JP2019068188A - Effector - Google Patents

Abstract

The present invention provides an effector capable of easily adjusting the balance between high and low tones within a range including selecting only one of high-tone and low-tone tones. An effector according to the present invention includes a second or higher order high pass filter, a second order or higher order low pass filter, and a weighted addition unit arranged in parallel. The weighted addition unit outputs a signal that is a predetermined multiple of the weighted average of the output of the high pass filter and the output of the low pass filter. The first effector of the present invention is further characterized in that the difference between the cutoff frequency of the high pass filter and the cutoff frequency of the low pass filter is within a predetermined range. The second effector of the present invention further includes a correction unit that smoothes the frequency characteristic of a combination of a high pass filter, a low pass filter, and a weighted addition unit when the weight is 1: 1. [Selected figure] Figure 1

Description

  The present invention relates to an effector for acoustic signals.

  Patent documents 1-3 etc. are known as a technique which adjusts the timbre etc. of an acoustic signal. In Patent Documents 1 to 3, the sound signal is divided for each frequency component by passing the input sound signal through a high pass filter and a low pass filter arranged in parallel, and processing is performed on a frequency band that requires processing. It is adding up. Patent Document 4 shows a configuration in which a plurality of combinations of band pass filters, distortion circuits, and variable resistors are arranged in parallel.

JP-A-49-73010 Japanese Patent Application Laid-Open No. 8-234790 JP-A-9-68992 Japanese Utility Model Publication No. 58-190698

  Patent documents 1 to 3 are techniques for improving the sound quality. Further, Patent Document 4 is a technique for obtaining a well-balanced clear distortion sound even when a musical tone signal by a chord performance is inputted. Therefore, the prior art does not show a technique for simply adjusting the balance within a range including selecting only one of the high tone and the low tone contained in one acoustic signal. In the case of the technique disclosed in Patent Document 4, it is considered possible to obtain an output in which only a specific musical tone is selected by adjusting a plurality of variable resistors. However, the operator needs to adjust a plurality of variable resistances, and it is not a technique that can easily select high-pitched tones or low-pitched tones.

  It is an object of the present invention to provide an effector capable of easily adjusting the balance between high and low tones within a range including selecting only one of high and low tones.

  The effector of the present invention includes a second or higher order high pass filter, a second order or higher order low pass filter, and a weighted addition unit arranged in parallel. The weighted addition unit outputs a signal that is a predetermined multiple of the weighted average of the output of the high pass filter and the output of the low pass filter. The first effector of the present invention is further characterized in that the difference between the cutoff frequency of the high pass filter and the cutoff frequency of the low pass filter is within a predetermined range. The second effector of the present invention further includes a correction unit that smoothes the frequency characteristic of a combination of a high pass filter, a low pass filter, and a weighted addition unit when the weight is 1: 1.

According to the effector of the present invention, the weighted addition unit outputs a signal which is a predetermined multiple of the weighted average of the output of the high pass filter and the output of the low pass filter. That is, assuming that the output of the high pass filter is V _H , the output of the low pass filter is V _L , the weight of the output of the high pass filter is r, the weight of the output of the low pass filter is R−r, and the predetermined multiple is A, The output V _OUT is
V _OUT = A (rV _H + (R−r) V _L ) / R
It becomes. Here, A and R are constants, and the only variable value is r. When r is near R, only high-pitched tones can be selected, and when r is near 0, only low-pitched tones can be selected. When r is not near 0 or near R, the balance between high and low tones can be adjusted. Therefore, according to the effector of the present invention, the balance can be easily adjusted within a range including selecting only one of the high tone and the low tone by operating only one variable.

