JP4096814B2 - Waveform modulation apparatus and waveform modulation program - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a waveform modulation device and a waveform modulation program for improving the degree of freedom and performance of vocoder performance.
[0002]
[Prior art]
2. Description of the Related Art There is known an apparatus that forms a musical sound by modulating a musical sound signal output from a sound source with a voice signal input from the outside. As this type of technology, for example, in Patent Document 1, an envelope level for each frequency band of an audio signal input from the outside is extracted using a plurality of bandpass filters having different pass frequency bands, and in response to this, An apparatus for generating a musical sound like a human voice by performing a so-called vocoder process for controlling the frequency characteristics of a musical sound to be automatically played is disclosed.
[0003]
The apparatus disclosed in Patent Document 1 generates a transient vocoder sound with poor reproducibility although it is excellent in improvised vocoder performance because it performs vocoder processing in accordance with an external input signal. Therefore, in the previous application (Japanese Patent Application No. 2003-071300), the present applicant applied the other key according to the formant component of the modulation waveform generated corresponding to the key operation of one key range of the key split key. A device that obtains a variety of vocoder sounds by changing the modulation timing according to the key operation of one key range when generating a vocoder sound by modulating the modulated waveform generated in response to the key operation of the range. I put it out.
[0004]
[Patent Document 1]
Japanese Patent No. 2808721
[0005]
[Problems to be solved by the invention]
By the way, the waveform modulation device devised in the above prior application is based on the vocoder sound according to the modulated waveform and the modulated waveform obtained by keying one and the other key ranges of the key-split keyboard with both left and right hands. Therefore, when a switch that variably sets the formant component of the modulation waveform is provided, the key is released as soon as you release your hand to operate the switch, which interrupts the vocoder sound that is sounding. There is a problem that the degree of freedom and performance of vocoder performance deteriorate.
Therefore, the present invention has been made in view of such circumstances, and an object thereof is to provide a waveform modulation device and a waveform modulation program capable of improving the degree of freedom and performance of vocoder performance.
[0008]
In the first aspect of the present invention, the first modulated waveform corresponding to the performance operation Or any one of the preset second modulation waveforms different from the first modulation waveform Generating means for generating a waveform and a modulated waveform, assigning means for assigning a function for instructing formant fixing and releasing the formant fixing to an operator operable simultaneously with the performance operation, and operation assigned to the function by the assigning means When the child instructs formant fixation The modulation waveform is 1 modulation waveform? The second Switching instruction means for instructing the waveform generation means to switch from the second modulation waveform to the first modulation waveform when the formant lock release is instructed to the modulation waveform of 2, and the function assignment by the assignment means When the designated operator instructs formant fixation, the second modulation waveform whose level is controlled in response to the formant fixation instruction and the formant of the first modulation waveform fixed when the formant fixation is instructed A first vocoder processing means for generating a first vocoder sound mixed with a modulated waveform modulated in accordance with a component; and when the operator assigned to the function by the assigning means instructs release of formant fixing, The first modulation waveform whose level is controlled in response to the unlocking instruction and the first modulation waveform whose unlocking is performed Characterized by comprising a second vocoder processing means for generating a second vocoder sound obtained by mixing a modulated waveform that is modulated in accordance with the mantle component.
[0009]
Claims above 1 Claims dependent on 2 In the invention described in the above, the waveform generating means follows a formant fixing instruction. Said From the first modulated waveform Said When switching to the second modulation waveform, Said The read address of the first modulation waveform is saved and stored according to the formant fixation release instruction. Said From the second modulated waveform Said When returning to the first modulation waveform, from the saved read address Said The first modulation waveform is reproduced.
[0010]
Claims above 1 Claims dependent on 3 In the invention described in the above, the waveform generating means follows a formant fixing instruction. Said From the first modulated waveform Said While switching to the second modulation waveform, Said Advance the read address of the first modulation waveform and follow the formant lock release instruction Said From the second modulated waveform Said When returning to the first modulation waveform, from the read address that has been advanced Said The first modulation waveform is reproduced.
[0013]
In the invention according to claim 4, the first operation corresponding to the performance operation is performed. Strange Harmonic waveform Or any one of the preset second modulation waveforms different from the first modulation waveform And a waveform generation step for generating a modulated waveform, an assigning step for assigning a function for instructing formant fixing and releasing the formant fixing to an operator operable simultaneously with the performance operation, and a function assignment in the assigning step. When the operator instructs formant fixation The modulation waveform is 1 modulation waveform? The second Function in the switching instruction step for instructing the waveform generation means to switch from the second modulation waveform to the first modulation waveform when the formant lock release is instructed to the second modulation waveform. When the assigned operator instructs formant fixation, the second modulation waveform whose level is controlled in response to the formant fixation instruction and the first modulation waveform fixed when the formant fixation is instructed A first vocoder processing step for generating a first vocoder sound mixed with a modulated waveform modulated in accordance with a formant component, and an operator assigned a function in the assigning step instructing the release of formant fixation , The first modulation waveform level-controlled in response to the formant fixation release instruction and the first change of the fixed release. Characterized in that to execute a second vocoder processing step of generating a second vocoder sound obtained by mixing a modulated waveform that is modulated in accordance with the formant components of the waveform in the computer
[0014]
Claims above 4 Claims dependent on 5 In the invention described in the above, the waveform generating step is performed according to a formant fixing instruction. Said From the first modulated waveform Said When switching to the second modulation waveform, Said The read address of the first modulation waveform is saved and stored according to the formant fixation release instruction. Said From the second modulated waveform Said When returning to the first modulation waveform, from the saved read address Said The first modulation waveform is reproduced.
[0015]
Claims above 4 Claims dependent on 6 In the invention described in the above, the waveform generating step is performed according to a formant fixing instruction. Said From the first modulated waveform Said While switching to the second modulation waveform, Said Advance the read address of the first modulation waveform and follow the formant lock release instruction Said From the second modulated waveform Said When returning to the first modulation waveform, from the read address that has been advanced Said The first modulation waveform is reproduced.
