JP2010087783A - Acoustic device, acoustic signal processing method, acoustic signal processing program and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To appropriately sort a C channel signal into speakers other than a center speaker while respecting an intent of a producer of the sound content. <P>SOLUTION: A correlation evaluation part 211L calculates a correlation coefficient between the C channel signal and an L channel signal. In addition, a correlation evaluation part 211R calculates a correlation coefficient between the C channel signal and an R channel signal. Continuously, a sorting coefficient determination part 212A determines a first sorting coefficient of a separation channel signal SCD<SB>C</SB>into the C channel and a second sorting coefficient of the separation channel signal SCD<SB>C</SB>into the L channel and the R channel based on the calculated correlation coefficient. Then, a sorting processing part 215A sorts the separation channel signal SCD<SB>C</SB>into the C channel, the L channel, and the R channel according to the first and second determined sorting signals. Sound corresponding to channel processing signals PCD<SB>C</SB>-PCD<SB>R</SB>generated in this way is reproduced and output from six speakers. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an acoustic device, an acoustic signal processing method, an acoustic signal processing program, and a recording medium on which the acoustic signal processing program is recorded.

  2. Description of the Related Art Conventionally, acoustic devices that reproduce audio content and output reproduced audio from speakers have been widely used. As a result, even in home spaces and vehicle spaces, it has become possible to enjoy reproduced sound full of realism by sound reproduction by a multi-channel surround system such as a 5.1 channel configuration.

  By the way, in many of the multi-channel surround systems, a center channel (hereinafter referred to as “C channel”) is included. Since the center speaker prepared for such a C channel is usually arranged at a position in the vicinity of the video display device with no space, it is often forced to be a speaker having a small aperture. Therefore, the center speaker is particularly low in comparison with the left speaker corresponding to the left channel (hereinafter referred to as “L channel”) and the right speaker corresponding to the right channel (hereinafter referred to as “R channel”). There are many cases where the reproduction ability is low.

  Therefore, as a configuration that can compensate for the low reproduction capability of the center speaker, a technique for distributing a part of the C channel signal from the sound source to the right speaker and the left speaker has been proposed (see Patent Documents 1 and 2). Hereinafter, they are referred to as “conventional examples 1 and 2”. Here, in the technique of Conventional Example 1, the low-frequency component and the high-frequency component of the C channel signal are extracted, and only the high-frequency component is supplied to the center speaker. Further, the bass component and the L channel signal are combined and supplied to the left speaker, and the bass component and the R channel signal are combined and supplied to the right speaker ([0068 in Patent Document 1]. ] To [0091] and FIG.

  In the technique of Conventional Example 2, the C channel signal is pseudo-stereo and a pseudo L channel signal and a pseudo R channel signal are generated. Then, the pseudo L channel signal and the L channel signal from the sound source are combined and supplied to the left speaker, and the pseudo R channel signal and the R channel signal from the sound source are combined and supplied to the right speaker. It has become. In the technique of Conventional Example 2, two types of center speakers, a center left speaker and a center right speaker, are provided. The pseudo L channel signal component and the pseudo R channel signal supplied to the left speaker and the pseudo R channel signal supplied to the right speaker at a predetermined ratio larger than the pseudo L channel signal and the center R It is supplied to the speaker.

JP 2003-61198 A Japanese Patent Laid-Open No. 10-285698

  In the technique of Conventional Example 1 described above, the low-frequency component of the C channel signal is reproduced and output only from the left speaker and the right speaker. In the technique of Conventional Example 2, the pseudo stereo signal of the C channel signal is reproduced and output from the left speaker and the right speaker at a predetermined ratio with respect to the reproduction output level from the center left speaker and the center right speaker. In other words, regardless of the relationship between the C channel signal, the L channel signal, and the R channel signal in the audio content to be reproduced, the C channel signal that is scheduled to be reproduced and output from one or two center speakers. Audio corresponding to the predetermined frequency band component is reproduced and output from the left speaker and the right speaker at a fixed ratio.

  As a result, in the techniques of the conventional examples 1 and 2, even if the C channel signal corresponds to an original sound with respect to the L channel signal and / or the R channel signal, the left channel is always left at a fixed ratio. Reproduction is output from the speaker and the light speaker. For this reason, the sound image of the audio corresponding to the C channel signal intended to be reproduced and output only from the center speaker is wider than that reproduced and output only from the center speaker. become. Also, when the C channel signal is distributed to speakers arranged at asymmetric positions with the center speaker as the center, the sound image localization corresponding to the C channel signal is greatly deviated from the intention of the audio content producer. There is also a possibility.

