JP2942959B2 - Modulation effect control device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a modulation effect control device suitable for use in electronic musical instruments that generate musical tones such as keyboard instruments, string instruments, and wind instruments.

[Background Art] Vibrato, which is a type of modulation effect, is added by modulating the frequency of a musical tone signal with a vibrato signal generated by an LFO (low frequency oscillator). in this case,
The degree of the vibrato depends on the vibrato depth (the amplitude of the vibrato signal) and the vibrato speed (the frequency of the vibrato signal). The conventional addition of vibrato is performed by controlling the amplitude of the vibrato signal based on vibrato depth information supplied from performance operators such as a modulation wheel and a keyboard.

"Problems to be Solved by the Invention" The degree of vibrato is determined by the vibrato depth and the vibrato speed as described above, and these have a correlation as shown in FIG. It is known. To give some examples,
The most effective vibrato is obtained when the vibrato speed is 5 Hz and its depth is 19 cents, and when the vibrato speed is 6.5 Hz and its depth is 40 cents. As described above, if the depth of the vibrato is increased as the speed of the vibrato is increased, a more effective vibrato can be obtained. Conversely, the more effective the vibrato is, the deeper the vibrato is, the faster the speed is.
However, in the conventional vibrato control device, information on the vibrato depth and the vibrato speed is input by individual controls and is individually controlled, so that the above controls are simultaneously operated during a performance. do it,
It is difficult to correlate vibrato depth with vibrato speed. In another vibrato control device, the vibrato speed is preset according to the type of musical instrument to be played, so even if the vibrato depth can be increased or decreased by a performance operator, the vibrato speed remains constant. is there. Therefore, if you make the vibrato shallow,
If the speed is felt to be too fast and the vibrato is deep, the problem is that effective vibrato cannot be obtained as if the speed is felt to be too slow, resulting in an unnatural musical tone.

The present invention has been made in view of the above-described problems, and has as its object to provide a modulation effect control device capable of adding a natural and effective modulation effect to a musical tone.

"Means for Solving the Problems" In order to solve such a problem, in the invention according to claim 1, when the depth of the modulation effect is changed by the operation means, the change in the depth of the modulation effect is suppressed. A modulation effect speed control means for non-linearly changing the speed of the modulation effect, and a modulation device for adding a modulation effect to a musical tone supplied from the outside based on the depth of the modulation effect and the speed of the modulation effect. And an effect adding means.

Next, in the invention according to claim 2, when the speed of the modulation effect is changed by the operation means instead of the modulation effect speed control means, the modulation effect is changed with respect to the change in the speed of the modulation effect. And a modulation effect depth control means for nonlinearly changing the depth.

Next, the invention according to claim 3 is characterized in that it comprises both the modulation effect speed control means and the modulation effect depth control means.

[Operation] When the depth of the modulation effect is changed by the operation means, the modulation effect speed control means changes the speed of the modulation effect nonlinearly with respect to the change in the depth of the modulation effect. Alternatively, when the speed of the modulation effect is changed by the operation means, the modulation effect depth control means changes the depth of the modulation effect non-linearly with respect to the change in the speed of the modulation effect. The modulation effect adding means adds a modulation effect to the supplied tone signal based on the depth of the modulation effect and the speed of the modulation effect.

"Example" Next, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of a first embodiment when the present invention is applied to a vibrato control device. In this figure, reference numeral 1 denotes a performance information generating unit, which comprises performance operators such as a modulation wheel and a keyboard. The performance information generator 1 outputs performance operator information PI such as after touch to the adder 2 and the key code KC to the key code converter 8. Reference numeral 3 denotes a tone color designation information generating unit which generates a vibrato depth DP ₁ , a vibrato speed RA ₁ and a sensitivity RS. For this example, the vibrato depth above
DP ₁ is information that determines the depth of the vibrato, increased or decreased by the operation of the performance operator. Vibrato speed RA ₁
This is information that determines the speed of vibrato, and takes a certain value. Also, the sensitivity RS, when the depth of the vibrato is increased,
This parameter determines how fast the vibrato is made. The tone color designation information generator 3 outputs the vibrato depth DP ₁ to the adder 2, the sensitivity RS to the multiplier 4, and the vibrato speed RA ₁ to the adder 5.

The adder 2 includes a performance operator information PI and a vibrato depth DP ₁
And outputs the result to the multiplier 4 and the multiplier 7 as the vibrato depth DP ₂ . The multiplier 4 has a vibrato depth DP
₂ multiplies the sensitivity RS to change the speed (frequency change) signal RTM
Is output to the adder 5. Therefore, the speed change signal RTM is adapted to increase or decrease depending on the vibrato depth DP _2. The adder 5 adds the speed change signal RTM vibrato rate RA _1, as vibrato speed RA _2, and outputs it to LFO6. Thus, the vibrato rate RA ₂ is adapted to increase or decrease depending on the speed change signal RTM. LFO
6 oscillates an oscillation signal S having a frequency corresponding to the vibrato speed RA ₂ and outputs it to the multiplier 7. The multiplier 7 outputs the oscillation signal S
Is multiplied by the vibrato depth DP ₂ to obtain a vibrato signal VIB, which is output to the adder 9.