[0016]
In the present invention, a function for instructing formant fixation and formant fixation release is assigned to an operator that can be operated simultaneously with a performance operation that generates a modulated waveform and a modulated waveform, and when the operator instructs formant fixation, Generates a vocoder sound that modulates the modulated waveform according to the formant component of the modulation waveform fixed at the time when the formant fixation is instructed.On the other hand, when the formant fixation is instructed, the formant component of the modulation waveform is released. As a result, a vocoder sound that modulates the modulated waveform is generated, so it is possible to avoid conventional problems such as the vocoder sound being interrupted by operating the switch that variably sets the formant component of the modulated waveform, and to fix / unfix the formant. As a result, it is possible to generate vocoder sounds that change in various ways according to the instructions. Yoshido and performance is improved.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an electronic musical instrument equipped with a waveform modulation device according to an embodiment of the present invention will be described as an example, and this will be described with reference to the drawings.
[0018]
A. Example configuration
(1) Overall configuration
FIG. 1 is a block diagram showing the overall configuration of an electronic musical instrument according to the present invention. In this figure, reference numeral 1 denotes a keyboard for generating performance information including key-on / key-off events, note numbers, velocities, after-touches, and the like in response to pressing and releasing key operations (performance operations). Reference numeral 2 denotes a foot switch that is turned on and off by the user, and is used as a performance operator for instructing formant fixation / fixation release (described later). Reference numeral 3 denotes a panel switch that includes various switches arranged on the musical instrument panel and generates a switch event corresponding to the operated switch. The panel switch 3 is provided with various operation switches such as a setting mode switch for designating a musical sound generation mode and a numeric keypad for numeric input used together with the setting mode switch.
[0019]
A switch scanner 4 scans the keyboard 1, the foot switch 2 and the panel switch 3 to obtain an on / off state, and sends the detected switch event or performance information generated by the keyboard 1 to the CPU 8. A ROM 5 stores various control programs executed by the CPU 8. The various control programs include various processing programs that constitute a main routine to be described later and a reproduction control process that is executed by interruption. A RAM 6 temporarily stores various register / flag data. The configuration of the main register of the RAM 6 related to the gist of the present invention will be described in detail later. Reference numeral 7 denotes a display unit disposed on the instrument panel, which displays the operation state and parameter setting state of each part of the instrument in accordance with a display control signal supplied from a CPU 8 described later.
[0020]
The CPU 8 executes switch processing, keyboard processing, and operator control processing, which will be described later, in response to an event captured by the switch scanner 4, and instructs the tone generator 10 and the DSP 13 to form musical sounds. The processing operation of the CPU 8 according to the gist of the present invention will be described in detail later. Reference numeral 9 denotes a MIDI interface for inputting / outputting MIDI data (MIDI message) to / from an external device in a serial format under the control of the CPU 8.
Reference numeral 10 denotes a sound source configured by a known waveform memory reading method. As shown in FIG. 2, the sound source 10 includes waveform generators 10a-1 to 10a-n and an adder 10b. The waveform generators 10a-1 to 10a-n are provided corresponding to the sound generation channels, respectively, and read out waveform data from a waveform ROM 11 or a waveform RAM 12 (to be described later) in accordance with a tone generation instruction from the CPU 8, and generate waveforms. Of these, the waveform generator 10a-1 assigned to the modulator part generates a modulated waveform. The outputs of the waveform generators 10a-2 to 10a-n assigned to the carrier parts are added by an adder 10b and output as a modulated waveform.
[0021]
The waveform ROM 11 stores various tone color waveform data and modulation waveform audio waveform data. As shown in FIG. 3, the waveform ROM 11 includes an address data area ADE and a waveform data area WDE. In the address data area ADE, as shown in FIG. 3A, a read start address StartAddress, a read end address EndAddress, and a loop reproduction start address LoopAddress for repeated reading are stored for each waveform number specifying the waveform type. . In the waveform data area WDE, as shown in FIG. 3B, waveform data specified by the read start address StartAddress and the read end address EndAddress of the waveform number stored in the address data area ADE is stored.
Similar to the waveform ROM 11, the waveform RAM 12 includes an address data area ADE and a waveform data area WDE. In the waveform RAM 12, the audio waveform data for the modulation waveform captured by the CPU 8 via the MIDI interface 9 is stored under the control of the sound source 10. In this embodiment, waveform data obtained by sampling a human voice is stored in the waveform RAM 12 as voice waveform data for a modulated waveform.
[0022]
Reference numeral 13 denotes a DSP that performs vocoder processing. In the DSP 13, when a modulation waveform (modulator part output) and a modulated waveform (carrier part output) are input from the sound source 10, vocoder processing is performed to modulate the modulated waveform according to the formant component of the modulation waveform. The keyboard sounds like a human voice (vocoder output OUT), and its configuration will be described later. A D / A converter 14 converts the vocoder output OUT of the DSP 13 into an analog waveform signal and outputs it. Reference numeral 15 denotes a sound system that performs filtering such as removing unnecessary noise from the waveform signal input from the D / A converter 14 and then amplifies it to produce sound from the speaker 16.
[0023]
(2) Configuration of RAM 6
Next, the configuration of main registers provided in the RAM 6 will be described with reference to FIG. In FIG. 4, registers KeyMap [0] to [127] store waveform numbers representing the types of waveforms to be read in correspondence with MIDI note numbers “0” to “127”. That is, a key map table for reading out the corresponding waveform number from the registers KeyMap [0] to [127] in accordance with a note number included in a MIDI input note-on event or a key-on event generated in response to a key press on the keyboard 1. Used as.
The register SplitPoint stores a note number of a key (split point) that divides the keyboard 1 into an upper key range and a lower key range. In this embodiment, a modulation waveform is generated by a key operation in the lower key range below the split point, and a modulated waveform is generated by a key operation in the upper key range including the split point.
[0024]
The register CntNum stores an identification number for identifying an operator assigned for formant fixing / unfixing. Specifically, “0” is set when the foot switch 2 is assigned to a formant fixing / unlocking operator, and “1” is set when the aftertouch of the keyboard 1 is assigned.
The register CntMode stores one of control mode values “0” to “2” that specify the control mode. With the control mode value “0”, only the formant fixing / unfixing of the modulation waveform is performed. With the control mode values “1” and “2”, when the formant is fixed, the modulation waveform is switched to a different modulation waveform from the original modulation waveform, and when the formant fixation is released, the other modulation waveform is returned to the original modulation waveform. The difference between the control mode values “1” and “2” lies in the presence or absence of a playback address step when returning from another modulation waveform to the original modulation waveform when formant fixation is released, which will be described in detail later.
[0025]
The waveform number of the audio waveform data is stored in the register CntWaveNum. The voice waveform data designated by this waveform number generates another modulation waveform to be switched when the formant is fixed under the control mode values “1” and “2”.