FIG. 2 is a view showing an example of the arrangement of an effector according to the first embodiment; FIG. 7 is a view showing the configuration of an effector more specifically showing the weighted addition unit of the first embodiment; FIG. 7 is a diagram showing frequency characteristics of the high pass filter and the low pass filter of the first embodiment, and frequency characteristics of outputs when weighted addition of respective outputs is performed on a one-to-one basis. The figure which shows the mode of a change of the frequency characteristic of the effector of Example 1 when the variable resistance of a weight addition part is operated. FIG. 7 is a view showing an example of the arrangement of an effector according to the second embodiment; FIG. 7 is a view showing the configuration of an effector more specifically showing the weighted addition unit of the second embodiment; FIG. 7 is a diagram showing frequency characteristics of the high-pass filter and the low-pass filter of the second embodiment and frequency characteristics of outputs when weighted addition of respective outputs is performed on a one-to-one basis. FIG. 7 is a diagram showing frequency characteristics of an output and a frequency characteristic of a correction unit when weighted addition of outputs of the high pass filter and the low pass filter according to the second embodiment is performed on a one-to-one basis. The figure which shows the mode of a change of the frequency characteristic of the effector of Example 2 when the variable resistance of a weight addition part is operated. The figure which shows the structural example of the effector of Example 2 modification. The figure which shows the structure of the effector which showed the weighted addition part of the Example 2 modification more concretely.

  Hereinafter, embodiments of the present invention will be described in detail. Note that components having the same function will be assigned the same reference numerals and redundant description will be omitted.

  The structural example of the effector of Example 1 is shown in FIG. The effector 100 includes a second or higher order high pass filter 110, a second or higher order low pass filter 120, a weighted addition unit 130, and a control unit 190. The high pass filter 110 and the low pass filter 120 are arranged in parallel. The second-order filter means a filter whose blocking amount increases by about -12 dB for each octave in a frequency band for blocking a signal. Generally, the first order filter is about -6 dB / octave, and the third order filter is about -18 dB / octave. In other words, a 2nd or higher-order high-pass filter is a filter in which the cutoff increases by about -12 dB or more when the frequency is lower by one octave (when the frequency is halved) in the stopband of the signal . Further, a low-pass filter of second order or higher is a filter in which the cutoff increases by about -12 dB or more when the frequency of one octave becomes higher (when the frequency is doubled) in the stop band of the signal . The filter characteristics may be appropriately selected from Butterworth filters, Chebyshev filters, etc. However, for the effector 100, it is desirable that the ripple be small.

Further, the effector 100 is characterized in that the difference between the cutoff frequency F _CH (the frequency at which cutoff is −3 dB) of the high pass filter 110 and the cutoff frequency F _CL of the low pass filter 120 is within a predetermined range. In general, if the cutoff frequency F _CH and the cutoff frequency F _CL coincide with each other, the high pass filter 110 and the low pass filter 120 are disposed in parallel, and the frequency characteristics when added at a ratio of one to one are , Almost flat. And, as the cutoff frequency F _CH and the cutoff frequency F _CL are apart, the flatness becomes uneven. “Within the range in which the difference between the cutoff frequency F _CH of the high pass filter 110 and the cutoff frequency F _CL of the low pass filter 120 is predetermined”, the high pass filter 110 and the low pass filter 120 are arranged in parallel. The frequency characteristics when added at the ratio of {circumflex over (.)} Mean an acceptably flat range. The control unit 190 instructs the operator (setting of the cutoff frequency F _CH of the high pass filter 110 and the cutoff frequency F _CL of the low pass filter 120) while maintaining the difference within a predetermined range. Change according to external input).

The weighted addition unit 130 outputs a signal that is a predetermined multiple of the weighted average of the output of the high pass filter 110 and the output of the low pass filter 120. Assuming that the output of the high pass filter is V _H , the output of the low pass filter is V _L , the weight of the output of the high pass filter is r, the weight of the output of the low pass filter is R−r, and the predetermined multiple is A, the output of the weighted addition unit 130 V _OUT is
V _OUT = A (rV _H + (R−r) V _L ) / R
It becomes. Here, A and R are constants, and the only variable value is r. When r is near R, only high-pitched tones can be selected, and when r is near 0, only low-pitched tones can be selected. When r is not near 0 or near R, the balance between high and low tones can be adjusted. Therefore, according to the effector 100, the balance can be easily adjusted within a range including selecting only one of the high tone and the low tone by operating one variable.