Next, the key code conversion unit 8 described above converts the key code KC
Is converted into frequency data FN representing the frequency corresponding to the key code KC, and is output to the adder 9. The adder 9 adds the frequency data FN and the vibrato signal VIB and outputs the result to the musical tone generator 10. The tone generator 10 generates and outputs a tone signal VS having a frequency corresponding to the frequency data FN 'to which vibrato is added.

Next, the operation of this embodiment having the above configuration will be described. First, when a performance is started, the key code KC output from the performance information generating section 1 is converted into frequency data FN, and the frequency data FN is converted into a musical tone by the musical tone generating section 10 and output. In addition to the performance described above, the initially set vibrato depth RA ₁ and vibrato speed D
Vibrato corresponding to P ₁ is added to the musical tone.

Then, by operating the performance operator, varying the depth of the vibrato, vibrato depth DP ₁ is changed in response to this change, vibrato depth DP ₂ is changed. Then, the multiplier 7, the amplitude of the oscillation signal S is controlled by the vibrato depth DP _2. On the other hand, the multiplier 4, the sensitivity RS to the vibrato depth DP ₂ are multiplied, is output as speed change signal RTM that changes according to the vibrato depth DP _2. Next, in the adder 5, the speed change signal RTM
Vibrato rate RA ₁ is controlled in accordance with the frequency of the oscillation signal S is controlled. The above-described control of the amplitude and frequency of the oscillation signal S is performed based on the solid line shown in FIG. 4 so as to gradually increase the vibrato speed as the vibrato depth increases.

Next, FIG. 2 is a block diagram showing a configuration of a second embodiment of the present invention. In this figure, the parts corresponding to the respective parts of the embodiment shown in FIG. A multiplier 11 multiplies the vibrato speed RA ₁ by the sensitivity DS and outputs the result to the multiplier 12 as a depth change signal DTM. In this case, the vibrato speed RA
Reference numeral ₁ denotes information for determining the speed of vibrato, which is increased or decreased by operating a performance operator. The sensitivity DS is a parameter that determines how fast the vibrato is made when the vibrato speed is increased. Next, the multiplier 12
It multiplies the above-described depth change signal DTM by the oscillation signal S and outputs the result to the multiplier 13 as an oscillation signal S '. The multiplier 13 multiplies the oscillation signal S ′ by the vibrato depth DP ₂ and outputs the result to the adder 9 as a vibrato signal VIB. In this example, the vibrato depth DP ₁ and the vibrato depth DP ₂ takes a constant value.

In the above configuration, first, when the performance starts, the first
As in the embodiment shown in the figure, the key code KC output from the performance information generator 1 is converted into frequency data FN, and the frequency data FN is converted into a musical tone by the musical tone generator 10 and output. Further, the performance described above, initially set vibrato depth RA ₁ and vibrato vibrato according to the speed DP ₁ is added to the musical tone.

Then, by operating the performance operator, changing the speed of the vibrato, vibrato depth RA ₁ is changed in response to this change, a change in frequency of the oscillation signal S. Then, in the multiplier 13, the amplitude of the oscillation signal S is equal to the vibrato depth.
Controlled by DP ₂ . On the other hand, in the multiplier 11, is multiplied by the sensitivity DS vibrato rate RA _1, is outputted as the depth change signal DTM that changes according to the vibrato speed RA _1. Next, in the adder 12, the oscillation signal S is controlled according to the speed change signal RTM, and the amplitude of the oscillation signal S is controlled. The amplitude and frequency of the oscillation signal S are determined based on the solid line shown in FIG. 4 so as to gradually increase the speed as the depth of the vibrato increases.

Next, FIG. 3 is a block diagram showing a configuration of a third embodiment of the present invention. Also in this figure, parts corresponding to the respective parts of the first embodiment shown in FIG. 1 are denoted by the same reference numerals, and description thereof is omitted. 14 is a multiplier,
The vibrato depth DP ₂ is multiplied by the vibrato speed RA ₁ and output to the multiplier 7 as a depth change signal DTM ′. Incidentally, the vibrato rate RA ₁ is passed through a multiplier 15 for sensitivity adjustment to correspond to the sensitivity DS described above, after being suitably adjusted, it may be supplied to the multiplier 14. In this example, the vibrato depth DP ₁ and the vibrato speed RA ₁ can be changed only by one of the performance operators at one time. For example, the vibrato depth DP ₁ is the operation information. , The vibrato speed RA ₁ is constant, and when the vibrato speed RA ₁ is operation information, the vibrato depth DP ₁ is constant.