The contents of the registers KeyMap [0] to [127], SplitPoint, CntNum, CntMode, and CntWaveNum can be arbitrarily set by the user by setting mode switches and numeric keypad operations. On the other hand, the contents of registers CntState, WaveNum, WaveNumBk, AdrBk, ModDryLevel, and NoteOn, which will be described later, are set by processing of the CPU 8.
[0026]
In the register CntState, flag values “0” to “2” indicating the operating state of the formant fixing / unfixing operation element (foot switch 2 or keyboard 1 aftertouch) designated by the identification number of the register CntNum are stored. Stored. The flag value “0” indicates no state change, the flag value “1” indicates an on operation for transition from the off state to the on state, and the flag value “2” indicates an off operation for transition from the on state to the off state. In the operation description to be described later, a flag value set in the register CntState is denoted as a flag CntState. The register WaveNum stores the waveform number of the currently selected modulation waveform. The register WaveNumBk stores the waveform number of the modulation waveform (original modulation waveform) reproduced when the formant is fixed. The register AdrBk stores the read address of the modulated waveform reproduced when the formant is fixed.
[0027]
The register ModDryLevel stores level values “1” to “3” for controlling the modulation waveform level of the dry route D described later. Level values “1” to “3” are supplied to a signal control unit 32 (described later) of the DSP 13. The signal control unit 32 supplies a multiplication coefficient k corresponding to the signal to the multiplier 31 that controls the modulation waveform level of the dry route D. The level value “1” represents the multiplication coefficient k at the time of releasing the formant fixation. The level value “2” represents the multiplication coefficient k when the formant is fixed. The level value “3” is temporarily changed to the modulation waveform of the dry route D when switching from the original modulation waveform to another modulation waveform when the formant is fixed or when returning from another modulation waveform to the original modulation waveform when the formant is released. Represents a multiplication coefficient k for muting. The counter NoteOn counts the number of note-on in the lower key area including the split point note number stored in the register SplitPoint. The number of notes on the counter NoteOn is decremented every time a key release operation is performed.
[0028]
(3) Configuration of DSP 13
Next, the configuration of the DSP 13 will be described with reference to FIG. The DSP 13 includes an analysis unit 20, a modulator control unit 30, a synthesis unit 40, and an adder 50. The analysis unit 20 includes band pass filters (hereinafter referred to as BPF) 20a-1 to 20a-n and envelope detectors (hereinafter referred to as ENV) 20b-1 to 20b-n. Each of the BPFs 20a-1 to 20a-n has a pass frequency band corresponding to the formant frequency of the human voice, and extracts the formant component of the modulation waveform supplied from the sound source 10. The ENVs 20b-1 to 20b-n are composed of an absolute value circuit including a rectifier and a smoothing circuit including an LPF, and detect and output an envelope level of a formant component extracted by the BPFs 20a-1 to 20a-n.
[0029]
The modulator control unit 30 includes a multiplier 31, a signal control unit 32, and envelope control circuits 33-1 to 33-n. The multiplier 31 multiplies the modulation coefficient (sound) input via the dry route D by the multiplication coefficient k supplied from the signal control unit 32 and outputs the result to the adder 50. That is, the multiplier 31 controls the level of the dry route D modulation waveform input to the adder 50. The signal control unit 32 generates a multiplication coefficient k according to the level values “1” to “3” (value of the register ModDryLevel) supplied from the CPU 8.
The signal control unit 32 outputs a through output instruction signal or a latch instruction signal to the envelope control circuits 33-1 to 33-n according to the flag CntState supplied from the CPU 8. When the through output instruction signal is supplied, the envelope control circuits 33-1 to 33-n output the envelope levels respectively input from the ENVs 20b-1 to 20b-n of the analysis unit 20 to the synthesis unit 40 side. When the latch instruction signal is supplied, the envelope level at that time is latched and output to the synthesis unit 40 side.
[0030]
The combining unit 40 includes BPFs 40a-1 to 40a-n, multipliers 40b-1 to 40b-n, and an adder 40c. The BPFs 40a-1 to 40a-n have the same pass frequency band as the BPFs 20a-1 to 20a-n of the analysis unit 20, and divide and filter the modulated waveform supplied from the sound source 10 into n pass frequency bands. . The multipliers 40b-1 to 40b-n multiply the respective outputs of the BPFs 40a-1 to 40a-n by the respective envelope levels output from the envelope control circuits 33-1 to 33-n. The adder 40c adds and synthesizes the outputs of the multipliers 40b-1 to 40b-n and outputs the result to the adder 50. The adder 50 adds the output of the adder 40c and the modulation waveform of the dry route D output from the multiplier 31 to generate a vocoder output OUT.
[0031]
B. Operation of the embodiment
Next, the operation of the embodiment having the above configuration will be described with reference to FIGS. In the following, the operation of the main routine will be described first, followed by various operations (switch processing, keyboard processing, operator control processing) constituting the main routine, and each operation of the reproduction control processing executed by interruption every predetermined cycle. I will explain in order.
[0032]
(1) Main routine operation
When power is turned on in the embodiment having the above configuration, the CPU 8 reads a predetermined control program from the ROM 5, loads it into itself, and executes the main routine shown in FIG. When the main routine is executed, the CPU 8 first proceeds to step SA1, resets various registers and flags stored in the RAM 6, sets initial values, and initializes the sound source 10 and the DSP 13 to instruct initialization. Process. Then, after the initialization is completed, the process proceeds to step SA2 to execute a switch process for setting a mode according to an operation of a setting mode switch provided in the panel switch 3 or setting a flag CntState corresponding to an ON / OFF operation of the foot switch 2.
[0033]
Subsequently, in step SA3, the modulation waveform corresponding to the pressed key in the lower key range including the split point of the keyboard 1 and the sounding / mute of the modulated waveform corresponding to the pressed key in the upper key range exceeding the split point are generated. Executes the specified keyboard process. In step SA4, an operator control process for changing the modulation waveform generation mode is executed in accordance with the control mode value stored in the flag CntState and the register CntMode. Thereafter, the process proceeds to step SA5, and other processes such as displaying the contents of the mode set in the switch process in step SA2 on the display unit 7 are executed. Thereafter, the above steps SA2 to SA5 are repeatedly executed until the power is turned off.
