JPH06105390A - Acoustic signal reproducing device - Google Patents

Abstract

PURPOSE:To obtain an effective sound by applying tone control to an installation environment of a speaker location, a height of the speaker and a position of a listener in the acoustic signal reproduction device with a comparatively simple method. CONSTITUTION:When a sound is corrected in response to the hardness of a wall of a room in which a speaker is installed, a degree of the hardness of the wall is inputted via a means 21a to set the hardness of the wall and an acoustic processing control section 1 corrects a high frequency component of an acoustic signal via a high frequency band tone control section 8 in response to the hardness of the wall. As other embodiment of the correction as above, there may be the correction corresponding to the interval of speakers, the correction in response to the installed height of speakers, ant the correction in response to the distance between the speakers and a listener.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an audio signal reproducing device such as a stereo device, and more particularly to the position of the audio signal reproducing device and the listener (user) depending on the environment in which the audio signal reproducing device is installed. The present invention relates to an audio signal reproducing device capable of providing the listener with the most appropriate reproduced sound according to the relationship.

[0002]

2. Description of the Related Art Improvements and ingenuities have been made on how a sound recorded on a CD or a record board can be provided as a reproduced sound with high sound quality in a stereo device.
On the other hand, efforts have been made to make the environment such as the room in which the stereo device is installed have the highest sound quality.

Whether or not the highest quality sound is provided to the listener depends on the kind and nature of the reproduced sound. For example, the sound quality of a reproduced sound of classical music is different from that of a reproduced sound of music such as jazz. Therefore, in the stereo device, it is preferable to perform the reproduction processing according to the nature of the sound. Ordinary stereo equipment other than the stereo equipment used for a specific business purpose or a specific enthusiast is provided with a wide range of acoustic signal improvement measures that can be widely utilized by various users. As a method of improving such a stereo device itself, for example, means for creating a stereo effect in the stereo device, means for creating a surround effect, and the like have been taken. Further, the stereo device is provided with a means for changing the balance between the two, a means for making a high tone effective, a means for making a low tone effective, and the like which can provide an arbitrary acoustic effect according to a listener's request.

[0004]

Even if the stereo device is provided with the various functions as described above to provide more effective sound, the stereo sound heard by the listener through the speaker is not produced. Depending on the environment in which the stereo device is installed, no matter how high-performance the stereo device is prepared, if the room in which the stereo device is installed is acoustically poor, such stereo device may be used. There may be cases where a reproduced sound with sufficiently high sound quality cannot be obtained. In addition, a relatively low-priced stereo device is limited in the above-mentioned various functions and performances. In addition to this performance limitation, if the environment in which the stereo device is installed is acoustically poor, a reproduced sound with even higher sound quality cannot be obtained.

The present invention applies a sound signal reproducing device such as a stereo device to an environment in which the sound signal reproducing device is installed by a relatively simple method so that the function and performance of the sound signal reproducing device can be sufficiently obtained. The present invention aims to provide an acoustic signal reproducing device capable of providing a reproduced sound with a sound quality that the user (listener) can fully satisfy.

[0006]

[Means for Solving the Problems]
To achieve the above object, the present invention adds an artificial intelligence (AI) processing function to a sound reproducing device such as a stereo device, and takes any one of the following tone controls, that is, environmental improvement measures. (1) The reproduced acoustic signal is corrected in consideration of the reverberation such as the hardness of the wall on which the acoustic signal reproducing device is installed. (2) The reproduced sound signal is corrected in consideration of the installation height of the speaker. (3) The reproduced sound signal is corrected in consideration of the installation interval of the pair of speakers. (4) The reproduced sound signal is corrected in consideration of the distance between the pair of speakers and the positional relationship between the speakers and the listener. In the present invention, the various measures described above can be arbitrarily combined.

According to the first aspect (mode) of the present invention, the means for setting the degree of reverberation and the gain of the high frequency component of the reproduced acoustic signal are corrected according to the degree of reverberation set by the reverberation setting means. An audio signal reproducing device having a means for According to a second aspect of the present invention, means for setting the installation height of the speaker and means for correcting the gain of the low frequency component of the acoustic signal according to the height of the speaker set by the speaker height setting means. There is provided an audio signal reproducing device having: According to a third aspect of the present invention, a means for setting an interval between a pair of speakers, and a phase and a level for a sum of a right side acoustic signal and a left side acoustic signal are changed according to the set intervals of the speakers. There is provided an acoustic signal reproducing device having the new right acoustic signal and the means for generating the left acoustic signal. According to a fourth aspect of the present invention, a means for setting a distance between a pair of speakers, a means for setting a distance between a listener and an installation position of these speakers, a distance between the set speakers and a listener for the speaker. There is provided an acoustic signal reproducing device having a delay time of a right acoustic signal or a left acoustic signal output from the speaker and means for correcting the level thereof according to the distance.