  Therefore, there is a need for a technology that can reasonably compensate for the lack of playback capability of the center speaker while respecting the intention of the producer of audio content. Meeting this demand is one of the problems to be solved by the present invention.

  The present invention has been made under the above circumstances, and an audio device and an audio signal that can appropriately distribute a C channel signal to speakers other than the center speaker while respecting the intention of the producer of audio content An object is to provide a processing method.

  The invention according to claim 1 outputs sound from a plurality of speakers including a center speaker installed corresponding to the center channel signal based on a plurality of channel signals including a center channel signal supplied from a sound source. A sound device, comprising: a first frequency band component of the center channel signal; and each of the first frequency band components of at least one other channel signal other than the center channel signal in the plurality of channel signals. Detecting means for detecting a correlation; based on a detection result by the detecting means, a distribution coefficient to each of the center speaker and the speaker corresponding to the other channel signal of the component of the second frequency band of the center channel signal Determining means for determining; according to a determination result by the determining means; An acoustic device, characterized in that it comprises; generating means for generating an acoustic signal supplied to each speaker corresponding to mosquitoes and the other channel signal.

  According to a seventeenth aspect of the present invention, based on a plurality of channel signals including a center channel signal supplied from a sound source, sound is output from a plurality of speakers including a center speaker installed corresponding to the center channel signal. An acoustic signal processing method, comprising: a first frequency band component of the center channel signal; and a first frequency band component of at least one other channel signal other than the center channel signal in the plurality of channel signals. A detection step for detecting a correlation between the center channel signal and a second frequency band component of the center channel signal to each of the center speaker and the speaker corresponding to the other channel signal based on a detection result in the detection step. A determination step for determining a coefficient; according to a determination result in the determination step; An acoustic signal processing method characterized by comprising a; a generating step of generating an acoustic signal supplied to each of the speakers corresponding to the center speaker and the other channel signal.

  According to an eighteenth aspect of the present invention, there is provided an acoustic signal processing program characterized by causing an arithmetic means to execute the acoustic signal processing method according to the seventeenth aspect.

  The invention described in claim 19 is a recording medium in which the acoustic signal processing program according to claim 18 is recorded so as to be readable by a calculation means.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the following description and drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

[First Embodiment]
First, a first embodiment of the present invention will be described with reference to FIGS. In the first embodiment, a case where the 5.1 channel surround system is employed will be described as an example.

<Configuration>
FIG. 1 is a block diagram illustrating a schematic configuration of an acoustic device 100A according to the first embodiment.

  As shown in FIG. 1, the acoustic device 100A includes a signal processing unit 110A and a sound source unit 120.

The acoustic device 100A includes a speaker 130 _C , a speaker 130 _L , a speaker 130 _R , a speaker 130 _SL , a speaker 130 _SR, and a speaker 130 _SW .

Here, the speaker 130 _C is a center speaker (hereinafter referred to as “C speaker”), the speaker 130 _L is a left speaker (hereinafter referred to as “L speaker”), and the speaker 130 _R is a right speaker (hereinafter referred to as “L speaker”). , Called "R speaker"). The speaker 130 _SL is a surround left speaker (hereinafter referred to as “SL speaker”), the speaker 130 _SR is a surround right speaker (hereinafter referred to as “SR speaker”), and the speaker 130 _SW is a subwoofer speaker (hereinafter referred to as “SR speaker”). , Referred to as “SW speaker”).

  Furthermore, the acoustic device 100 </ b> A includes a display unit 140 and an operation input unit 150.

The signal processing unit elements other than 110A 120,130 _C ~130 _SW, 140,150 are connected to the signal processing unit 110A.

The signal processing unit 110A processes the content data CTD from the sound source unit 120, and supplies the audio output signals AOS _{C to} AOS _SW , which are the processing results, to the speakers 130 _{C to} 130 _sw . Details of the signal processing unit 110A will be described later.

  The sound source unit 120 outputs content data CTD under the control of the read command CSL from the signal processing unit 110A. In the first embodiment, the content data CTD carries 6-channel signals in the 5.1 channel surround system.

