JP6578859B2 - Acoustic signal processing device - Google Patents

Description

  The present invention relates to a signal processing technique that expands the range of expressive power of reproduced sound of a digital audio signal.

  For example, with the widespread use of digital audio equipment that reproduces sound in accordance with a digital sound signal such as a CD player, it is possible to easily reproduce clear sound free from noise and distortion.

JP 2004-048140 A JP 2004-264502 A

  If the digital sound signal is subjected to signal processing to obtain a reproduced sound as if an analog record is being reproduced, the range of expression of the reproduced sound can be expanded. In recent years, attention has been focused on the warm sound quality of the playback sound of analog records, so the need for this signal processing is also considered high.

  As signal processing for making a playback sound as if an analog record is being played back, for example, signal processing for adding noise included in the playback sound of an analog record to a digital acoustic signal can be considered.

  However, the signal processing that adds noise to the digital audio signal is insufficient to produce a reproduced sound as if an analog record is being reproduced. The reason is as follows. The analog record is reproduced by tracing the groove provided in the analog record with the analog record needle. Since the analog record needle is pressed vertically against the groove of the analog record, when tracing the groove of the analog record, the analog record needle is easier to move in the horizontal direction than in the vertical direction, and the vertical movement is suppressed. It tends to be. Due to the physical phenomenon peculiar to such an analog record, the reproduction sound of the analog record is distorted according to this physical phenomenon, but even if signal processing that adds noise to a digital acoustic signal is performed, such an analog record This is because the reproduced sound is not distorted according to the physical phenomenon peculiar to the record.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a signal processing technique that expands the range of expressive power of reproduced sound of a digital acoustic signal.

  In order to solve the above-described problems, the present invention provides a first nonlinear processing unit that nonlinearly amplifies the amplitude of an in-phase signal obtained by adding an L channel signal and an R channel signal, and any one of an L channel signal and an R channel signal. A second non-linear processing unit that non-linearly amplifies the amplitude of the reverse phase signal obtained by subtracting the other from the other, the amplification factor of the first non-linear processing unit, and the amplification of the second non-linear processing unit Provided is an acoustic signal processing device characterized by having different rates.

  According to the present invention, since the amplification factor of the first non-linear processing unit is different from the amplification factor of the second non-linear processing unit, the range of expressive power of reproduced sound is widened. Patent Document 1 discloses a technique for grouping a plurality of input signals and amplifying the amplitude of the input signal for each group. Patent Document 2 discloses a technique for dividing an input signal into a plurality of frequency bands and amplifying the amplitude of the input signal for each frequency band. However, the techniques disclosed in Patent Document 1 and Patent Document 2 are not signal processing techniques that expand the range of expressive power of reproduced sound, but are completely different from the present invention.

  As a more preferable aspect, the amplification factor of the second nonlinear processing unit is smaller than the amplification factor of the first nonlinear processing unit. In an analog record, the distortion of the reproduced sound is more likely to occur in the opposite phase signal than in the in-phase signal according to the physical phenomenon unique to the analog record. According to this aspect, the reproduction sound reproduces the distortion corresponding to the physical phenomenon peculiar to the analog record, and the reproduction sound as if the analog record is reproduced.

  As a more preferable aspect, the amplitude of the in-phase signal after nonlinear amplification is limited to the first value or less, the amplitude of the anti-phase signal after nonlinear amplification is limited to the second value or less, and the second value is It is smaller than the first value. According to this aspect, the reproduction sound reproduces the distortion corresponding to the physical phenomenon peculiar to the analog record, and the reproduction sound as if the analog record is reproduced.

  As a more preferable aspect, the first nonlinear processing unit performs nonlinear amplification when the amplitude of the in-phase signal is equal to or greater than the first threshold value, and the second nonlinear processing unit has the amplitude of the anti-phase signal of the second value. If it is equal to or greater than the threshold value, nonlinear amplification is performed, and the second threshold value is smaller than the first threshold value. In the analog record, the larger the amplitude of the signal recorded in the groove, the more pronounced the distortion of the reproduced sound according to the physical phenomenon peculiar to the analog record. According to this aspect, the in-phase signal is nonlinearly amplified when the amplitude is equal to or greater than the first threshold value, while the anti-phase signal has the amplitude of the second threshold value (provided that the second threshold value <the first threshold value). If it is greater than or equal to the threshold, the reproduced sound reproduces the distortion corresponding to the physical phenomenon peculiar to the analog record, and can be closer to the reproduced sound as if the analog record is being reproduced. it can.