Further, according to the present invention, there is provided an acoustic signal reproducing device in which various forms of the above-mentioned acoustic signal reproducing device are arbitrarily combined. As the combination, the following combinations are possible. Table-1 1st form 2nd form 3rd form 4th form 1st combination ○ ○ 2nd combination ○ ○ 3rd combination ○ ○ 4th combination ○ ○ ○ 5th combination ○ ○ ○ ○ 6th combination ○ ○ 7th combination ○ ○ 8th combination ○ ○ ○ 9th combination ○ ○

[0009]

The reproduced stereo sound is greatly influenced by the reverberation of the acoustic signal reproducing apparatus, especially the environment where the speaker is installed. For example, the degree of absorption and reflection of the sound output from the speaker varies depending on the degree of reverberation such as the hardness of the wall of the room in which the speaker is installed. In the first aspect (mode) of the present invention, the user (listener) sets the degree of reverberation in the environment in which the sound reproduction device is installed, particularly in the environment in which the speaker is installed. The sound signal correction means in the sound reproduction device corrects the gain of the high frequency component of the reproduced sound signal according to the degree of reverberation set by the reverberation setting means, and compensates the reverberation for the reproduced stereo sound.

The low frequency characteristic of reproduced stereo sound changes according to the installation height of the speaker. In a second aspect of the present invention, the user sets the installation height of the speaker, and the gain of the low frequency component of the audio signal is set in accordance with the speaker height set by the speaker height setting means in the sound reproduction device. Compensate to compensate for changes in low frequency characteristics.

The stereo sound effect varies depending on the distance between the pair of speakers. For example, if the speakers are placed close to each other, the sound becomes closer to monaural sound than stereo sound, and if the speakers are too far apart, there is a gap (a stereo sound is clearly separated and cannot be called a stereo sound. Become). According to a third aspect of the present invention, a user sets an interval between a pair of speakers, and a phase with respect to a sum of a right side audio signal and a left side audio signal is set according to an interval between the speakers set in the sound reproducing device. A new right side sound signal and a left side sound signal with different levels are generated to maintain the stereo sound effect.

The stereo sound effect varies depending on the distance between the pair of speakers and the distance between the speakers and the listener. In the fourth aspect of the present invention, the number of users is 1
The distance between the pair of speakers and the distance of the listener to the installation position of these speakers are set, and in the sound reproduction device, the right side output from the speaker according to the set speaker distance and the distance of the listener to the speaker. Stereo sound is provided by correcting the delay time of the audio signal or the left audio signal and its level.

When the above-described first to fourth modes are appropriately combined, the above-mentioned individual operations are combined.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As an audio signal reproducing device described below, a typical stereo device used by an ordinary user who is not a maniac in a room of 6-8 tatami mats is illustrated. In other words, a stereo device that allows a user who does not have the skills and knowledge of stereo devices to relatively easily adjust the environment in which the stereo device is installed to obtain stereo sound with tone control (acoustic correction). To illustrate.

FIG. 1 is a diagram illustrating the configuration of a stereo device as a first embodiment of an audio signal reproducing device of the present invention.
The stereo device of the first embodiment corrects the reverberation of the stereo device, especially the environment such as the room where the speaker is installed. The stereo device shown in FIG. 1 has a left side acoustic signal input terminal 2L to which a left side acoustic input signal AUD ₁ which is one of the stereo input signals is applied, and a right side acoustic input signal AUD _R which is the other side of the stereo input signal. The ADC for converting the left acoustic input signal AUD ₁ as an analog signal applied to the acoustic signal input section 2 composed of the right acoustic signal input terminal 2R and the left acoustic signal input terminal 2L into a digital signal.
3L, right acoustic input signal AUD _R as analog signal
Has an analog / digital conversion unit 3 including an ADC 3R for converting the signal into a digital signal. With the circuit configuration described above, the left acoustic input signal AUD ₁ and the right acoustic input signal AUD _R applied to the acoustic signal input unit 2 are converted into digital acoustic signals. The reason why the analog audio signal is converted into the digital audio signal in this manner is to adapt it to the digital signal processing described later.

The stereo apparatus further includes a dynamics processing section 4 including a left-side dynamics processing section 4L and a right-side dynamics processing section 4R, an equalization processing section 5 including a left-side equalizer 5L and a right-side equalizer 5R, and a surround processing section 6.
Have. Dynamics processing unit 4, equalization processing unit 5
The surround processing section 6 constitutes an active sound processing section 7. The dynamics processing unit 4, the equalization processing unit 5, and the surround processing unit 6 perform the same dynamics processing, equalization processing, and surround processing as conventional under the control of the sound processing control unit 1 configured by a microcomputer or the like. As such, active acoustic processing similar to the conventional one is performed. It should be noted that the stereo device of the present invention does not necessarily require the active acoustic processing, but from the viewpoint of stereo acoustic processing, an example of active acoustic processing will be described below.