[0034]
(2) Switch processing operation
Next, the operation of the switch process will be described with reference to FIG. When this processing is executed through step SA2 (see FIG. 6) of the main routine described above, the CPU 8 proceeds to step SB1 in FIG. 7 and whether or not the setting mode switch provided in the panel switch 3 is turned on. Judging. In the following, the description of the operation will be divided into a case where the setting mode switch is turned on and a case where a switch operation other than the setting mode switch is performed.
[0035]
(1) When the setting mode switch is turned on
When the setting mode switch is turned on, the determination result in step SB1 is “YES”, and the process proceeds to step SB2, where it is determined whether or not the numeric input numeric keypad used in combination with the setting mode switch has been pressed. In the following, an operation corresponding to the pressing operation of the numeric keypads “0” to “4” will be described.
[0036]
When the numeric key “0” is pressed, the process proceeds to step SB3, where the waveform numbers for the MIDI note numbers “0” to “127” are set in the registers KeyMap [0] to [127], and this process is completed.
When the numeric key “1” is pressed, the process proceeds to step SB4, and the note number (split point) of the key that divides the keyboard 1 into the upper key area and the lower key area is set in the register SplitPoint, and this process is completed. The split point is included in the upper key range.
When the numeric key “2” is pressed, the process proceeds to step SB5, where the identification number of the operator used for formant fixing / unfixing is set in the register CntNum, and this process is completed. It should be noted that “0” is set when the foot switch 2 is used as the operator for instructing the formant fixing / unlocking, and “1” is set when the aftertouch of the keyboard 1 is used.
When the numeric keypad “3” is pressed, the process proceeds to step SB6, where one of the control mode values “0” to “2” for designating the control mode is set in the register CntMode, and this process is completed. The purpose of the control mode values “0” to “2” will be described in detail in an operator control process (see FIG. 9) described later.
When the numeric key “4” is pressed, the process proceeds to step SB7, and in the control mode values “1” and “2”, the waveform number of the modulation waveform to be switched when the formant is fixed is set in the register CntWaveNum, and this processing is completed. Let
[0037]
(2) When a switch other than the setting mode switch is operated
In this case, the result of determination at step SB1 is “NO”, the process proceeds to step SB8, and whether or not the identification number stored in the register CntNum is “0”, that is, the operator is instructed to fix the formant. It is determined whether or not the switch 2 is set to be used. If the identification number “1” is stored in the register CntNum and the aftertouch of the keyboard 1 is set to be used, the determination result is “NO”, the process proceeds to step SB14, and after executing other switch processing, Complete the process.
[0038]
On the other hand, if it is set to use the foot switch 2, the determination result is “YES”, and the process proceeds to step SB9 to determine whether or not the foot switch 2 is turned on. If an ON operation that transitions from the OFF state to the ON state is detected, the determination result is “YES”, the process proceeds to step SB10, and after setting the flag CntState to “1”, other switches are set in step SB14. This process is completed after the process is executed.
On the other hand, if the on operation is not detected, the determination result in step SB9 is “NO”, and the flow proceeds to step SB11. In step SB11, it is determined whether or not the foot switch 2 is turned off. If an off operation for transition from the on state to the off state is not detected, the determination result is “NO”, the process proceeds to step SB13, the flag CntState is set to “0”, and other switch processing is executed at step SB14. Then, this process is completed.
On the other hand, if an off operation is detected, the determination result in step SB11 is “YES”, the process proceeds to step SB12, and after setting the flag CntState to “2”, other switch processes are executed in step SB14. This process is completed.
[0039]
As described above, when the foot switch 2 is set to be used as an operator for instructing the formant fixing / unlocking, the flag CntState is set to “1” in response to the ON operation of the foot switch 2, and the OFF operation is performed. Accordingly, “2” is set to the flag CntState, and “0” is set to the flag CntState when the on / off operation is not performed.
[0040]
(3) Keyboard processing operation
Next, the keyboard processing operation will be described with reference to FIG. When this process is executed through step SA3 (see FIG. 6) of the main routine described above, the CPU 8 advances the process to step SC1 in FIG. 8 and determines whether or not the keyboard 1 is operated. If no key operation is performed and the performance information from the keyboard 1 is not detected by the switch scanner 4, the determination result is “NO”, and this processing is once completed.
On the other hand, when the performance information corresponding to the key operation is detected, the determination result in step SC1 is “YES”, the process proceeds to step SC2, and the note number included in the performance information of the key operated key is registered. It is determined whether or not it is smaller than the note number (split point) stored in SplitPoint, that is, whether or not the key is pressed and released in the lower key range that generates the modulation waveform.
[0041]
If the key is pressed and released in the upper key range that generates the modulated waveform, the determination result is “NO”, and the process proceeds to step SC3, where the keyboard sound having the pitch corresponding to the key that is pressed and released, that is, the key to be pressed. After executing the carrier part sound generation / mute process for instructing the sound source 10 to generate or mute the modulated waveform, the process is temporarily completed.
On the other hand, if it is a key release operation in the lower key range that generates the modulation waveform, the determination result in step SC2 is “YES”, and the flow proceeds to step SC4. In step SC4, the type of key operation (note-on, note-off and after-touch) is determined from the performance information generated in response to the pressing / releasing key operation. Hereinafter, the description will be divided into an operation at the time of note-on, an operation at the time of note-off, and an operation at the time of after-touch.
[0042]
▲ 1 ▼ Note-on operation
When a key depression operation is performed in the lower key range, the process proceeds to step SC5, and the counter NoteOn that counts the number of note-ons in the lower key range is incremented and incremented. The waveform number of the modulation waveform read from the register KeyMap [note number] is stored in the register WaveNum. Subsequently, in step SC6, it is determined whether or not the waveform number of the modulation waveform stored in the register WaveNum is “−1”. When the waveform number of the modulation waveform is “−1”, it means that the modulation waveform to be read is not designated as the note number. Therefore, in this case, the determination result is “YES”, and this processing is once completed without performing any processing.
[0043]
On the other hand, if the modulation waveform to be read is designated as the note number, the determination result is “NO”, and the process proceeds to step SC7, where the reproduction address and the note number of the pressed key are sent to the sound source 10 and modulated. Instructs the waveform to sound. As a result, the tone generator 10 generates a modulation waveform having a pitch corresponding to the note number of the depressed key as the musical sound of the modulator part. The reproduction address here refers to the read start address StartAddress of the audio waveform data for the modulation waveform specified by the waveform number of the register WaveNum.