  As a more preferable aspect, the first low-pass filter that supplies the low-frequency component of the in-phase signal to the first nonlinear processor, and the second low-pass filter that supplies the low-frequency component of the anti-phase signal to the second nonlinear processor. And at least one of a low-pass filter. In an analog record, if the frequency of the reproduced sound is low, the reproduced sound is likely to be distorted according to a physical phenomenon unique to the analog record. According to this aspect, since the low frequency component of at least one of the in-phase signal and the anti-phase signal is nonlinearly amplified, the reproduced sound reproduces the distortion corresponding to the physical phenomenon peculiar to the analog record, and the analog record is reproduced. It can be closer to the playback sound as if it were.

It is a block diagram which shows the structural example of the reproducing | regenerating apparatus 1 using the acoustic signal processing apparatus 10 of 1st Embodiment of this invention. 2 is a block diagram illustrating a configuration example of the acoustic signal processing device 10. FIG. It is a functional block diagram which shows an example of the signal processing function which the signal processing part 110 of the acoustic signal processing apparatus 10 implement | achieves according to the signal processing program 134a. It is a graph which shows the relationship between the amplitude of the input signal in the nonlinear processing parts 211 and 221, and an output signal. It is sectional drawing for demonstrating the 45-45 system used with the analog record 30. FIG. It is sectional drawing which shows the behavior of the analog record needle | hook 20 when an L channel signal and an R channel signal are in-phase signals. It is sectional drawing which shows the behavior of the analog record needle | hook 20 when an L channel signal and an R channel signal are reverse phase signals. It is a graph which shows the relationship between the amplitude of the input signal and output signal in the nonlinear processing parts 211 and 221 of 2nd Embodiment of this invention. It is a functional block diagram which shows an example of the signal processing function which the signal processing part 110 of 3rd Embodiment of this invention implement | achieves according to the signal processing program 134b. It is a functional block diagram which shows the modification of 3rd Embodiment of this invention. It is a functional block diagram which shows the modification of 3rd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<First Embodiment>
(A: Configuration)
FIG. 1 is a block diagram illustrating a configuration example of a playback device 1 using the acoustic signal processing device 10 according to the first embodiment of the present invention. The playback device 1 includes an acoustic signal processing device 10, an acoustic signal input device 11, and an acoustic signal output device 12. The acoustic signal input device 11 is, for example, a CD player, and the acoustic signal output device 12 is, for example, a speaker.

  The acoustic signal input device 11 supplies an L channel signal and an R channel signal, which are digital acoustic signals, to the acoustic signal processing device 10. The acoustic signal processing device 10 performs signal processing (in this embodiment, non-linear amplification) on the L-channel signal and the R-channel signal to produce a reproduced sound as if an analog record is being reproduced, and supplies the processed signal to the acoustic signal output device 12. To do. The nonlinear amplification signal processing performed by the acoustic signal processing apparatus 10 includes not only signal processing in which the amplitude of the output signal is larger than the amplitude of the input signal, but also a signal in which the amplitude of the output signal is equal to or smaller than the amplitude of the input signal. Processing is also included. This is the same not only in this embodiment but also in other embodiments. The acoustic signal output device 12 reproduces sound based on the supplied L channel signal and R channel signal.

  FIG. 2 is a block diagram illustrating a configuration example of the acoustic signal processing device 10. As shown in FIG. 2, the acoustic signal processing apparatus 10 mediates data transmission / reception between the signal processing unit 110, the communication interface (hereinafter abbreviated as “I / F”) unit 120, the storage unit 130, and these components. A bus 140 is included.

  The signal processing unit 110 is, for example, a CPU (Central Processing Unit). The signal processing unit 110 functions as a control center of the acoustic signal processing device 10 by operating according to the signal processing program 134a stored in the storage unit 130 (more precisely, the nonvolatile storage unit 134). Details of processing executed by the signal processing unit 110 in accordance with the signal processing program 134a will be clarified later.

  The communication I / F unit 120 is a transceiver that performs communication conforming to a predetermined standard. The communication I / F unit 120 transmits the data delivered from the signal processing unit 110 to the acoustic signal output device 12, while receiving the data transmitted from the acoustic signal input device 11 and gives it to the signal processing unit 110. In the present embodiment, data communication between the acoustic signal processing device 10 and the acoustic signal input device 11 or the acoustic signal output device 12 is realized by wired communication, but may be realized by wireless communication. If the data communication between the acoustic signal processing device 10 and the acoustic signal input device 11 or the acoustic signal output device 12 is realized by wired communication, the communication I / F unit 120 may be a USB (Universal Serial Bus) I / F, A serial I / F, NIC (Network Interface Card), or the like may be used. In addition, if data communication between the acoustic signal processing device 10 and the acoustic signal input device 11 or the acoustic signal output device 12 is realized by wireless communication, another device such as a wireless access point device may be provided between them. It may be a mode through which it may be used, or a mode through a telecommunication line such as the Internet.