The stereo device further includes a high frequency band tone control section 8 including a left high frequency tone control circuit 8L and a right high frequency tone control circuit 8R, a DAC 18L and a DAC.
18R digital / analog signal conversion unit 18,
And left speaker 19L and right speaker 19R
It has a pair of speakers 19 consisting of. Left and right active sound processing signals S6 from the surround processing unit 6
The L and S6R are applied to the digital / analog signal conversion section 18 via the high frequency band tone control section 8 and applied to the speakers 19L and 19R as left and right analog reproduced acoustic signals S18L and S18R. A pair of speakers 1
Stereo playback sound is output from 9L and 19R. In the stereo apparatus of this embodiment, the high frequency band tone control section 8 described in detail and the means 2 for inputting the hardness of the wall are described.
1a is added. With the addition of the high frequency band tone control unit 8 and the means 21a for inputting the hardness of the wall,
The processing content of the sound processing control unit 1 is modified.

In this embodiment, the degree of reverberation of the environment in which the speaker 19 is installed is set as the degree of hardness (or softness) of the wall of the room in which the speaker 19 is installed. Fig. 2 shows the hardness of the wall, the pitch of the sound, and the reverberation (attenuation) characteristics. In a room with soft walls, the sound level is high, but the sound is absorbed by the wall and immediately attenuates. On the other hand, when the wall is hard, the pitch of the sound is low, but the sound is reflected by the wall without being absorbed, and the decay time is long. In FIG. 2, the integral of sound on a soft wall is equal to the integral of sound on a hard wall. The user sets the degree of hardness of the wall in the following five stages via the means 21a for inputting the hardness of the wall. (1) Level 1: Very soft (2) Level 2: Somewhat soft (3) Level 3: Standard hardness (softness) (4) Level 4: Somewhat hard (5) Level 5: Very hard These The level of hardness can be set according to the manual of the stereo device as a guide. Alternatively, these hardness levels may be determined relative to each other by a listener who is the user of the stereo device subjectively or empirically. When one of the above hardnesses is input by the user from the means 21a for inputting the hardness of the wall, the acoustic processing control unit 1 instructs the high frequency band tone control unit 8 to make a correction curve corresponding to the hardness.

The left high frequency tone control circuit 8L and the right high frequency tone control circuit 8R in the high frequency band tone control section 8 are provided.
Has a variable gain amplifier circuit that changes the gain of the input acoustic signal based on the correction curve shown in FIG.
The left high frequency tone control circuit 8L and the right high frequency tone control circuit 8R output signals S6L, S from the surround processing section 6 based on the set reverberation level from the acoustic processing control section 1.
6R is corrected with the same characteristics. The correction in the high frequency band tone control section 8 in this example is 2.5 in this example.
The following corrections are made for high-frequency signal components above KH _Z. (A) For a very soft wall: Add signals for 2 dB. (B) In the case of a slightly soft wall, a signal of 1 dB is added. (C) Standard hardness (softness): not corrected (d) For a slightly hard wall: 1 dB signal is subtracted. (E) For a very hard wall: Subtract the signal for 2 dB. For example, when the wall is very soft, the reproduced sound is very absorbed and is corrected, so that the level of the reproduced sound is increased by 2 dB. On the other hand, if the wall is hard, the level of reproduced sound is lowered. With this correction, the reproduced sound corrected according to the hardness of the wall of the room in which the stereo device is installed is output from the left speaker 19L and the right speaker 19R by a simple method. As described above, the degree of hardness of the wall as the degree of reverberation can be easily set by a user who does not require specialized knowledge.

The degree of hardness of the wall can be considered as an example of the degree of reverberation. Therefore, it is possible to create a correction curve as illustrated in FIG. 3 in consideration of the reverberation of the environment in which the stereo device is installed and correct the reproduced sound according to the correction curve. In that case, the listener sets the degree of reverberation in the sound processing control unit 1 via the input means 21a which inputs the hardness of the wall.

FIG. 4 is a block diagram of the stereo apparatus of the second embodiment of the audio signal reproducing apparatus of the present invention. This stereo device corrects sound according to the installation height of the pair of speakers 19. Therefore, this stereo apparatus has a low frequency band tone control section 9 instead of the high frequency band tone control section 8 shown in FIG. FIG. 5 is a diagram illustrating that the propagation characteristics of sound, particularly bass, differ depending on the height of the speaker 19 from the floor 20. A high-pitched speaker 191 is arranged in the upper part of the speaker 19, and a low-pitched speaker 192 is arranged in the bottom part. The output sound from the high-pitched speaker 191 tends to go straight with a narrow directivity and has a small amount of diffused components. On the other hand, the sound output from the low-pitched speaker 192 has a wide directivity, and in addition to the straight-ahead component, there are many diffused components. Therefore, there is a considerable amount of the output sound component from the bass speaker 192 toward the floor 20, and the component is reflected by the floor 20 and reaches the listener. The sound reflected on the floor 20 toward the listener depends on the installation height of the speaker 19 with respect to the floor 20. Therefore, in order to provide better stereo reproduction sound, the stereo reproduction sound is corrected in the speaker 19 according to the height h1 or h2 from the floor 20. The low frequency band tone control unit 9 corrects the acoustic signals S6L and S6R from the surround processing unit 6 according to the correction curve illustrated in FIG.