[0044]
▲ 2 ▼ Note off operation
When the key release operation is performed in the lower key range, the process proceeds to step SC8, the counter NoteOn is decremented, and in the subsequent step SC9, the value of the decremented counter NoteOn is “0”, that is, all keys are released (all notes off). Determine whether or not. If it is not all notes off, the determination result is “NO”, and this processing is once completed without performing any processing.
On the other hand, when all notes are turned off, the determination result is “YES”, the process proceeds to step SC10, and the value “−1”, which means that the modulation waveform generation is stopped, is stored in the register WaveNum, and the waveform reading is stopped in the sound source 10. The designated reproduction address “−1” is sent. As a result, the sound source 10 mutes the modulated waveform being sounded.
[0045]
(3) Operation when after touch
If it is an after touch in the lower key range, the process proceeds to step SC11, and whether or not the value of the register CntNum is “1”, that is, whether or not it is set to use after touch for formant fixing / unfixing. to decide. If it is not set to use aftertouch, the determination result is “NO”, and this processing is temporarily completed without performing any processing.
On the other hand, if it is set to use aftertouch for formant fixing / unfixing, the determination result is “YES”, and the flow proceeds to step SC12. In step SC12, the type of aftertouch change is determined. If it is the start of aftertouch, the flag CntState is set to “1” in step SC13. If it is the end of aftertouch, the process is completed after the flag CntState is set to “2” in step SC14. .
[0046]
(4) Operation of the operator control process
Next, the operation of the operator control process will be described with reference to FIG. When this process is executed through step SA4 (see FIG. 6) of the main routine described above, the CPU 8 advances the process to step SD1 in FIG. 9, and determines whether or not the value stored in the register WaveNum is “−1”. That is, it is determined whether or not the generation of the modulation waveform is stopped. If the modulation waveform generation is stopped due to all-note off, the determination result is “YES”, and this processing is temporarily completed without performing any processing.
On the other hand, if the modulation waveform generation is not stopped, the determination result is “NO”, the process proceeds to step SD2 and subsequent steps, and the operator control according to the flag CntState is executed. Hereinafter, the description of the operation proceeds separately for each of the cases where the flag CntState is “0”, “1”, and “2”.
[0047]
(1) When the flag CntState is “0”
When the flag CntState is “0”, that is, when the operation state of the formant fixing / unfixing operation element is not changed, the determination results in steps SD2 and SD7 are “NO”, and no processing is performed. This process is completed.
[0048]
(2) When the flag CntState is “1”
When the formant fixing / unfixing operation element transitions from the off state to the on state in response to the user's on operation and the flag CntState is set to “1”, the determination result in step SD2 is “YES”. Proceed to step SD3. In step SD3, the DSP 13 is instructed to fix the formant. Thereby, in the DSP 13, the envelope control circuits 33-1 to 33-n latch the respective envelope levels (formant components of the modulation waveform) detected by the ENVs 20b-1 to 20b-n in accordance with the latch instruction signal from the signal control unit 32. To fix.
Next, in step SD4, it is determined whether or not the control mode value stored in the register CntMode is “0”. Hereinafter, the operation will be described separately when the control mode value stored in the register CntMode is “0” and “1” or “2”.
[0049]
a. When the control mode value is “0”
In this case, the determination result in step SD4 is “YES”, the process proceeds to step SD6, and the level value “2” is stored in the register ModDryLevel. As a result, the DSP 13 generates a vocoder output OUT obtained by adding the modulated waveform of the dry route D level-controlled corresponding to the level value “2” and the modulated waveform vocoder-processed according to the fixed formant component. To do.
[0050]
b. When the control mode value is “1” or “2”
If the control mode value of the register CntMode is “1” or “2”, the determination result in step SD4 is “NO”, the process proceeds to step SD5, and the initial modulation waveform of the dry route D is muted. Switch from one modulation waveform to another.
[0051]
That is, in step SD5, in order to temporarily mute the initial modulation waveform of the dry route D, the level value “3” is stored in the register ModDryLevel. Subsequently, the contents of the register WaveNum (the waveform number of the original modulation waveform reproduced when the formant is fixed) are saved in the register WaveNumBk, while the waveform number is stored in the register CntWaveNum and designates another modulation waveform to be switched when the formant is fixed. Is stored in the register WaveNum. Then, the reproduction address of the original modulation waveform is saved in the register AdrBk, and the read start address StartAddress of the waveform number stored in the register CntWaveNum is set as the reproduction address to instruct the sound source 10 to generate another modulation waveform. .
[0052]
Thereafter, the process proceeds to step SD6, and the level value “2” is stored in the register ModDryLevel. As a result, the DSP 13 generates another modulated waveform of the dry route D, the level of which is controlled according to the level value “2”, and the modulated waveform vocoder-processed according to the formant component fixed in the original modulated waveform. The added vocoder output OUT is generated.
[0053]
(3) When the flag CntState is “2”
When the formant fixing / unfixing operation element transitions from the on state to the off state in response to the user's off operation and the flag CntState is set to “2”, the determination result in step SD7 becomes “YES”. Proceed to step SD8. In step SD8, the DSP 13 is instructed to release formant fixation. As a result, in the DSP 13, the envelope control circuits 33-1 to 33-n synthesize the envelope levels (formant components of the modulation waveform) detected by the ENVs 20b-1 to 20b-n according to the through output instruction signal from the signal control unit 32. As a result of output to the 40 side, a modulated waveform that has been vocoder-processed in accordance with the formant component of the unfixed modulation waveform is generated.
Next, in step SD9, it is determined whether or not the control mode value stored in the register CntMode is “0”. Hereinafter, the operation will be described separately when the control mode value stored in the register CntMode is “0” and “1” or “2”.
[0054]
a. When the control mode value is “0”
If the control mode value is “0”, the determination result in step SD9 is “YES”, the process proceeds to step SD11, and the level value “1” is stored in the register ModDryLevel. As a result, the DSP 13 adds the dry root D modulation waveform whose level is controlled in accordance with the level value “1” and the modulated waveform that has been vocoder-processed according to the formant component of the unfixed modulation waveform. A vocoder output OUT is generated.
[0055]
b. When the control mode value is “1” or “2”
If the control mode value is “1” or “2”, the determination result in step SD9 is “NO”, and the process proceeds to step SD10 to mute another modulation waveform of the dry route D and start from another modulation waveform. Switch to the original modulation waveform.