<Specific example>
FIG. 2 shows the configuration of an effector more specifically showing the weighted addition unit of the first embodiment. The effector 101 differs from the effector 100 only in the portion of the weighted addition unit 131. The weighted addition unit 131 is one specific example of the weighted addition unit 130. The weighted addition unit 131 includes a variable resistor 132 whose entire resistance is R and an amplifier 133. When the operator operates the knob of the variable resistor 132, the value of the resistor r changes. Then, assuming that the amplification factor of the amplifier 133 is A, the output V _OUT of the weighted addition unit 131 is
V _OUT = A (rV _H + (R−r) V _L ) / R
It becomes. That is, the weighted addition unit 131 is one of the specific examples of the weighted addition unit 130.

FIG. 3 shows the frequency characteristics of the high pass filter and the low pass filter of the first embodiment, and the frequency characteristics of the outputs when the respective outputs are weighted and added one by one. The dashed-dotted line indicates the frequency characteristic of the high pass filter, the broken line indicates the frequency characteristic of the low pass filter, and the solid line indicates the frequency characteristic of the output. The cutoff frequency F _CH of the high pass filter 110 is 600 Hz, and the cutoff frequency F _CL of the low pass filter 120 is 1 kHz. In this example, although the cutoff frequency F _CH and the cutoff frequency F _CL are different, it can be seen that the frequency characteristic of the output when weighted addition is performed on a one-to-one basis is substantially flat. If this frequency characteristic is acceptable, the above-mentioned “difference between the cutoff frequency F _CH of the high pass filter 110 and the cutoff frequency F _CL of the low pass filter 120 falls within a predetermined range”.

  FIG. 4 shows how the frequency characteristics of the effector of Example 1 change when the variable resistance of the weighted addition unit is operated. In this simulation, the resistance R is 10 kΩ and the amplification factor is 1. Then, the resistance r is changed by about 1 kΩ from about 0 kΩ to about 10 kΩ. As can be seen from FIG. 4, it is possible to select the high tone or the low tone with a difference of 20 dB or more to the other only by changing the resistance r (the operator merely manipulates the knob of the variable resistor 132), and select both. it can. Therefore, the balance can be easily adjusted in a range including selecting only one of the high tone and the low tone.

  For example, it is assumed that an acoustic signal in which a sound of about 100 Hz such as bass and a sound of about 3 kHz such as percussion are mixed at the same volume is input. At this time, if the value of r is increased, the bass sound is sufficiently attenuated, so it can be heard that a person contains only a percussion sound. In addition, if the value of r is decreased, the percussion sound is sufficiently attenuated, so it sounds like a sound containing only the bass sound.

  The structural example of the effector of Example 2 is shown in FIG. The effector 200 includes a second or higher order high pass filter 110, a second or higher order low pass filter 120, a weighted addition unit 130, a correction unit 240, and a control unit 290. The high pass filter 110, the low pass filter 120, and the weighted addition unit 130 are the same as the effector 100.

The correction unit 240 smoothes the frequency characteristic of the combination of the high-pass filter 110, the low-pass filter 120, and the weighted addition unit 130 when the weight is 1: 1. In the first embodiment, the difference between the cutoff frequency F _CH (the frequency at which the cutoff is −3 dB) of the high pass filter 110 (the cutoff is −3 dB) and the cutoff frequency F _CL of the low pass filter 120 is limited to a predetermined range. Was almost flat. In the second embodiment, the correction unit 240 is provided to freely set the cutoff frequency. The correction unit 240 corrects the input V _IN and outputs the corrected signal V _INC . The corrected signal V _INC is input to the high pass filter 110 and the low pass filter 120. The subsequent processing is the same as in the first embodiment.