The listener first sets the height h1 or h2 of the bottom surface of the speaker 19 from the floor 20 via the means 21b for inputting the height of the speaker. The height is not limited to the floor 20, but may be the height of the listener's ear, for example. In this embodiment, the floor 20 is used as the reference.
The standard height of the speaker 19 with respect to the floor 20 is in the range of about 0 to 2 m on the assumption that this stereo device is a general stereo device and is installed in a room of 6 to 8 tatami mats. Therefore, for example, the installation height of the speaker 19 is set as levels 1 to 5 as described below. Table-2 Height level Height standard Actual height 5 Quite high height 1.5m or more 4 Slightly high height 50cm-1.5m 3 Standard height 50cm 2 Slightly low height 20-50cm 1 Very low height Same as floor

The sound processing control section 1 inputs any one of the above-mentioned height levels from the speaker height input means 21b, and the left side low range tone control circuit 9L and the right side low range in the low frequency band tone control section 9 are inputted. In the tone control circuit 9R, the acoustic signal output from the surround processing section 6 is corrected according to the level, for example, according to the correction curve shown in FIG. Therefore, the left low-frequency tone control circuit 9L
The right side tone control circuit 9R and the right side low frequency tone control circuit 9R each have the correction curve shown in FIG. 6 and a variable gain amplification circuit capable of adjusting the gain of the input signal. Left low tone control circuit 9L
And the right low-frequency tone control circuit 9R perform the same correction. The correction curve shown in FIG. 6 corresponds to height levels 5-1 from the top. For example, when the height level is 3, the left low frequency tone control circuit 9L (the right low frequency tone control circuit 9R
The same applies) is not corrected. For high level = 5 left low-frequency tone control circuit 9L surround processing section 6 to the left sound signal S6L raising + 2 dB min over the frequency band below 300H _Z from. For high level = 1 reduces the left sound signal S6L from the left low-frequency tone control circuit 9L surround processing section 6 only -1dB over less 300H _Z. As described above, by correcting the height of the speaker 19 with respect to the floor surface 20, the listener can obtain good reproduced stereo sound without being significantly affected by the installation height of the speaker 19. In addition, since good reproduced stereo sound can be obtained without being significantly affected by the installation height of the speaker, the speaker can be installed at an arbitrary height in a limited room, and the installation condition of the stereo device is eased. As described above, the height of the speaker 19 is set in about 5 steps, and can be easily set by a user who does not have any special knowledge.

FIG. 7 is a block diagram of the stereo apparatus of the third embodiment of the audio signal reproducing apparatus of the present invention. The third embodiment relates to a stereo apparatus which eliminates the installation interval dependency of the pair of speakers 19 and provides a good reproduced sound. This stereo device is provided with a speaker width acoustic adjustment unit 10 instead of the high frequency band tone control unit 8 in the stereo device shown in FIG. The speaker width acoustic adjustment unit 10 includes a first variable gain amplifier circuit 11, a second variable gain amplifier circuit 12,
First signal addition circuit 13 and second signal addition circuit 14
Have. Each of the first variable gain amplifier circuit 11 and the second variable gain amplifier circuit 12 can also be configured as a multiplication circuit that multiplies an input signal by a correction coefficient. Normally, a pair of left speaker 19L and right speaker 19R is 50 cm to 1 m.
The speakers are installed indoors with some distance therebetween, but the distance between the left speaker 19L and the right speaker 19R differs depending on the indoor conditions. For example, if the left speaker 19L and the right speaker 19R are installed adjacent to each other with no space therebetween, monaural reproduction sound without stereo feeling is obtained. On the other hand, if the left speaker 19L and the right speaker 19R are too far apart from each other, a stereo sound in which the right side and the left side are completely separated is obtained. The stereo device of the third embodiment corrects the deterioration of the reproduced stereo sound depending on the installation interval between the left speaker 19L and the right speaker 19R. As the correction, the phase of the reproduced sound is changed to create a virtual image (virtual sound).

The user inputs left and right speakers 19L and 1L via the means 21c for inputting the speaker intervals.
Set the interval with 9R. Consider the normal room as the interval setting, and set it at the following level. Table-3 Speaker spacing level Actual spacing correction coefficient k1 Correction coefficient k2 1 Approximately 0 cm -0.25 -0.25 2 20 cm Approx. -0.125 -0.125 3 50 cm Approx. 0 0 4 1 m Approx. 0.1250 .125 5 1.5 m or more 0.25 0.25 In Table 2, the correction coefficient k1 indicates the gain of the first variable gain amplification circuit 11 (or the multiplication coefficient of the first multiplication circuit), and the correction coefficient k2 is The gain of the second variable gain amplifier circuit 12 (or the multiplication coefficient of the second multiplier circuit) is shown. When the sound processing control unit 1 inputs the speaker spacing level via the speaker spacing input means 21c, the correction factors k1 and k2 are supplied to the first variable gain amplifier circuit 11 and the correction coefficients k1 and k2 according to the levels shown in Table-3. The second variable gain amplifier circuit 12 is set.