In the above configuration, first, when the performance starts, the first
As in the embodiment shown in FIG. 2 and FIG. 2, the key code KC output from the performance information generating section 1 is converted into frequency data FN, and this frequency data FN is converted into a musical tone by the musical tone generating section 10 and output. . Also, along with the performance described above,
Vibrato corresponding to the initially set vibrato depth RA ₁ and vibrato speed DP ₁ is added to the musical sound.

Then, a constant vibrato rate RA _1, varying the vibrato depth DP ₁ by performance operator, frequency and amplitude of vibrato signal VIB are controlled similarly to the embodiment shown in FIG. 1 described above .

Further, the constant vibrato depth DP _1, varying the vibrato speed RA ₁ by performance operator, first, in the multiplier 4 multiplies the sensitivity RS vibrato depth DP _2, speed change signal RTM Output as Then, by controlling the vibrato rate RA ₁ by the speed change signal RTM, controls the frequency of the oscillation signal S.

On the other hand, the multiplier 14 multiplies the vibrato depth DP ₂ by the vibrato speed RA _{1 and} outputs the result as a depth change signal DTM ′. The amplitude of the oscillation signal S is controlled by the depth change signal DTM '.

In this case, in both cases described above, the control of the amplitude and frequency of the vibrato signal VIB is performed based on the solid line shown in FIG.

Incidentally, in the embodiment shown in FIG. 2 described above, as shown by the broken line, adds the calculation information PI and vibrato speed RA _1, and supplied to a multiplier 11, whereby the amplitude of the oscillation signal S (vibrato May be controlled.

Moreover, preliminarily a table the relationship between the vibrato depth DP ₁ and vibrato rate RA ₁ shown in FIG. 4, for example, in the case of changing the depth of the vibrato performance operator is timbre designation information generated part 3 in accordance with vibrato depth DP ₁ for outputting, may be read vibrato rate RA _1.

The present invention can be used not only for vibrato control but also for various modulation effects.

[Effects of the Invention] As described above, the present invention provides a modulation effect speed control means for non-linearly changing the modulation effect speed with respect to a change in the modulation effect depth when the modulation effect depth changes. Or by providing a modulation effect depth control means for non-linearly changing the depth of the modulation effect with respect to the change in the speed of the modulation effect when the speed of the modulation effect changes, thereby providing a natural and effective method. This provides the advantage that a great modulation effect can be added to the musical sound.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the configuration of a first embodiment of the present invention, FIG. 2 is a block diagram showing the configuration of a second embodiment of the present invention, and FIG. 3 is a third embodiment of the present invention. FIG. 4 is a relationship diagram showing the relationship between the depth of the vibrato and its speed. 2,5 ... adder (modulation effect speed control means), 4 ... multiplier (modulation effect speed control means), 7,11,12,13,14 ... multiplier (modulation effect depth control means) ), 6: LFO (modulation effect speed control means, modulation effect depth control means), 9: adder (modulation effect adding means).

Claims (3)

(57) [Claims] 1. A modulation signal generating means for generating a modulation signal for modulating a tone signal, and a modulation speed for controlling the speed of the modulation signal generated by the modulation signal generation means by outputting speed information. Control means, and the depth of the modulation signal generated by the modulation signal generation means,
A modulation depth control unit that outputs and controls depth information in accordance with an operation of an operation unit, and the modulated signal by controlling the output speed information based on the output depth information. A modulation control means for non-linearly changing the depth of the modulation signal with respect to the change in the speed. 2. A modulation signal generating means for generating a modulation signal for modulating a tone signal, and the speed information of the modulation signal generated by the modulation signal generating means is set to speed information corresponding to the operation of the operation means. A modulation speed control means for outputting and controlling a depth of the modulation signal generated by the modulation signal generation means,
Modulation depth control means for outputting and controlling depth information, and controlling the depth of the modulation signal in consideration of the output speed information, thereby controlling a change in the speed of the modulation signal. A modulation control means for non-linearly changing the depth of the modulation signal. 3. Modulation signal generating means for generating a modulation signal for modulating a tone signal, modulation speed control means for controlling the speed of the modulation signal generated by the modulation signal generation means, and the modulation signal Modulation depth control means for controlling the depth of the modulation signal generated by the generation means; speed of the modulation signal controlled by the modulation speed control means; and control by the modulation depth control means Change control means for changing a depth of the modulation signal in response to an operation of an operation means, wherein the change control means changes a speed of the modulation signal and a depth of the modulation signal. The modulation effect control device according to claim 1, wherein the aspect is set in accordance with information generated from the tone color designation information generating section.