That is, the content data CTD carries a center channel (hereinafter referred to as “C channel”) signal, a left channel (hereinafter also referred to as “L channel”) signal, and a right channel (hereinafter also referred to as “R channel”) signal. ing. Further, the content data CTD includes a surround left channel (hereinafter referred to as “SL channel”) signal, a surround right channel (hereinafter also referred to as “SR channel”) signal, and a subwoofer channel (hereinafter also referred to as “SW channel”) signal. Is responsible. The j (j = C to SW) channel signal is a signal intended to be reproduced and output from the j speaker 130 _j by the producer of the audio content.

  For example, when the audio device 100A is a device that reproduces audio content recorded on a recording medium such as a DVD (Digital Versatile Disk), the sound source unit 120 reads the audio content from the recording medium. Is provided. When the audio device 100A is a device that reproduces audio content acquired by receiving broadcast waves, the sound source unit 120 includes content extracting means for extracting audio content data from the broadcast wave reception results. Become.

  The content data signal CTD output from the sound source unit 120 is supplied to the signal processing unit 110A.

Each of the speakers 130 _{C to} 130 _SW reproduces and outputs music in accordance with the audio output signals AOS _{C to} AOS _SW sent from the signal processing unit 110A. Note that the L speaker and the R speaker are arranged at symmetrical positions with the arrangement position of the C speaker as the center.

  The display unit 140 includes, for example, (i) a display device such as a liquid crystal panel, an organic EL (Electro Luminescence) panel, a PDP (Plasma Display Panel), and (ii) display control data sent from the signal processing unit 110A. The display unit 140 includes a display controller such as a graphic renderer that controls the entire display unit 140, and (iii) a display image memory that stores display image data. The display unit 140 displays operation guidance information and the like according to the display data IMD from the signal processing unit 110A.

  The operation input unit 150 includes a key unit provided in the main body of the acoustic device 100A and / or a remote input device including the key unit. Here, as a key part provided in the main body part, a touch panel provided in a display device of the display unit 140 can be used. In addition, it can replace with the structure which has a key part, or can also employ | adopt the structure input with a sound using a voice recognition technique in combination.

  When the user operates the operation input unit 150, the operation content of the acoustic device 100A is set. For example, an input by a user such as an audio content reproduction command is performed using the operation input unit 150. Such input contents are sent as operation input data IPD from the operation input unit 150 to the signal processing unit 110A.

Next, the signal processing unit 110A will be described. As described above, the signal processing unit 110A processes the content data CTD from the sound source unit 120, and supplies the audio output signals AOS _{C to} AOS _SW , which are the processing results, to the speakers 130 _{C to} 130 _sw. The overall control of the acoustic device 100A is controlled. The signal processing unit 110A includes a control processing unit 111, a channel separation unit 112, a signal processing unit 113A, and an analog processing unit 114.

  The control processing unit 111 controls the sound source unit 120, the display unit 140, and the analog processing unit 114 based on a command input to the operation input unit 150. Details of the control processing unit 111 will be described later.

The channel separation unit 112 receives the content data CTD from the sound source unit 120. Then, the channel separator 112 develops the content data CTD and separates it into six separated channel signals SCD _{C to} SCD _SW corresponding to the _{C to SW} channels in the 5.1 channel surround system. The separated channel signals SCD _{C to} SCD _SW separated in this way are sent to the signal processing unit 113A.

The above signal processing section 113A receives the separated channel signal SCD _C ~SCD _SW, generates a channel processing signals PCD _C ~PCD _SW corresponding to the speaker 130 _C to 130 DEG _SW. As shown in FIG. 2, the signal processing unit 113A having such a function includes a signal allocating unit 210A and a delay applying unit 220 as a part of the synchronization adjusting unit.

Incidentally, the separation channel signal SCD _C ~SCD _R is sent to the signal selector 210A. Separated channel signals SCD _{SL to} SCD _SW are sent to delay applying section 220.

Additional signal selector 210A generates a channel processing signals PCD _C ~PCD _R from the separation channel signal SCD _C ~SCD _R. As shown in FIG. 3, the signal distribution unit 210A includes correlation evaluation units 211L and 211R as detection means, and a distribution coefficient determination unit 212A as determination means. The signal distribution unit 210A includes a delay adding unit 213A as a part of the synchronization adjustment unit and a distribution processing unit 215A as a generation unit.