For example, when the left speaker 19L and the right speaker 19R are adjacent to each other and the listener sets the interval level to 1 in the means 21c for inputting the interval between the speakers, the sound processing control section 1 makes the first variable gain amplification. Correction coefficient k of the circuit 11 and the second variable gain amplifier circuit 12
1 = -0.25 and k2 = -0.25 are set. As a result, the corrected acoustic signals S10L and S10R represented by the following equations are output from the first signal addition circuit 13 and the second signal addition circuit 14 in the speaker width acoustic adjustment unit 10. S10L = S6L-0.25.S6R S10R = S6R-0.25.S6L By adding signals of opposite (-) phases in this way, the sound image spreads, and the left speaker 19L and the right speaker 19R are separated from each other. Even if they are adjacent to each other, a stereo reproduction sound based on a virtual sound can be obtained. Further, when the listener sets the interval level to 5 in the means 21c for inputting the interval of the speaker, the acoustic processing control unit 1 causes the correction coefficient k1 = of the first variable gain amplifier circuit 11 and the second variable gain amplifier circuit 12 to be equal. 0.25 and k2 = 0.25 are set. As a result, the corrected acoustic signals S10L and S10R represented by the following equations are output from the first signal addition circuit 13 and the second signal addition circuit 14 in the speaker width acoustic adjustment unit 10. S10L = S6L + 0.25 / S6R S10R = S6R + 0.25 / S6L By adding positive (+) phase signals respectively, even if the left speaker 19L and the right speaker 19R are considerably separated, a gap close to monaural There is no stereo playback sound. Further, when the listener sets the interval level to 3 in the means 21c for inputting the interval of the speaker, the sound processing control unit 1 causes the sound processing control unit 1 to correct the correction coefficient k of the first variable gain amplifier circuit 11 and the second variable gain amplifier circuit 12.
Set 1 = 0 and k2 = 0. As a result, the first signal addition circuit 13 and the second signal addition circuit 13 in the speaker width acoustic adjustment unit 10
Acoustic signal S10 that is not corrected from the signal adding circuit 14 of
L and S10R are output. That is, in this example, the stereo device is designed based on the case where the left speaker 19L and the right speaker 19R are installed at a distance of about 50 cm. The same applies to other spacing levels.

In the above example, the interval between the left speaker 19L and the right speaker 19R is set as a rough level, but a specific interval is set as a numerical value from the means 21c for inputting the speaker interval. Good. In that case, the sound processing control unit 1 stores data indicating the relationship between the interval and the correction coefficient, and the correction coefficient is picked up according to the numerical value indicating the interval to correct the reproduced stereo sound as described above. You can

FIG. 8 is a block diagram of a stereo apparatus as a fourth embodiment of the sound reproducing apparatus of the present invention. The stereo device of the fourth embodiment corrects the reproduced stereo sound signal in consideration of the position of the speaker and the position of the listener. The stereo apparatus shown in FIG. 8 is provided with an acoustic signal delay / level adjusting section 16 instead of the high frequency band tone control section 8 of the stereo apparatus shown in FIG. The acoustic signal delay / level adjusting unit 16 includes a left delay circuit 16L1 and a left variable amplification circuit 1
6L2, right delay circuit 16R1, right variable amplification circuit 16
Has R2.

FIG. 9 is a diagram illustrating the position (spacing) between the left speaker 19L and the right speaker 19R and the distance of the listener to the speaker. In this example, the room is 3mx
The speaker 19 is installed in a room of 3 m square, and the listener has left speaker 19L and right speaker 19 in this room.
The case of listening to the reproduced stereo sound from R will be illustrated. The left speaker 19L and the right speaker 19 are at the positions shown by the solid lines.
When R is arranged, the stereo effect is different when the listener is in zone Z22 and when it is in zone Z31. Also, even if there is a listener in the same zone Z22, the stereo effect is different when the left speaker 19L and the right speaker 19R are at the positions shown by the solid lines and when they are at the positions shown by the broken lines. As illustrated in FIG. 10, when the listener is in the zone Z22, the left speaker 19
Since the L and the right speaker 19R are located at substantially the same position, correction may not be performed in the stereo device, but when the listener is in the zone Z31, the left speaker 19L.
The balance is lost unless the position is virtually retracted by the distance D3 to the position indicated by the broken line. In order to balance the left speaker 19L and the right speaker 19R, the left speaker 19
When the speaker is moved backward from the position indicated by the solid line to the position indicated by the broken line, the sound output from the left speaker 19L is delayed by the distance D3, and the distance D3
This is equivalent to the level of the reproduced speaker sound being lowered by the distance.