  The storage unit 130 includes a volatile storage unit 132 and a nonvolatile storage unit 134. The volatile storage unit 132 is, for example, a RAM (Random Access Memory). The volatile storage unit 132 is used by the signal processing unit 110 as a work area when executing various programs such as the signal processing program 134a. The nonvolatile storage unit 134 is, for example, a flash ROM (Read Only Memory). The nonvolatile storage unit 134 stores the signal processing program 134a described above in advance.

  The signal processing unit 110 reads the signal processing program 134a from the non-volatile storage unit 134 to the volatile storage unit 132 and starts executing it when the power (not shown) of the acoustic signal processing device 10 is turned on or reset. A signal processing function is given to the signal processing unit 110 operating according to the signal processing program 134a. Details of this signal processing function will be described in the operation of the acoustic signal processing apparatus 10.

(B: Operation)
FIG. 3 is a functional block diagram showing an example of a signal processing function realized by the signal processing unit 110 according to the signal processing program 134a. The signal processing function realized by the signal processing unit 110 according to the signal processing program 134a is provided in each block of the addition units 210 and 222, the subtraction units 212 and 220, the nonlinear processing units 211 and 221, and the multiplication units 213 and 223. Broadly divided.

  The adder 210 adds the L channel signal and the R channel signal supplied from the acoustic signal input device 11, and supplies the in-phase signal representing the in-phase component included in both signals to the nonlinear processing unit 211. The in-phase component refers to a signal component that is included in both the L channel signal and the R channel signal and that has the same phase at the same time. On the other hand, the subtraction unit 220 subtracts the L channel signal from the R channel signal, and supplies a negative phase signal representing the negative phase component included in both signals to the nonlinear processing unit 221. The anti-phase component refers to a signal component that is included in both the L channel signal and the R channel signal and whose phases at the same time are different by a half cycle.

  The nonlinear processing units 211 and 221 perform nonlinear amplification on the input signal according to a saturation function, and output to the subsequent stage. In the nonlinear processing units 211 and 221, the amplification factor decreases as the amplitude of the input signal increases. The amplification factor is the ratio of the amplitude of the output signal to the amplitude of the input signal. FIG. 4 is a graph showing the relationship between the amplitudes of the input signal and the output signal (that is, the saturation function) in the nonlinear processing units 211 and 221. The x-axis in FIG. 4 is the amplitude of the input signal, and the y-axis is the amplitude of the output signal. Furthermore, the slope of the graph of FIG. 4 is the amplification factor. As shown in FIG. 4, even if the amplitude of the input signal to the nonlinear processing units 211 and 221 is increased, the amplitude of the output signal exceeds the predetermined value only by approaching the predetermined constant value. There is no.

  The subtracting unit 212 subtracts the reverse phase signal supplied from the nonlinear processing unit 221 from the in-phase signal supplied from the nonlinear processing unit 211 and supplies the result to the multiplication unit 213. The multiplier 213 halves the amplitude of the supplied signal and outputs it as an L channel signal. On the other hand, the adder 222 adds the in-phase signal and the anti-phase signal, and supplies the result to the multiplier 223. The multiplier 223 halves the amplitude of the supplied signal and outputs it as an R channel signal.

In the present embodiment, the contents of nonlinear amplification in each of the nonlinear processing units 211 and 221 are different, and this is a feature of the present embodiment. Specifically, as shown in FIG. 4, the constant value q ₁ in the nonlinear processing unit 221 is smaller than the constant value p ₁ in the nonlinear processing unit 221. Furthermore, the amplification factor of the nonlinear processing unit 221 is smaller than the amplification factor of the nonlinear processing unit 211. The reason for this is as follows.

  FIG. 5 is a cross-sectional view for explaining the 45-45 method used in the analog record 30. The analog record 30 has a groove formed at 90 °, and the analog record needle 20 formed of diamond, for example, traces the groove to reproduce the sound. Generally, the inner circumferential side 45 ° of this groove is dug corresponding to the L channel signal, and the outer circumferential side 45 ° is dug corresponding to the R channel signal. Since the analog record needle 20 made of diamond or the like has a property that mutual interference does not occur in vibrations propagating in directions perpendicular to each other, the analog record needle 20 traces the groove of the analog record 30 to thereby prevent mutual interference. It is possible to extract an L channel signal and an R channel signal with a small amount. This is the 45-45 method used in the analog record 30.