Correlation evaluation part 211L described above, by calculating a correlation coefficient between the separation channel signal SCD _C and the separation channel signal SCD _L, to evaluate the correlation between the two signals. The calculated correlation coefficient has a value in the range of “−1” to “1”. Here, when there is a strong correlation in the reverse phase, the correlation coefficient approaches “−1”. When there is no correlation, the correlation coefficient is “0”. Further, when there is a strong correlation in the same phase, the correlation coefficient approaches “1”. The correlation coefficient calculated in this way is sent to the distribution coefficient determination unit 212A.

Correlation evaluation unit 211R described above, by calculating a correlation coefficient between the separation channel signal SCD _C and the separation channel signal SCD _R, to evaluate the correlation between the two signals. The calculated correlation coefficient is calculated in the same range as in the correlation evaluation unit 211L described above, corresponding to the mode of correlation between both signals. The correlation coefficient calculated in this way is sent to the distribution coefficient determination unit 212A.

Based on the two correlation coefficients from the correlation evaluation unit 211L and the correlation evaluation unit 211R, the distribution coefficient determination unit 212A described above assigns the distribution coefficient to the C channel, L channel, and R channel of the separated channel signal SCCD _C. decide. In the first embodiment, the distribution coefficient determination unit 212A is configured to use the first distribution coefficient for the C channel based on the average value (ACR) of the two correlation coefficients from the correlation evaluation unit 211L and the correlation evaluation unit 211R. (DC) and a common second distribution coefficient (DLR) as a distribution coefficient to the L channel and the R channel are determined by a predetermined algorithm.

In determining the first distribution coefficient (DC), the distribution coefficient determination unit 212A determines that the correlation is high when the correlation between the separation channel signal SCD _C and the separation channel signals SCD _L and SCD _R is positive. The first distribution coefficient (DC) is determined so as to be smaller as it is evaluated, that is, as the average value (ACR) of the correlation coefficient becomes larger in the range of “0” to “1”. On the other hand, when the correlation between the separated channel signal SCD _C and the separated channel signals SCD _L and SCD _R is negative, the distribution coefficient determination unit 212A determines that the correlation is higher, that is, the correlation coefficient The first distribution coefficient (DC) is determined so that the average value (ACR) decreases as the average value (ACR) decreases in the range of “−1” to “0”.

In determining the second distribution coefficient (DLR), the distribution coefficient determination unit 212A has a high correlation when the correlation between the separated channel signal SCCD _C and the separated channel signals SCD _L and SCD _R is positive. That is, the second distribution coefficient (DLR) is determined so as to increase as the average value (ACR) of the correlation coefficient increases in the range of “0” to “1”. On the other hand, when the correlation between the separated channel signal SCD _C and the separated channel signals SCD _L and SCD _R is negative, the distribution coefficient determination unit 212A determines that the correlation is higher, that is, the correlation coefficient The second distribution coefficient (DLR) is determined so that the average value (ACR) decreases as the average value (ACR) decreases in the range of “−1” to “0”.

  The predetermined algorithm is determined in advance by experiment, simulation, experience, or the like.

An example of the relationship between the average value (ACR) of the correlation coefficient and the first distribution coefficient (DC) is shown in FIG. In FIG. 4A, as the average value (ACR) changes from “−1” to “0”, the first distribution coefficient (DC) changes from the minimum value DC _MIN (≧ 0) to the maximum value DC _MAX. An example in which the first distribution coefficient (DC) monotonously decreases from the maximum value DC _MAX to the minimum value DC _MIN as the average value (ACR) changes from “0” to “1”. It is shown.

FIG. 4B shows an example of the relationship between the correlation coefficient average value (ACR) and the second distribution coefficient (DLR). In FIG. 4B, the second distribution coefficient (DLR) monotonously increases from the minimum value DLR _MIN to “0” as the average value (ACR) changes from “−1” to “0”. In addition, an example is shown in which the second distribution coefficient (DLR) monotonously increases from “0” to the maximum value DLR _MAX as the average value (ACR) changes from “0” to “1”.

  Returning to FIG. 3, the determined first distribution coefficient (DC) and second distribution coefficient (DLR) are sent to the distribution processing unit 215A.