The listener sets his own position (zone) through the means 21d for inputting the position of the listener. In response to this zone setting, the sound processing control unit 1 determines, based on a preset interval between the left speaker 19L and the right speaker 19R, for example, 50 cm as a standard interval.
The delay time in the left-side delay circuit 16L1 or the right-side delay circuit 16R1 is determined, the delay time is set in the left-side delay circuit 16L1 or the right-side delay circuit 16R1, and the gain of the variable amplifier circuit in the subsequent stage of the delayed delay circuit is delayed. Adjust its gain to increase with time. The delay time is determined by the sound processing control unit 1 as follows, for example. The sound processing control unit 1 calculates the distance between the left speaker 19L and the right speaker 19R and the distance between these speakers and the listener, and determines one speaker located near the listener as a distance between the listener and the other speaker. The retreat distance D3 for virtually retreating to a position substantially equal to is determined by calculation. The sound processing control unit 1 further calculates the time during which the sound propagates through the receding distance D3 to determine the left delay circuit 16L1 or the right delay circuit 1
The delay time is 6R1. Further, the sound processing control unit 1 increases the gain of the left side variable amplification circuit 16L2 or the right side variable amplification circuit 16R2 so as to compensate for the sound attenuated by the backward distance. By adjusting the phase and level in the sound signal delay / level adjusting unit 16, the listener can listen to the reproduced sound from the left speaker 19L and the right speaker 19R in a balanced manner regardless of the zone.

The delay time and the gain depend on the distance between the pair of speakers and the distance between the speakers and the listener. Therefore, the left speaker 19L and the right speaker 1
If the distance from 9R is different, the above-mentioned retreat distance D3 is also different. As described above, the distance between the left speaker 19L and the right speaker 19R is, for example, 50 cm as a standard distance.
However, the delay time and gain described above can be calculated using the speaker interval setting data described in the third embodiment. As a result, it is possible to obtain an effective reproduced stereo sound that is independent of the distance between the pair of speakers and the distance between the speakers and the listener.

A modification of the fourth embodiment will be described. In the audio signal delay / level adjusting unit 16 shown in FIG. 8, the left side delay circuit 16L1 and the left side variable amplification circuit 16L2, or the right side delay circuit 16R1 and the right side variable amplification circuit 1
It is also possible to provide only one of 6R2 and omit the other circuit. For example, in the distance (position) relationship between the speaker and the listener shown in FIG. 9, when the listener hears only in one zone, for example, Z11, Z21, Z31 side, the right delay circuit 16R1 and the right variable amplification circuit 16R2 becomes unnecessary.

The above-described first to fourth embodiments have independent functions and effects. Therefore, it is possible to appropriately combine these embodiments. In the present invention, all combinations are possible, as listed below. Table-4 Combination 1st Example 2nd Example 3rd Example 4th Example 1 ○ ○ (Reverberation correction and speaker height correction) 2 ○ ○ (Reverberation correction and speaker interval correction) 3 ○ ○ (Reverberation Correction and speaker distance correction for listener position) 4 ○ ○ (Speaker height and distance correction) 5 ○ ○ (Speaker height and speaker distance correction for listener position) 6 ○ ○ (Speaker distance and listener 7 ○ ○ ○ (Speaker distance and speaker distance correction to the listener position) 8 ○ ○ ○ ○ (Reverberation correction, speaker height correction, speaker distance and listener position to speaker position correction) 9) ○ ○ ○ (Speaker height correction, speaker distance correction for speaker spacing and listener position)

FIG. 11 is a block diagram of a stereo device when the first to fourth embodiments are combined. This stereo device comprises an audio signal input unit 2, an analog / digital conversion unit 3, a dynamics processing unit 4, an equalization processing unit 5, a surround processing unit 6, a high frequency band tone control unit 8 according to the first embodiment, and a second embodiment. Low frequency band tone control section 9 relating to the third embodiment, speaker width sound adjusting section 1 relating to the third embodiment
0, acoustic signal phase / level adjusting unit 1 according to the fourth embodiment
6, a digital / analog signal converter 18, a speaker 19, a sound processing controller 1, and means 21 for inputting environmental conditions. The means 21 for inputting environmental conditions is the means 21a for inputting the hardness of the wall, the means 21b for inputting the height of the speaker, and the means 2 for inputting the distance between the speakers.
1c and means 21d for inputting the position of the listener are integrated. The sound processing control unit 1 includes the above-mentioned first to first
The processing of the fourth embodiment is performed. Therefore, according to this stereo device, all the above-mentioned corrections can be performed.
The environment setting described above, such as the setting of the hardness of the room and the setting of the speaker interval, can be easily set even by a user who does not have specialized knowledge. In particular, the environment setting described above does not set the speaker spacing by an absolute value, for example, so if the environment in which the stereo device is installed does not provide sufficient sound quality at the set speaker spacing, the next level is set. The advantage is that you can empirically determine the most suitable conditions for the environment in which the stereo device is installed by changing the setting. Of course, the distance between the speakers can be set accurately, for example, in cm.