  FIG. 6 is a cross-sectional view showing the behavior of the analog record needle 20 when the L channel signal and the R channel signal are in-phase signals. If the L channel signal and the R channel signal are in-phase signals, is force applied to the analog record needle 20 from the outer peripheral side to the inner peripheral side in parallel with the analog record 30 as shown in FIG. A force is applied from the inner circumference side to the outer circumference side in parallel with the analog record 30 as shown in FIG. Therefore, in this case, the analog record hand 20 swings in the horizontal direction of the analog record 30.

  FIG. 7 is a cross-sectional view showing the behavior of the analog record needle 20 when the L channel signal and the R channel signal are opposite phase signals. If the L channel signal and the R channel signal are opposite phase signals, a downward force is applied to the analog record needle 20 perpendicularly to the analog record 30 as shown in FIG. 7A, or FIG. An upward force is applied perpendicular to the analog record 30 as shown. Therefore, in this case, the analog record hand 20 swings in the vertical direction of the analog record 30.

  Since the analog record needle 20 is pressed against the groove of the analog record 30 in the vertical direction, movement in the vertical direction is suppressed. For this reason, the amplitude of the antiphase component included in the L channel signal and the R channel signal becomes smaller than the original amplitude value, and the reproduced sound is distorted.

In the nonlinear amplification in each of the nonlinear processing units 211 and 221 of the present embodiment, the amplification factor of the nonlinear processing unit 221 to which the anti-phase signal is supplied is made smaller than the amplification factor of the nonlinear processing unit 211 to which the in-phase signal is supplied. The reason why the constant value q ₁ in the non-linear processing unit 211 is smaller than the constant value p ₁ in the non-linear processing unit 221 is that the distortion of the anti-phase component in the reproduced sound of the 45-45 analog record 30 described above is caused. This is to reproduce. According to the present embodiment, it is possible to obtain a reproduced sound as if the analog record 30 is being reproduced, and the range of expressive power of the reproduced sound of the digital acoustic signal can be expanded.

Second Embodiment
FIG. 8 is a graph showing the relationship between the amplitudes of the input signal and the output signal in the nonlinear processing units 211 and 221 of the second embodiment of the present invention. The present embodiment is different from the first embodiment in the processing contents of nonlinear amplification for the input signals of the nonlinear processing units 211 and 221. Specifically, each of the nonlinear processing units 211 and 221 is a compressor. Except for the processing contents of this nonlinear amplification, the present embodiment is the same as the first embodiment. Therefore, in this embodiment, the same code | symbol is attached | subjected to the same component and the description is abbreviate | omitted. In the following, the processing contents of nonlinear amplification of the nonlinear processing units 211 and 221 will be mainly described.

  The x-axis in FIG. 8 is the amplitude of the input signal, and the y-axis is the amplitude of the output signal. Further, the slope of the graph of FIG. 8 is the amplification factor. As shown in FIG. 8, when the amplitude of the input signal is smaller than the threshold value, the nonlinear processing units 211 and 221 linearly amplify the input signal and supply it to the subsequent stage. On the other hand, when the amplitude of the input signal is greater than or equal to the threshold value, the input signal is linearly amplified with an amplification factor different from the amplification factor when the amplitude of the input signal is smaller than the threshold value, and output to the subsequent stage. As a result, the processing content performed by the nonlinear processing units 211 and 221 on the input signal is nonlinear amplification.

As shown in FIG. 8, less than the threshold value p ₂ for the amplitude of it is in-phase signal threshold q ₂ for the amplitude of the reverse-phase signal in the present embodiment. The amplification factor of the nonlinear processing unit 221 is smaller than the amplification factor of the nonlinear processing unit 211. For this reason, also in this embodiment, the distortion of the reverse phase component in the analog record 30 can be reproduced, and the reproduced sound is as if the analog record 30 is being reproduced.