[0056]
That is, in step SD10, in order to temporarily mute another modulation waveform of the dry route D, the level value “3” is stored in the register ModDryLevel. Subsequently, the waveform number of the original modulation waveform saved in the register WaveNumBk is returned to the register WaveNum. Then, the read address of the original modulation waveform saved and stored in the register AdrBk is reset to the reproduction address, and “−1” is stored in the register AdrBk, and then the sound source 10 is instructed to generate the original modulation waveform.
[0057]
Thereafter, the process proceeds to step SD11, and the level value “1” is stored in the register ModDryLevel. As a result, the DSP 13 adds the initial modulated waveform of the dry route D whose level is controlled in accordance with the level value “1” and the modulated waveform vocoder-processed according to the formant component of the original modulated waveform. A vocoder output OUT is generated.
[0058]
As described above, in the control element control process, in the case of the control mode value “0”, the modulation waveform of the dry route D whose level is controlled according to the level value “2” in accordance with the operation for instructing the formant fixation. And a vocoder output OUT obtained by adding the modulated waveform vocoder-processed in accordance with the fixed formant component.
Then, in response to an operation for instructing the release of formant, vocoder processing is performed according to the modulation waveform of the dry route D whose level is controlled in accordance with the level value “1” and the formant component of the modulation waveform that has been released from the fixation. A vocoder output OUT is generated by adding the modulated waveform.
[0059]
In the case of the control mode value “1” or “2”, the initial modulation waveform is changed to another modulation waveform while the initial modulation waveform of the dry route D is muted in response to an operation for instructing the formant fixation. Vocoder output obtained by adding another modulated waveform of dry route D that is level-controlled in response to the level value “2” and a modulated waveform that has been vocoder-processed according to the formant component fixed in the original modulated waveform OUT is generated.
Then, in response to an operation for instructing the release of formant, the other modulation waveform of dry route D is muted, and the other modulation waveform is returned to the original modulation waveform, and the level is controlled in accordance with the level value “1”. The vocoder output OUT is generated by adding the initial modulation waveform of the dry route D and the modulated waveform vocoder-processed in accordance with the formant component of the original modulation waveform released from the fixed state.
[0060]
(5) Operation of playback control processing
Next, the operation of the reproduction control process will be described with reference to FIG. The CPU 8 interrupts and executes this process at predetermined intervals in the course of executing the main routine (see FIG. 6) described above. When the interrupt execution timing is reached, the process proceeds to step SE1 to determine whether the value stored in the register WaveNum is “−1”, that is, whether the modulation waveform generation is stopped. If the modulation waveform generation is stopped due to all-note off, the determination result is “YES”, and this processing is completed without performing any processing.
On the other hand, if the modulation waveform generation is not stopped, the determination result is “NO”, the process proceeds to step SE2, and it is determined whether it is the update timing of the reproduction address for reading the modulation waveform. If it is not under the reproduction address update timing, the determination result is “NO”, the process proceeds to step SE10, and after executing the sound generation instruction process for instructing the sound source 10 to generate a modulation waveform corresponding to the current reproduction address, this process is temporarily performed. Complete.
[0061]
On the other hand, if it is under the reproduction address update timing, the determination result in step SE2 is “YES”, and the process proceeds to step SE3. In step SE3, it is determined whether or not the reproduction address has reached the read end address EndAddress of the currently reproduced modulation waveform. If the read end address EndAddress has not been reached, the determination result is “NO”, the process proceeds to step SE5, and the playback address is incremented and stepped. On the other hand, when the read end address EndAddress is reached, the determination result is “YES”, the process proceeds to step SE4, and the playback address is set to the loop playback start address LoopAddress.
[0062]
Next, in step SE6, it is determined whether or not the current modulation waveform is switched to another modulation waveform when the formant is fixed under the control mode value “2”. In the control mode value “2”, as described above, control is performed such that when the formant is fixed, the original modulation waveform is switched to another modulation waveform and when the formant is released, the other modulation waveform is returned to the original modulation waveform. While switching from one modulation waveform to another modulation waveform, the reading address of the original modulation waveform is stepped up, and when returning from another modulation waveform to the original modulation waveform, the stepped-out reading is performed. The reproduction address is used as the address, and the original modulation waveform is generated accordingly.
[0063]
Therefore, in step SE6, it is determined whether or not the read address step of the original modulation waveform is necessary while switching from the original modulation waveform to another modulation waveform.
If it is not necessary to step the read address, the determination result is “NO”, and the process proceeds to step SE10. After executing the sound generation instruction process for instructing the sound source 10 to generate a modulation waveform corresponding to the current reproduction address, this process is performed. Is once completed.
[0064]
On the other hand, when it is necessary to step the read address, that is, when the formant is fixed under the control mode value “2”, the determination result is “YES” when the original modulation waveform is switched to another modulation waveform. Proceed to step SE7. In step SE7, it is determined whether or not the read address of the original modulation waveform saved and stored in the register AdrBk when the formant is fixed has reached the read end address EndAddress. If the read end address EndAddress has not been reached, the determination result is “NO”, the process proceeds to step SE9, and the read address of the original modulation waveform saved in the register AdrBk is incremented and advanced.
[0065]
On the other hand, if the read address of the original modulation waveform saved in the register AdrBk has reached the read end address EndAddress, the determination result in step SE7 is “YES”, and the process proceeds to step SE8. The address is set to the loop playback start address LoopAddress. When the reading address is incremented in this way, the process proceeds to step SE10, and after executing the sound generation instruction process for instructing the sound source 10 to generate the modulation waveform corresponding to the current reproduction address, this process is once completed.
[0066]
(6) Specific operation example
Next, a specific operation example of the present embodiment will be described with reference to FIG. In FIG. 11, (A) represents the on / off change of the formant fixing / unfixing operation element. (B) represents a modulation waveform generated when a predetermined key in the lower key range is pressed under the control mode value “0”. (C) represents a combined output (output of the adder 40c illustrated in FIG. 5) of the combining unit 40 generated in response to the modulation waveform of (B) in the control mode value “0”. (D) represents a modulation waveform generated when a predetermined key in the lower key range is pressed under the control mode value “1”. (E) represents a modulation waveform generated when a predetermined key in the lower key range is pressed under the control mode value “2”.