Although the above-described embodiment has been illustrated with respect to a stereo device used in a relatively small room, the audio signal reproducing device of the present invention is not limited to such an embodiment and can be applied to other audio signal reproducing devices. Further, in order to facilitate the setting of the above-mentioned environmental conditions, an example in which the level is set as a stepwise level or a relative value is shown, but for example, the setting of the speaker interval, the setting of the speaker height, etc. It can also be set with any numerical value.

In the above embodiment, the example in which the acoustic signal to be corrected is subjected to active acoustic processing in the dynamics processing section 4, the equalization processing section 5 and the surround processing section 6 has been shown. ， It can be applied with or without such active acoustic processing.

[0037]

According to the audio signal reproducing device of the present invention, the best reproduced sound can be provided according to the environment in which the audio signal reproducing device is installed. Corrections for this purpose include speaker interval correction, speaker height correction, reverberation correction, speaker interval and listener position with respect to the speaker, etc. These individual corrections can be made and combined appropriately. Correction can also be performed. By performing the correction adapted to the environment as described above, the restriction for installing the audio signal reproducing device is reduced, and the labor for preparing the environment for installing the audio reproducing device is reduced. Furthermore, the above-mentioned correction of the present invention can be easily performed by a normal user who is not an expert so as to adapt to the environment at that time.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a first embodiment of an audio signal reproducing device of the present invention.

FIG. 2 is a diagram illustrating acoustic characteristics of the acoustic signal reproducing device shown in FIG.

FIG. 3 is a graph showing a high frequency region acoustic signal correction characteristic curve in the high frequency band tone control unit shown in FIG.

FIG. 4 is a configuration diagram of a second embodiment of an audio signal reproducing device of the present invention.

5 is a diagram showing the relationship between the position of a speaker and the acoustic effect in the audio signal reproducing device shown in FIG.

6 is a graph showing a low frequency region acoustic signal correction characteristic curve in the low frequency band tone control unit shown in FIG.

FIG. 7 is a configuration diagram of a third embodiment of an audio signal reproducing device of the present invention.

FIG. 8 is a configuration diagram of a fourth embodiment of the audio signal reproducing device of the invention.

9 is a diagram illustrating a relationship between a listener position and a speaker position in the audio signal reproduction device shown in FIG.

10 is a diagram illustrating acoustic correction according to the listener position in the acoustic signal reproduction device shown in FIG.

FIG. 11 is a configuration diagram of a fifth embodiment of an audio signal reproducing device of the present invention.

[Explanation of symbols]

 1 .. Acoustic processing control unit 2 .. Acoustic signal input unit 2L .. Left acoustic signal input terminal 2R .. Right acoustic signal input terminal 3 .. Analog / digital conversion unit 4 .. Dynamics processing unit 5 .. Equalization processing unit 6-Surround processing section 7-Active sound processing section 8-High frequency band tone control section 8L-Left high frequency tone control circuit 8R-Right high frequency tone control circuit 9-Low frequency band tone control section 9L・ ・ Left side low frequency tone control circuit 9R ・ ・ Right side low frequency tone control circuit 10 ・ ・ Speaker width acoustic adjustment section 11 ・ ・ First variable gain amplification circuit 12 ・ ・ Second variable gain amplification circuit 13 ・ ・ First Signal adder circuit 14 ··· Second signal adder circuit 16 ·· Acoustic signal delay / level adjustment unit 16L1 ·· Left side delay circuit 16R1 ·· Right side delay circuit 16L2 ··· Left variable amplification circuit 16R2 ・ ・ Right side variable amplification circuit 18 ・ ・ Digital / analog signal converter 19 ・ ・ Speaker unit 19L ・ ・ Left side speaker 19R ・ ・ Right side speaker 21 ・ ・ Means for inputting environmental conditions 21a ・ ・ Input wall hardness Means 21b .. means for inputting speaker height 21c .. means for inputting speaker spacing 21d .. means for inputting listener's position

Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI Technical display location H04S 1/00 D 8421-5H 7/00 Z 8421-5H

Claims (20)