  The distortion of the reproduced sound of the analog record 30 becomes more significant as the amplitude of the signal recorded in the groove is larger. That is, the reproduced sound of the analog record 30 is not distorted when the amplitude of the signal recorded in the groove is small, and is distorted when the amplitude is large. According to the present embodiment, since the nonlinear processing units 211 and 221 perform nonlinear amplification on the input signal only when the amplitude of the input signal is greater than or equal to the threshold value, the analog processing unit 30 reproduces the analog record 30 compared to the first embodiment. It is possible to make the reproduced sound as close as possible, and the range of expressive power of the reproduced sound of the digital audio signal can be further expanded.

<Third Embodiment>
FIG. 9 is a functional block diagram showing an example of functions realized by the signal processing unit 110 according to the third embodiment of the present invention in accordance with the signal processing program 134b. The present embodiment is different from the first embodiment in that not the signal processing program 134 a but the signal processing program 134 b is stored in the nonvolatile storage unit 134. Except for this point, the present embodiment is the same as the first embodiment. Therefore, in this embodiment, the same code | symbol is attached | subjected to the same component and the description is abbreviate | omitted. Hereinafter, the signal processing program 134b will be mainly described.

  As is clear from comparison between FIG. 9 and FIG. 4, the signal processing function realized by the signal processing unit 110 according to the signal processing program 134b is the same as the signal processing function realized by the signal processing unit 110 according to the signal processing program 134a. These blocks are roughly divided into high-pass filters 310 and 320, low-pass filters 311 and 321 and adders 330 and 331. The high-pass filters 310 and 320 are band division filters that supply only a signal in a higher frequency band than a predetermined frequency to the subsequent stage, and the low-pass filters 311 and 321 are only a signal in a low frequency band equal to or lower than the predetermined frequency in the subsequent stage. This is a band division filter to be supplied.

  The input signal is band-divided by high-pass filters 310 and 320 and low-pass filters 311 and 321. Then, the high frequency components of the input signal that are band-divided by the high pass filters 310 and 320 are supplied to the adding units 330 and 331 without any processing. On the other hand, the low frequency components of the input signal band-divided by the low pass filters 311 and 321 are subjected to the same nonlinear amplification as in the first embodiment. Note that this nonlinear amplification may be the nonlinear amplification of the second embodiment.

  The high-frequency component of the input signal band-divided by the high-pass filters 310 and 320 and the low-frequency component of the input signal subjected to nonlinear amplification are added by the adders 330 and 331 and supplied to the acoustic signal output device 12 as an output signal. Is done.

  In the present embodiment, non-linear amplification is performed only on the low frequency component of the input signal for the following reason. Since the low frequency component of the input signal has a large amplitude, reproduction sound distortion becomes significant in the low frequency band. The present embodiment is for reproducing this phenomenon.

  According to the present embodiment, it is possible to get closer to the reproduced sound as if the analog record 30 is being reproduced than in the first embodiment, and the range of expressive power of the reproduced sound of the digital audio signal can be further expanded. .

<Other embodiments>
The first to third embodiments of the present invention have been described above. However, the present invention may have other embodiments. For example:
(1) In each of the above embodiments, in order to obtain a playback sound as if the analog record 30 is being played back, the non-linear processing units 211 and 221 are shown in FIG. 4 and FIG. Non-linear amplification as shown was applied. However, this non-linear amplification is not limited to the non-linear amplification shown in FIGS. 4 and 8, and other non-linear amplification may be used as long as the reproduced sound is as if the analog record 30 is being reproduced.

(2) In the above embodiments, the signal processing according to the present invention is realized by the signal processing program 134a or 134b which is a computer program. However, the mode of the means for performing the signal processing (nonlinear amplification) according to the present invention is not limited to the computer program. For example, the adding unit 210, the non-linear processing units 211 and 221 and the like may be configured by an electronic circuit or the like, and these units may be combined.

(3) In each of the above embodiments, the L channel signal is subtracted from the R channel signal to obtain a reverse phase signal. However, the R channel signal may be subtracted from the L channel signal to obtain a reverse phase signal. However, in this case, it is necessary to provide an adding unit that adds the in-phase signal and the anti-phase signal instead of the subtracting unit 212, and to provide a subtracting unit that subtracts the anti-phase signal from the in-phase signal instead of the adding unit 222. This is because the L channel signal and the R channel signal are supplied to the acoustic signal output device 12.

(4) In each of the above embodiments, the amplification factor of the non-linear processing unit 221 to which the anti-phase signal is supplied is smaller than the amplification factor of the non-linear processing unit 211 to which the in-phase signal is supplied. In this case, it is possible to create a new sound that has not been available before, and the range of expressive power of the reproduced sound of the digital sound signal can be expanded. Further, in the first embodiment, the constant value q ₁ of the anti-phase signal is smaller than the constant value p ₁ of the in-phase signal, but the opposite may be possible. In the second embodiment, the anti-phase signal threshold value q ₂ is smaller than the in-phase signal threshold value p ₂ . In either case, the range of expressive power of the reproduced sound of the digital audio signal can be expanded.

