JPH05241580A - Formant sound generating instrument - Google Patents

Abstract

PURPOSE:To form the formant sound of the constant acoustic feeling volume regardless of a band width value by correcting the power spectrum of the formant sound corresponding to a formant band width by a corrective means. CONSTITUTION:A generated logarithmic sine wave is added to a logarithmic sine square wave (window function) read corresponding to a formant band width value K and becomes a formant sound signal. Then correction value data FCL corresponding to the band width K is added to the formant sound signal in an adder 13. Thus, the power spectrum of the formant sound is improved so as to be the constant acoustic feeling volume regardless of the band width K. Then the envelope shape of the formant sound signal whose acoustic feeling volume is corrected is prescribed based on an envelope signal log ENV. Then, after the formant sound is converted into an antilogarithm by a log/linea conversion table 17, is outputted as a music sound signal through a D/A converter 18.

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a formant sound generator suitable for use in, for example, generating wind instrument sounds and human voice sounds.

[0002]

2. Description of the Related Art FIG. 4 is a diagram showing a power spectrum of a general formant sound. Fc shown in this figure is a formant center frequency, and Bw is a formant band width. This formant sound waveform is formed by periodically generating a phoneme obtained by multiplying the periodic waveform shown in FIG. 5B by the window function of the waveform shown in FIG.

That is, in the conventional formant sound generator, for example, a sin wave whose frequency matches the formant center frequency fc and a window function (sin ² wave) having a time width Tw.
Is generated and the multiplication wave obtained by multiplying
It is configured to output at ₀ to form a formant sound having a desired pitch. Here, the period 1 / f ₀ is the period of the basic pitch frequency f ₀ , and the frequency f ₀ corresponds to the pitch of the formant tone. A device of this type is disclosed in JP-A-2-254497.

In such a formant sound generator, for example, the formant center frequency fc is 6000H.
z (constant amplitude level), basic pitch frequency f ₀ is 400
When the frequency is THz and the time width Tw of the window function (sin ² wave) is changed, the formant sound waveforms shown in FIGS. 6A to 10A are formed. In these figures, the respective time widths Tw are 2.5 msec (FIG. 6), 1.2 msec.
5 msec (FIG. 7), 0.83 msec (FIG. 8), 0.
42 msec (FIG. 9) and 0.31 msec (FIG. 10). In addition, each figure (b) shows a power spectrum obtained by sampling one cycle of the formed formant sound and performing Fourier transform of the sampled sound.

[0005]

In the conventional formant sound generator described above, a wide formant band width Bw is obtained by narrowing the time width Tw of the window function. This is shown in FIG. 6 (b) to FIG. 10 (b).
As can be seen from the power spectra shown in each of the above, as the time width Tw of the window function becomes narrower, the formant band width Bw thereof gradually becomes wider. Here, the time width Tw of the window function is determined by the formant band width value K that defines the tone color of the formant tone.

On the other hand, when the rms value (effective value) of one cycle of the formant sound waveform shown in FIG. 6 is used as a reference (0 dB) and the rms value of the formant sound waveform in each time width Tw is plotted, as shown in FIG. , The rms value decreases in proportion to the logarithmic frequency logf of the window function. The rms value for one cycle of the formant sound waveform corresponds to the sound volume on the sense of hearing. As described above, when the band width Bw is widened (when the time width Tw is narrowed), there is a problem that the audible volume of the formant sound is reduced. The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a formant sound generation device capable of forming a formant sound having a constant audible volume regardless of the bandwidth.

[0007]

According to the present invention, a multiplication wave formed by multiplying a periodic function having a frequency corresponding to a formant center frequency and a window function having a period corresponding to a formant bandwidth is based on a fundamental pitch period. In the formant sound generating apparatus that repeatedly generates by the above, it is characterized by comprising a correcting means for correcting the power spectrum of the multiplied wave corresponding to the formant bandwidth.

[0008]

According to the above structure, the correcting means corrects the power spectrum of the multiplication wave in accordance with the formant bandwidth. As a result, a formant sound having a constant audible volume is formed regardless of the bandwidth value.

[0009]

Embodiments of the present invention will be described below with reference to the drawings. A. Configuration of Embodiment FIG. 1 is a block diagram showing the configuration of an electronic musical instrument using a formant sound generator according to an embodiment of the present invention. In this figure, reference numeral 1 is a key information generating circuit composed of a keyboard, a key pressing detection circuit and the like. The key information generating circuit 1 generates a key-on signal Kon indicating that a key has been pressed and a key code KC corresponding to the pressed key. Reference numeral 2 denotes a tone color designating section which has a plurality of operators and generates tone color designation data RD corresponding to each operator. A tone color parameter supply unit 3 generates tone color parameters corresponding to the tone color designation data RD. This timbre parameter determines the waveform shape of the formant sound to be formed. Among these parameters, fc is data representing the formant center frequency, K is the formant bandwidth value, and EB is data designating the envelope waveform of the formant sound.