[Claims] 1. An audio signal reproducing apparatus having means for setting a degree of reverberation, and means for correcting a gain of a high frequency component of a reproduced acoustic signal according to the degree of reverberation set by the reverberation setting means. 2. The degree of reverberation is set via the degree of reverberation setting means as hardness of a wall of a room in which a speaker is installed, and means for correcting the gain of a high frequency component of the reproduced acoustic signal comprises: The audio signal reproducing apparatus according to claim 1, further comprising a signal amplifying unit that corrects a gain of a high frequency component of the reproduced audio signal according to a gain correction curve defined corresponding to the set hardness. 3. A means for setting the installation height of the speaker, and a signal correction means for correcting the gain of the low frequency component of the acoustic signal according to the height of the speaker set by the speaker height setting means. Sound signal reproduction device. 4. The signal correction means for correcting the gain of the low frequency component of the reproduced acoustic signal is a low frequency component of the reproduced acoustic signal according to a gain correction curve defined corresponding to the set installation height of the speaker. 4. The audio signal reproducing apparatus according to claim 3, further comprising a signal amplifying unit that corrects the gain of. 5. A means for setting an interval between a pair of speakers, and a new right side in which a phase and a level with respect to a sum of a right side audio signal and a left side audio signal are changed according to the set speaker interval. An acoustic signal reproducing device having an acoustic signal and a means for generating a left acoustic signal. 6. The means for correcting the phase and the level comprises a first multiplication circuit for multiplying the right side acoustic signal by a first correction coefficient, and a first addition circuit for adding the multiplication result to the left side acoustic signal. A second multiplication circuit for multiplying the left side acoustic signal by a second correction coefficient, and a second addition circuit for adding the multiplication result to the right side acoustic signal, wherein the first correction coefficient and the second correction coefficient The audio signal reproducing device according to claim 5, wherein is defined by an installation interval of the speaker. 7. A means for setting a distance between a pair of speakers, a means for setting a distance of a listener with respect to an installation position of these speakers, and the speaker according to the distance between the set speakers and the distance of the listener with respect to the speaker. A sound signal reproducing device having a delay time of a right side sound signal or a left side sound signal output from the device and means for correcting the level thereof. 8. The delay time and level correcting means is a delay time equivalent to virtually retracting one speaker defined according to a distance between a pair of speakers and a distance of a listener to these speakers. The audio signal reproducing apparatus according to claim 7, further comprising: at least one delay circuit that delays the audio signal only, and at least one signal amplifier circuit that corrects the gain of the delayed audio signal according to the delay time. 9. The means for correcting the delay time and level comprises a first delay circuit for delaying the first acoustic signal, and a first delay circuit for changing the gain of the acoustic signal delayed by the first delay circuit. A signal amplifying circuit, a second delay circuit provided in parallel with the first delay circuit, and a second signal amplifying circuit provided in parallel with the first amplifier circuit. Position of the first speaker is virtually retracted so that the first speaker located at a close position is substantially the same distance as the second speaker located at a position far from the listener, and the first speaker is set to the retracted distance. 8. The audio signal reproducing apparatus according to claim 7, wherein one of the delay circuits delays the audio signal for a corresponding time, and one of the signal amplifier circuits corrects a gain corresponding to a gain that is attenuated at the backward distance. 10. The acoustic signal reproducing device according to claim 1, wherein the correction is performed on an acoustic signal subjected to active acoustic processing. 11. The acoustic signal reproducing device according to claim 1, wherein the corrected stereo acoustic signal is output via a pair of speakers. 12. The method according to claim 3, further comprising means for setting the degree of reverberation, and signal correcting means for correcting the gain of the high frequency component of the reproduced acoustic signal according to the degree of reverberation set by the reverberation setting means. The acoustic signal reproducing device described. 13. The apparatus according to claim 5, further comprising: a means for setting a degree of reverberation; and a signal correcting means for correcting a gain of a high frequency component of the reproduced acoustic signal according to the degree of reverberation set by the reverberation setting means. The acoustic signal reproducing device described. 14. A method for setting the degree of reverberation, and a signal correcting means for correcting the gain of the high frequency component of the reproduced acoustic signal according to the degree of reverberation set by the reverberation setting means. The acoustic signal reproducing device according to any one of the above. 15. A method for setting the degree of reverberation, and a signal correction means for correcting the gain of the high frequency component of the reproduced acoustic signal according to the degree of reverberation set by the reverberation setting means. The acoustic signal reproducing device according to any one of the above. 16. A method for setting the degree of reverberation, and a signal correction means for correcting the gain of the high frequency component of the reproduced acoustic signal according to the degree of reverberation set by the reverberation setting means. The acoustic signal reproducing device according to any one of the above. 17. A means for setting the installation height of the speaker, and a signal correction means for correcting the gain of the low frequency component of the acoustic signal according to the height of the speaker set by the speaker height setting means. The audio signal reproducing device according to claim 5. 18. A means for setting the installation height of the speaker, and a signal correction means for correcting the gain of the low frequency component of the acoustic signal according to the height of the speaker set by the speaker height setting means. The acoustic signal reproducing device according to claim 7. 19. A unit for setting an installation height of a speaker, and a signal correction unit for correcting a gain of a low frequency component of an acoustic signal according to the height of the speaker set by the speaker height setting unit. The audio signal reproducing device according to claim 5. 20. A means for setting an interval between a pair of speakers, and a new right side in which the phase and the level with respect to the sum of the right side acoustic signal and the left side acoustic signal are changed according to the set speaker spacing. The acoustic signal reproducing device according to claim 7, further comprising a unit that generates an acoustic signal and a left acoustic signal.