[0067]
(1) When the control mode value is “0”
Under the control mode value “0”, a predetermined key in the lower key range is pressed to generate the modulation waveform shown in FIG. Suppose that the operator is turned on and off. Then, the formant component of the modulation waveform in (B) is fixed when the operating element transitions from the off state to the on state, and is released when the operating element transitions from the on state to the off state. A composite output (modulated waveform) shown in the figure is generated, and a vocoder output OUT is generated by adding this and the modulation waveform of (B) whose level is controlled via the dry route D. As a result, while the formant is fixed, a chorus sound is generated in which the modulation waveform “Kakikukeko” and the modulated waveform “Oooo” are mixed.
[0068]
(2) When the control mode value is “1”
Under the control mode value “1”, pressing a predetermined key in the lower key range to generate the modulation waveform shown in FIG. Suppose that the on-off controller is turned on and off. Then, as in the case of the control mode value “0” in (1) above, a modulated waveform “Oooo” shown in FIG. 5C is generated during the formant fixed period.
On the other hand, during the formant fixed period, the initial modulation waveform shown in (B) is switched to another preset modulation waveform “Hahifuhoho”, and the original modulation waveform “Kaki…” is released when the fixation is released. Therefore, the modulation waveform shown in (D) is generated.
[0069]
Therefore, during the formant fixed period, the modulated waveform “Oooo” illustrated in (C) and the modulated waveform “D” (level) controlled via the dry route D are added. After the vocoder output OUT is generated, and after being released from the fixed state, the modulated waveform modulated by the modulation waveform “Dr ....” of (D) and the modulation waveform “Dr. Is added to the vocoder output OUT. As a result, after the formant is fixed and after being released, a chorus sound is produced by mixing the modulated waveform “hahifuhekiki…” and the modulated waveform “oooo kaki…”.
[0070]
(3) In case of control mode value “2”
Under the control mode value “2”, the formant is fixed at the timing shown in (A) while the predetermined waveform in the lower key range is pressed to generate the modulation waveform (voice) shown in (B). / Assume that the operator for unlocking is turned on / off. Then, as in the case of the control mode value “0” in (1) above, a modulated waveform “Oooo” shown in FIG. 5C is generated during the formant fixed period.
On the other hand, during the formant fixed period, the original modulation waveform shown in (B) is switched to another preset modulation waveform “Hahifheho”, and at the time of releasing the lock, the address is incremented from the switching point. Since the original modulation waveform "Sashi ..." is restored, the modulation waveform shown in (E) is generated.
[0071]
Therefore, during the formant fixed period, the modulated waveform “Oooo” shown in (C) and the modulated waveform “E), whose level is controlled via dry route D, are added. After the vocoder output OUT is generated, and after being released from the fixed state, the modulated waveform modulated by the modulation waveform “sashi” shown in FIG. 5E and the modulated waveform of level E controlled via the dry route D (E) A vocoder output OUT is generated by adding “sashi…”. As a result, after the formant is fixed and after being released, a chorus sound in which a modulation waveform “Hahifahashi ...” and a modulated waveform “Ooooashi ...” are mixed.
[0072]
As described above, in this embodiment, a formant fixing / unlocking instruction is assigned to an operator (a foot switch 2 or an after touch of the keyboard 1) that can be operated without releasing the hand from the keyboard 1, and the control mode Under the value “0”, in response to the formant fixing instruction, the vocoder output OUT is generated by adding the modulated waveform of the dry route D whose level is controlled and the modulated waveform vocoder-processed according to the fixed formant component, On the other hand, the vocoder output OUT is generated by adding the level-controlled dry route D modulation waveform and the modulated waveform vocoder-processed according to the formant component of the modulation waveform released from the fixation in response to the formant fixation release instruction. Therefore, the vocoder sound that is sounding is interrupted by operating the switch that variably sets the formant component of the modulation waveform. Rutoitta or avoiding the traditional negative effects, in the manner of indication of formant fixed / unlocking can generate vocoder sound that varies all sorts, as a result, improves the flexibility and performance of the vocoder performance.
[0073]
Further, in this embodiment, when the control mode value is “1” or “2”, when the formant fixing instruction is given, the initial modulation waveform of the dry route D is muted and the original modulation waveform is switched to another modulation waveform. When a vocoder output OUT is generated by adding another modulated waveform of the dry route D whose level is controlled and a modulated waveform vocoder-processed according to the formant component fixed in the original modulated waveform, and when the formant fixation release instruction is given, While muting another modulation waveform of dry route D, the original modulation waveform is returned from another modulation waveform to the original modulation waveform, and the formant component of the original modulation waveform of dry route D that has been level-controlled and the original modulation waveform that has been unfixed The vocoder output OUT is generated by adding the vocoder-processed modulated waveform according to the Allowing formation, which therefore becomes possible to improve the playability of the vocoder performance.
[0074]
In addition, in this embodiment, when the control mode value is “1”, when switching from the original modulation waveform to another modulation waveform in accordance with the formant fixation instruction, the read address of the original modulation waveform is saved and stored, and the formant is fixed. When returning from another modulation waveform to the original modulation waveform according to the release instruction, the original modulation waveform is reproduced from the saved read address. On the other hand, when the control mode value is “2”, the original modulation waveform is reproduced according to the formant fixation instruction. While switching from one modulation waveform to another modulation waveform, the read address of the original modulation waveform is stepped, and when returning from another modulation waveform to the original modulation waveform according to the formant lock release instruction, the read address that has been stepped Since the original modulated waveform is played back, it is possible to generate a wide variety of vocoder sounds, and hence the vocoder performance. It is possible to improve the playability made.
[0075]
In the above-described embodiment, either the foot switch 2 or the after touch of the keyboard 1 can be assigned as an operator for instructing to fix / unlock formants. However, the present invention is not limited to this, and the hand is released from the keyboard 1. For example, the key operation in a certain key range can be regarded as an operation for instructing formant fixing / unlocking, or the formant fixing / unlocking can be instructed by increasing or decreasing the number of simultaneous sounds. .
Furthermore, in the present embodiment, the modulation waveform level of the dry route D is controlled corresponding to the flag CntState and the control mode value, but instead of this, the user may arbitrarily set the configuration. Further, instead of level control, the timbre of the modulation waveform of the dry route D may be changed according to formant fixation / fixation release.