Reference numeral 4 is an envelope generator. When the key-on signal Kon is supplied, the envelope generator 4 receives an envelope signal (logarithmic value) l according to the data EB.
Generate ogENV. Reference numeral 5 is a phase accumulator, which is a key code K supplied from the key information generating circuit 1.
C is taken in as the basic pitch frequency data f ₀ , which is sequentially accumulated and output. The phase accumulator 5 is reset when it overflows, and is configured to perform accumulation operation again from 0. Therefore, the cycle of this accumulation operation is the time corresponding to the basic pitch frequency data f ₀ . Further, the accumulator 5 supplies an overflow pulse to the differentiating circuit 6 when the overflow has occurred.

The differentiating circuit 6 generates a reset signal RS having a predetermined pulse width in synchronization with the rising edge of the overflow pulse. That is, the differentiating circuit 6 detects the timing when the output value of the phase accumulator 5 becomes 0 and outputs the reset signal RS. A phase accumulator 7 sequentially accumulates the values of the formant center frequency fc. This phase accumulator 7
Is configured to accumulate numerical data proportional to the formant center frequency fc, and when the accumulated value overflows, the accumulation is repeated again from the initial value. Further, the accumulator 7 forcibly resets the accumulated value when the reset signal RS is supplied.

Reference numeral 8 is a logarithmic sin table composed of a ROM or the like, and the logarithmic sin wave data is stored for one cycle. The logarithmic sin table 8 uses the output of the phase accumulator 7 as a read address, and outputs the logarithmic sin data corresponding to the address. A phase accumulator 9 accumulates a formant band width value K, which is a tone color parameter, in synchronization with a predetermined clock. The phase accumulator 9 holds the final value when the accumulated value overflows, and when the reset signal RS is supplied, the phase accumulator 9 is reset and restarts the accumulation from the initial value.

The accumulated value of the phase accumulator 9 is
This is the read address of the logarithmic sin square table 10. The logarithmic sin squared table 10 is composed of a ROM or the like and stores logarithmic sin squared data for one cycle. 11 is the output of the logarithmic sin table 8 and the logarithmic sin
It is an adder that adds the output of the square table 10. In the adder 12, logarithmic data are added to each other, so that the antilogarithm corresponds to multiplication.

Reference numeral 12 is a correction value table composed of a ROM or the like, in which volume correction data FCL corresponding to the formant band width value K is stored. This volume correction data FC
L is for correcting the audible sound volume (see L1 in FIG. 11 or FIG. 2) that decreases with an increase in the formant bandwidth value K to a flat characteristic. That is, the correction value table 12 uses the data corresponding to the formant bandwidth value K as a read address, and outputs the volume correction data FCL stored corresponding to the read address. This volume correction data FCL is -10 + K as shown in FIG.
It is expressed by a linear expression of / 10 (dB). The logarithmic sin table 8 and the logarithmic sin squared table 1 described above are used.
When the logarithmic data is stored as "-log" at 0, the linear expression is 10-K / 10. When such volume correction data FCL is added to the formed formant sound, the perceptual volume characteristic indicated by the straight line L1 becomes a flat characteristic, that is, the perceptual volume is constant regardless of the bandwidth value K.

Reference numeral 13 denotes an adder for adding the output of the adder 11 and the volume correction data FCL (corresponding to multiplication with an antilogarithm),
4 is the output of the adder 13 and the envelope signal lo described above.
gENV is an adder that adds (corresponds to multiplication with an antilogarithm). Reference numeral 15 is an OR gate that forms the logical sum of the underflow signals output from the adders 11, 13, and 14. 16 is a limiter. This limiter 16 sets all bits to "1" when any of the adders 11, 13, and 14 underflows. That is,
The limiter 16 sets the amplitude of the formant sound signal to "0" when underflow occurs.
Reference numeral 17 is a log / which converts the formant sound signal represented by logarithmic data output from the limiter 16 into antilogarithmic data.
It is a linea conversion table. Reference numeral 18 denotes a digital / analog converter that converts the formant sound signal converted into the true number data into an analog signal and outputs the analog signal.

B. Operation of the Embodiment With such a configuration, when a key is pressed in a state where a tone color is designated, a tone color parameter (fc, K, EB) is generated and a key-on signal Kon corresponding to a key-press operation is generated.
And the key code KC is generated. Of the generated tone color parameters, the formant center frequency fc is accumulated in the phase accumulator 7, and the logarithmic sin wave is read from the logarithmic sin table 8 according to this accumulation operation. Here, the frequency of the logarithmic sin wave matches the formant center frequency fc.