The control unit 290 changes settings of the cutoff frequency F _CH of the high pass filter 110 and the cutoff frequency F _CL of the low pass filter 120. Then, the correction unit 240 smoothes the frequency characteristic of the combination of the high-pass filter 110, the low-pass filter 120, and the weighted addition unit 130 after the change. For example, the correction unit 240 previously records a plurality of data of correction values for smoothing the frequency characteristic corresponding to the combination of the cutoff frequency F _CH and the cutoff frequency F _CL . The control unit 290 transmits information on the combination of the cutoff frequency F _CH and the cutoff frequency F _CL to the correction unit 240, and the correction unit 240 may smooth the frequency characteristics according to the data of the correction value from the received information. .

Alternatively, the control unit 290 changes the settings of the cutoff frequency F _CH of the high pass filter 110 and the cutoff frequency F _CL of the low pass filter 120, and combines the high pass filter 110, the low pass filter 120, and the weighted addition unit 130 after the change. The correction unit 240 may be adjusted to smooth the frequency characteristics of the above configuration. For example, the control unit 290 previously records a plurality of data of correction values for smoothing the frequency characteristic corresponding to the combination of the cutoff frequency F _CH and the cutoff frequency F _CL . The control unit 290 reads out data of the correction value according to the information of the combination of the cutoff frequency F _CH and the cutoff frequency F _CL and transmits it to the correction unit 240, and the correction unit 240 performs frequency characteristic according to the data of the received correction value. It may be smoothed.

  With such a configuration, according to the effector 200, as in the effector 100, the balance can be simplified simply by operating one variable to include selection of only one of the high-pitched tone and the low-pitched tone. It can be adjusted.

<Specific example>
FIG. 6 shows a configuration of an effector more specifically showing the weighted addition unit of the second embodiment. The effector 201 differs from the effector 200 only in the portion of the weighted addition unit 131. The weighted addition unit 131 is one specific example of the weighted addition unit 130. The weighted addition unit 131 includes a variable resistor 132 whose entire resistance is R and an amplifier 133. When the operator operates the knob of the variable resistor 132, the value of the resistor r changes. Then, assuming that the amplification factor of the amplifier 133 is A, the output V _OUT of the weighted addition unit 131 is
V _OUT = A (rV _H + (R−r) V _L ) / R
It becomes.

FIG. 7 shows the frequency characteristics of the high pass filter and the low pass filter of the second embodiment, and the frequency characteristics of the output when the respective outputs are weighted and added one by one. The dashed-dotted line indicates the frequency characteristic of the high pass filter, the broken line indicates the frequency characteristic of the low pass filter, and the solid line indicates the frequency characteristic of the output. The cutoff frequency F _CH of the high pass filter 110 is 200 Hz, and the cutoff frequency F _CL of the low pass filter 120 is 2.0 kHz. The output when 1-to-1 weighted addition has a difference of about 6 dB depending on the frequency.

  FIG. 8 shows the frequency characteristic of the output and the frequency characteristic of the correction unit when the outputs of the high pass filter and the low pass filter according to the second embodiment are weighted and added one by one. The solid line is the frequency characteristic of the output when weighted addition is performed on a one-to-one basis, and the dotted line is the frequency characteristic of the correction unit 240. It can be seen that the frequency characteristic of the correction unit 240 is close to the characteristic obtained by inverting the frequency characteristic of the output when weighted addition is performed on a one-to-one basis.

  FIG. 9 shows how the frequency characteristics of the effector of Example 2 change when the variable resistance of the weighted addition unit is operated. In this simulation, the resistance R is 10 kΩ and the amplification factor is 1. Then, the resistance r is changed by about 1 kΩ from about 0 kΩ to about 10 kΩ. As can be seen from FIG. 9, the treble or bass can be selected with a difference of 20 dB or more to the other simply by changing the resistance r, and both can also be selected. Therefore, the balance can be easily adjusted in a range including selecting only one of the high tone and the low tone. Further, the volume of the low-pitched sound side increases when the resistance r is small, and the high-pitched sound side increases when the resistance r is large. Therefore, there is also an effect of making it difficult for a person to hear small sounds (ones not selected).