(5) The first embodiment and the second embodiment may be combined. The nonlinear processing unit 211 or 221 performs linear amplification on the input signal when the amplitude of the input signal is smaller than the threshold value, and amplifies as the amplitude of the input signal increases when the amplitude of the input signal is larger than the threshold value. The rate is reduced, and nonlinear amplification is performed so that the amplitude of the input signal approaches a predetermined constant value. The amplitude of the input signal subjected to nonlinear amplification does not exceed this fixed value. By doing in this way, it can be brought closer to the reproduced sound as if the analog record 30 is being reproduced, and the range of the expressive power of the reproduced sound of the digital acoustic signal can be further expanded.

(6) In the third embodiment, the adding unit 210 and the subtracting unit 220 are provided after the low-pass filters 311 and 321, respectively. However, as shown in FIG. As shown in FIG. 11, a high-pass filter 310 and a low-pass filter 311 may be provided after the adding unit 210, and a high-pass filter 320 and a low-pass filter 321 may be provided after the subtracting unit 220. However, in this case, it is necessary to provide the addition units 330 and 331 at the subsequent stage of the nonlinear processing units 211 and 221, respectively. In short, any mode may be used as long as the low frequency component of the in-phase signal is supplied to the nonlinear processing unit 211 and the low frequency component of the reverse phase signal is supplied to the nonlinear processing unit 221.

(7) In the third embodiment, band division is performed to divide the input signal at a predetermined frequency by the two filters, the high-pass filter 310 and the low-pass filter 311, but a band-pass filter may be further used. If it is this aspect, distortion of reproduction sound can be adjusted more finely, it can be brought closer to reproduction sound as if analog record 30 is reproduced, and the range of expressive power of reproduction sound of a digital sound signal can be increased. It can be expanded.

(8) In the third embodiment, both the L channel signal and the R channel signal are band-divided, but only one of the L channel signal and the R channel signal may be band-divided. That is, in the signal processing function realized by the signal processing unit 110 according to the signal processing program 134b, the high-pass filter 310, the low-pass filter 311 and the addition unit 330 may not be present, or the high-pass filter 320, the low-pass filter 321 and the addition unit. 331 may not exist.

DESCRIPTION OF SYMBOLS 1 ... Playback apparatus, 10 ... Signal processing apparatus, 11 ... Acoustic signal input apparatus, 12 ... Acoustic signal output apparatus, 20 ... Analog record needle, 30 ... Analog record, 110 ... Signal processing part, 120 Communication I / F unit 130 Storage unit 132 Volatile storage unit 134 Non-volatile storage unit 134a, 134b Signal processing program 140 Bus 210, 222, 330, 331... Addition unit, 220, 212... Subtraction unit, 211, 221... Non-linear processing unit, 213, 223 ... Multiplication unit, 310, 320 ... High-pass filter, 311, 321.

Claims (4)

A first nonlinear processing unit that nonlinearly amplifies the amplitude of the in-phase signal obtained by adding the L channel signal and the R channel signal;
A second non-linear processing unit that non-linearly amplifies the amplitude of a reverse phase signal obtained by subtracting the other from one of the L channel signal and the R channel signal;
Have
The acoustic signal processing device , wherein an amplification factor of the second nonlinear processing unit is smaller than an amplification factor of the first nonlinear processing unit . The amplitude of the in-phase signal after nonlinear amplification is limited to a first value or less,
The amplitude of the antiphase signal after nonlinear amplification is limited to a second value or less,
The acoustic signal processing apparatus according to claim 1, wherein the second value is smaller than the first value . The first nonlinear processing unit performs nonlinear amplification when the amplitude of the in-phase signal is equal to or greater than a first threshold value,
The second nonlinear processing unit performs nonlinear amplification when the amplitude of the negative-phase signal is equal to or greater than a second threshold value,
The second threshold is smaller than the first threshold
The acoustic signal processing apparatus according to claim 1, wherein A first low-pass filter that supplies a low-frequency component of the in-phase signal to the first nonlinear processing unit;
A second low-pass filter that supplies a low-frequency component of the negative-phase signal to the second nonlinear processing unit;
The acoustic signal processing apparatus according to any one of claims 1 to 3, wherein at least one of the following is included.

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