The logarithmic sin wave thus generated is read out in correspondence with the formant bandwidth value K of the logarithmic si wave.
The formant sound signal is obtained by adding the n squared wave (window function). Then, the formant sound signal is added to the adder 13
At, the correction value data FCL corresponding to the bandwidth value K is added. As a result, the power spectrum of the formant sound is improved so as to have a constant audible volume regardless of the band width K. Then, the envelope shape of the formant sound signal whose audible volume is corrected is defined based on the envelope signal logENV. Then, after this, it is converted into a true number by the log / linea conversion table 17, and then output as a musical tone signal via the D / A converter 18.

C. Other Embodiments In the above-described correction of the perceptual sound volume, since the power spectrum of the formant sound is corrected, its rms value can be theoretically normalized. However, when the bandwidth is the smallest (when the bandwidth value K is "0"), the amplitude uniquely decreases by -10 dB, so that the average volume of the formant sound is greatly reduced.

By the way, the formant sound is as shown in FIG.
As is clear from the power spectrum shown in FIG. 10B, the larger the formant band width Bw, the more harmonic components are included. Further, when two formant tones having the same rms value are compared, there is a fact that the more formant tones include the higher harmonics, the larger the audibility can be heard. Considering such a fact, as described above, when the bandwidth value K is "0", the correction of -10 dB is not necessary.

Therefore, the correction value data FCL 'shown in FIG. 3 may be used to correct the audible sound volume in consideration of the harmonic components of the formant sound. That is, a data table is stored in the correction value table 12 so that the correction data FCL ′ = − 5 + 20 / K (dB) is read according to the bandwidth value K. As a result, if the correction value data output from the table 12 is added to the formant sound, the perceptual sound volume can be made constant without lowering the average sound volume of the formant sound.

D. Modified Example In the above-described embodiment, the correction value data corresponding to the bandwidth value K is added to the formant sound, but instead of this, the following mode may be adopted. That is, the bandwidth value K
Method for correcting the amplitude of the window function corresponding to
Examples include a method of correcting the output level of the n-wave table and a method of correcting the envelope signal logENV.
For these corrections, in addition to the table reading method described above, correction values may be generated by calculation and linearly corrected.

The above-mentioned correction value data FCL, FC
L ′ can be expressed by a linear expression for linear correction, but the present invention is not limited to this, and it is also possible to control the audible sound volume non-linearly by using a correction expression of a second or higher order, for example. .. Further, the correction value is changed according to the bandwidth value K, but instead of this, for example, the correction value may be selected according to the key code KC.
That is, a correction value table corresponding to each key range is provided,
A correction value table corresponding to the key range of the depressed key code KC may be selected. By doing so, it becomes possible to control the audible characteristic according to the pitch of the formed formant sound.

[0023]

As described above, according to the present invention, the correcting means corrects the power spectrum of the formant sound corresponding to the formant band width, so that the formant having a constant audible sound volume regardless of the band width value. A sound can be formed.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment according to the present invention.

FIG. 2 is a diagram showing characteristics of correction value data FCL in the same embodiment.

FIG. 3 is a diagram showing characteristics of correction value data FCL ′ in another embodiment.

FIG. 4 is a diagram for explaining a conventional example.

FIG. 5 is a diagram for explaining a conventional example.

FIG. 6 is a diagram showing a formant sound waveform example formed by a conventional formant sound generator and a power spectrum example of the waveform.

FIG. 7 is a diagram showing a formant sound waveform example formed by a conventional formant sound generator and a power spectrum example of the waveform.

FIG. 8 is a diagram showing a formant sound waveform example formed by a conventional formant sound generator and a power spectrum example of the waveform.

FIG. 9 is a diagram showing a formant sound waveform example formed by a conventional formant sound generator and a power spectrum example of the waveform.

FIG. 10 is a diagram showing a formant sound waveform example formed by a conventional formant sound generator and a power spectrum example of the waveform.

FIG. 11: r of formant sound corresponding to band width K
The figure which shows a ms value.

[Explanation of symbols]

5 ... Phase accumulator, 6 ... Differentiation circuit, 7 ...
Phase accumulator, 8 ... logarithmic sin table,
9 ... Phase accumulator, 10 ... Logarithmic sin square table, 11 ... Adder, 12 ... Correction value table.

Claims (1)

[Claims] 1. A formant sound generator that repeatedly generates, based on a basic pitch period, a multiplication wave formed by multiplying a periodic function having a frequency matching the formant center frequency and a window function having a period corresponding to the formant bandwidth. The formant sound generation device according to claim 1, further comprising a correction unit that corrects the power spectrum of the multiplied wave in accordance with the formant bandwidth.