Furthermore, in FIG. 9, it can be seen that the gain of 500 Hz to 1 kHz hardly changes. By keeping the volume of the melody constant, it is possible to change the sound quality without changing the sense of volume felt by people. Frequency band of the melody, since change genre of music, musical instruments, such as by vocal gender, by the controller 290 in accordance with the music change the cutoff frequency F _CL cutoff frequency F _CH and the low-pass filter 120 of the high-pass filter 110 Just do it.

  For example, an acoustic signal including a sound representing a rhythm of about 100 Hz like a bass and a sound representing a rhythm about 3 kHz like a percussion at a similar volume and including a melody centered on 500 Hz to 1 kHz Is input. At this time, if the value of r is increased, the bass sound is sufficiently attenuated, so it sounds like a sound including melody and percussion sounds. In addition, if the value of r is decreased, the percussion sound is sufficiently attenuated, so it sounds like a sound that includes melody and bass sounds. That is, only by operating the knob of the variable resistance 132, the operator outputs the melody without changing the feeling of volume, selects one of the bass and the percussion, which is the sound expressing the rhythm, and the sound expressing the rhythm. You can adjust the balance of

[Modification]
FIG. 10 shows a configuration example of the effector of the second embodiment. The effector 202 is different from the effector 200 in the position of the correction unit 240. In the effector 202, the output V _C of the weighted addition unit 130 is input to the correction unit 240, and the output of the correction unit 240 becomes the output V _{OUT of the} effector 202. The other configuration is the same as that of the effector 200. Therefore, the same effect as the effector 200 can be obtained.

<Specific example>
FIG. 11 shows the configuration of an effector more specifically showing the weighted addition unit of the second embodiment. The effector 203 differs from the effector 202 only in the portion of the weighted addition unit 131. The weighted addition unit 131 is one specific example of the weighted addition unit 130. The effector 203 differs from the effector 201 only in the position of the correction unit 240. Therefore, the same effect as the effector 201 can be obtained.

100, 101, 200, 201, 202, 203 Effector 110 High Pass Filter 120 Low Pass Filter 130, 131 Weighted Addition Unit 132 Variable Resistor 133 Amplifier 190, 290 Control Unit 240 Correction Unit

Claims (6)

2nd or higher order high pass filters and 2nd order or higher order low pass filters arranged in parallel;
A weighted addition unit that outputs a signal that is a predetermined multiple of the weighted average of the output of the high pass filter and the output of the low pass filter;
An effector in which a difference between a cutoff frequency of the high pass filter and a cutoff frequency of the low pass filter is within a predetermined range. The effector according to claim 1, wherein
An effector comprising: a control unit that changes settings of the cutoff frequency of the high pass filter and the cutoff frequency of the low pass filter while maintaining that the difference is within a predetermined range. 2nd or higher order high pass filters and 2nd order or higher order low pass filters arranged in parallel;
A weighted addition unit that outputs a signal that is a predetermined multiple of the weighted average of the output of the high pass filter and the output of the low pass filter;
An effector comprising: a correction unit that smoothes a frequency characteristic of a combination of the high pass filter, the low pass filter, and the weighted addition unit when the weight is 1: 1. The effector according to claim 3, wherein
A control unit configured to change settings of a cutoff frequency of the high pass filter and a cutoff frequency of the low pass filter;
The correction unit smoothes the frequency characteristic of a combination of the high-pass filter, the low-pass filter, and the weighted addition unit after change. The effector according to claim 3, wherein
The setting of the cutoff frequency of the high pass filter and the cutoff frequency of the low pass filter is changed, and the frequency characteristic of the combination of the high pass filter, the low pass filter, and the weighted addition unit after the change is smoothed. A control unit that adjusts the correction unit. The effector according to any one of claims 1 to 5, wherein
The effector according to claim 1, wherein the weight is determined by one variable resistance.

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