parameter change control device comprising: 2. The timbre parameter change control apparatus according to claim 1, wherein the parameter detecting means detects an envelope from the inputted musical tone signal as a characteristic parameter. 2. The timbre parameter change control apparatus according to claim 1, wherein the parameter detecting means detects a pitch from the input musical sound signal as a characteristic parameter. The displacement amount calculating means determines a magnitude relation between a characteristic parameter value detected by the parameter detecting means and an initial value stored in the initial value storage means at a predetermined timing period. Including
2. The timbre parameter change control apparatus according to claim 1, wherein the calculation method of the displacement amount of the characteristic parameter is made different based on the magnitude relation discriminated by the magnitude relation discriminating means. The displacement amount calculating means is configured to change the feature parameter based on a difference between a characteristic parameter value detected by the parameter detecting means at a predetermined timing period and an initial value stored in the initial value storage means. 2. The timbre parameter change control device according to claim 1, wherein the amount is calculated. Tone parameter change control having tone color changing means for changing and outputting a tone color of an input tone signal based on a pre-stored tone color parameter value and parameter detecting means for detecting a characteristic parameter from the input tone signal To the computer applied to the device,
An initial value storage function for storing the value of the detected characteristic parameter in the storage means as an initial value at the timing of execution instruction by the switch means for instructing execution of timbre parameter change control;
Displacement amount calculation for calculating the displacement amount of the feature parameter based on the value of the feature parameter detected at a predetermined timing period after the start of the execution instruction by the switch unit and the initial value stored in the storage unit Function and
A parameter calculation function that calculates a new timbre parameter value based on the displacement amount and the previously stored timbre parameter value and supplies the calculated timbre parameter value to the timbre changing means each time the displacement amount is calculated;
A computer-readable storage medium storing a program for realizing the above.