[0076]
【The invention's effect】
According to invention of Claim 1, 4, , Strange Assigning a function that instructs formant fixation and formant fixation release to an operator that can be operated simultaneously with a performance operation that generates a harmonic waveform and a modulated waveform. The modulation waveform is The first modulation waveform is switched to a preset second modulation waveform different from the first modulation waveform, and the second modulation waveform level-controlled in response to the formant fixation instruction and the formant fixation instruction When the first vocoder sound mixed with the modulated waveform modulated according to the formant component of the first modulation waveform fixed at the time is generated, and when the formant fixation release is instructed, the second vocoder sound is generated. The modulation waveform is returned to the first modulation waveform, and is modulated according to the first modulation waveform level-controlled in response to the formant fixation release instruction and the formant component of the first modulation waveform released from the fixation state. Since the second vocoder sound mixed with the modulated waveform is generated, a wide variety of vocoder sounds can be generated to improve the performance of the vocoder performance.
According to the second and fifth aspects of the invention, when the first modulation waveform is switched to the second modulation waveform in accordance with the formant fixing instruction, the read address of the first modulation waveform is saved and stored. When the first modulation waveform is restored from the second modulation waveform to the first modulation waveform in accordance with the formant fixation release instruction, the first modulation waveform is reproduced from the saved read address, so that various vocoder sounds can be generated. The performance of vocoder performance can be improved.
According to the third and sixth aspects of the present invention, the waveform generating means is capable of generating the first modulation waveform while switching from the first modulation waveform to the second modulation waveform in accordance with a formant fixing instruction. Since the read address is stepped and the first modulation waveform is reproduced from the stepped read address when returning from the second modulation waveform to the first modulation waveform according to the formant fixation release instruction, A wide variety of vocoder sounds can be generated to improve the performance of vocoder performance.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an overall configuration of an embodiment according to the present invention.
FIG. 2 is a block diagram showing a configuration of a sound source 10;
FIG. 3 is a memory map showing a memory configuration of a waveform ROM 11 and a waveform RAM 12;
FIG. 4 is a memory map showing a main register configuration of a RAM 6;
FIG. 5 is a block diagram showing a configuration of a DSP 13;
FIG. 6 is a flowchart showing an operation of a main routine.
FIG. 7 is a flowchart showing an operation of switch processing.
FIG. 8 is a flowchart showing an operation of keyboard processing.
FIG. 9 is a flowchart showing an operation of an operator control process.
FIG. 10 is a flowchart showing an operation of a reproduction control process.
FIG. 11 is a diagram for explaining a specific operation example;
[Explanation of symbols]
1 keyboard
2 Foot switch
3 Panel switch
4 Switch scanner
5 ROM
6 RAM
7 Display section
8 CPU
9 MIDI interface
10 sound sources
11 Waveform ROM
12 Waveform RAM
13 DSP
14 D / A converter
15 Sound system
16 Speaker

Claims (6)

Waveform generating means for generating one of a first modulation waveform corresponding to a performance operation or a second modulation waveform set in advance different from the first modulation waveform and a modulated waveform ; ,
Assigning means for assigning a function for instructing formant fixation and formant fixation release to an operator operable simultaneously with the performance operation;
Wherein said modulation waveform to a first modulation waveform or we second modulation waveform in the case of function-allocated operating element has instructed formant fixed by allocating means, when instructed formant unlocking the second Switching instruction means for instructing the waveform generating means to switch from a modulation waveform to the first modulation waveform;
When the operator assigned the function by the assigning unit instructs formant fixation, the second modulation waveform level-controlled in response to the formant fixation instruction and the first fixed waveform when the formant fixation instruction is given. First vocoder processing means for generating a first vocoder sound obtained by mixing a modulated waveform modulated according to a formant component of one modulation waveform;
When the operator assigned with the function by the assigning unit instructs release of formant fixation, the first modulation waveform level-controlled in response to the formant fixation release instruction and the first modulation waveform released from fixation A waveform modulation apparatus comprising: second vocoder processing means for generating a second vocoder sound in which a modulated waveform modulated according to a formant component is mixed.   The waveform generating means saves and stores the read address of the first modulation waveform when switching from the first modulation waveform to the second modulation waveform according to the formant fixation instruction, and according to the formant fixation release instruction. 2. The waveform modulation device according to claim 1, wherein the first modulation waveform is reproduced from the read-out read address when returning from the second modulation waveform to the first modulation waveform.   The waveform generation means advances the read address of the first modulation waveform while switching from the first modulation waveform to the second modulation waveform in accordance with the formant fixing instruction, and instructs to release the formant fixing. 2. The waveform modulation device according to claim 1, wherein the first modulation waveform is reproduced from the stepped read address when the second modulation waveform is returned to the first modulation waveform. Waveform generation step of generating the one of the modulation waveform and the modulation waveform of the second modulation waveform and the first modulation waveform corresponding to the performance operation or the first modulation waveform that is another preset When,
An assigning step of assigning a function for instructing formant fixation and formant fixation release to an operator operable simultaneously with the performance operation;
It said assigning the modulated waveform to the first modulation waveform or we second modulation waveform in the case of function-allocated operating element has instructed formant fixed step, when instructed formant unlocking the second A switching instruction step for instructing the waveform generating means to switch from the modulated waveform to the first modulated waveform,
When the operator assigned with the function in the assigning step instructs formant fixation, the second modulation waveform level-controlled in response to the formant fixation instruction and the time when the formant fixation is instructed are fixed. A first vocoder processing step for generating a first vocoder sound mixed with a modulated waveform modulated according to a formant component of the first modulation waveform;
When the operator assigned the function in the assigning step instructs release of formant fixation, the first modulation waveform whose level is controlled in response to the formant fixation release instruction and the first modulation waveform released from fixation A waveform modulation program causing a computer to execute a second vocoder processing step for generating a second vocoder sound obtained by mixing a modulated waveform modulated in accordance with a formant component of the second vocoder.   In the waveform generation step, when the first modulation waveform is switched to the second modulation waveform according to the formant fixation instruction, the read address of the first modulation waveform is saved and stored according to the formant fixation release instruction. 5. The waveform modulation program according to claim 4, wherein the first modulation waveform is reproduced from the saved read address when returning from the second modulation waveform to the first modulation waveform. 6.   In the waveform generation step, while the first modulation waveform is switched to the second modulation waveform in accordance with the formant fixation instruction, the read address of the first modulation waveform is stepped up, and the formant fixation release instruction 5. The waveform modulation program according to claim 4, wherein the first modulation waveform is reproduced from the stepped read address when the second modulation waveform is returned from the second modulation waveform to the first modulation waveform.

Images