Additional delay imparting section 213A is provided with three separate delay imparting section corresponding to each of the separation channel signal SCD _C ~SCD _R. Then, the delay imparting section 213A includes a delay separation channel signal SCD _C ~SCD _R, by the amount of offset timing differences between the first and second sorting coefficient determined, the respective separation channel signal SCD _C ~SCD _R Let That is, the delay imparting section 213A, the correlation evaluating unit 211L, by an amount of processing time in 211R and distribution coefficient determining unit 212A, delaying the respective separation channel signal SCD _C ~SCD _R. The separated channel signals SCD _{C to} SCD _R thus provided with the delay are sent to the distribution processing unit 215A.

The distribution processing unit 215A is based on the separated channel signals SCD _{C to} SCD _R to which the delay is added by the delay adding unit 213A and the first and second distribution coefficients determined by the distribution coefficient determining unit 212A. The channel processing signals PCD _{C to} PCD _R are generated. The distribution processing unit 215A includes a multiplication unit 216C as a first multiplication unit and multiplication units 216L and 216R as a second multiplication unit. Further, the distribution processing unit 215A includes addition units 217L and 217R as addition means.

It said multiplier 216C receives the separated channel signal SCD _C delay imparted by the delay imparting section 213A. Then, multiplying unit 216C multiplies the first sorting coefficient determined by the distribution coefficient determining unit 212A to the reception signal, it generates a channel processing signals PCD _C. The generated channel processing signal PCD _C is sent to the analog processing unit 114.

It said multiplier 216L receives a separated channel signal SCD _C delay imparted by the delay imparting section 213A. Then, multiplication section 216L multiplies the received signal by the second distribution coefficient determined by distribution coefficient determination section 212A. The multiplication result signal is sent to the addition unit 217L.

It said multiplier 216R receives the separated channel signal SCD _C delay imparted by the delay imparting section 213A. Then, multiplication section 216R multiplies the received signal by the second distribution coefficient determined by distribution coefficient determination section 212A. The multiplication result signal is sent to the adder 217R.

It said adder 217L receives the signal of the multiplication result of the separation channel signal SCD _L and multiplying unit 216L delay imparted by the delay imparting section 213A. Then, the addition unit 217L adds the two signals and generates a channel processing signals PCD _L. The generated channel processed signal PCD _L was is sent to the analog processing unit 114.

It said adder 217R receives a signal of the multiplication result by the separation channel signal delay imparted by the delay imparting section 213A SCD _R and multiplying unit 216R. Then, the addition unit 217R adds the two signals and generates a channel processing signals PCD _R. Channel processed signal PCD _R generated is sent to the analog processing unit 114.

  In the first embodiment, the processing time by the adders 217L and 217R is sufficiently short when synchronization between reproduced audio channels is achieved.

Returning to FIG. 2, the delay applying unit 220 includes three individual delay applying units corresponding to the separated channel signals SCD _{SL to} SCD _SW . Then, the delay imparting section 220, a separation channel signal SCD _SL ~SCD _SW, as much to compensate for timing differences between the channel processing signals PCD _C ~PCD _R described above, delays the respective separation channel signal SCD _SL ~SCD _SW . The delay result by the delay adding unit 220 is sent to the analog processing unit 114 as channel processing signals PCD _{SL to} PCD _SW .

Returning to FIG. 1, the analog processing unit 114 receives the channel processing signals PCD _{C to} PCD _SW from the signal processing unit 113A. Then, the analog processing unit 114, under the control of the control unit 111, and generates an audio output signal AOS _C ~AOS _SW, and sends to the speaker 130 _C to 130 DEG _SW. As illustrated in FIG. 5, the analog processing unit 114 having such a function includes a DA (Digital to Analogue) conversion unit 241, a volume adjustment unit 242, and a power amplification unit 243.

The DA converter 241 receives the channel processing signals PCD _{C to} PCD _SW from the signal processing unit 113A. Then, the DA converter 241 converts the channel processing signals PCD _{C to} PCD _SW into analog signals. The DA converter 241 includes six DA converters configured similarly to each other in response to six types of digital signals. The conversion result by the DA conversion unit 241 is sent to the volume adjustment unit 242.

  The volume control unit 242 receives an analog signal that is a conversion result of the DA conversion unit 241. Then, the volume adjustment unit 242 performs volume adjustment processing on the received analog signal in accordance with the volume adjustment command VLC from the control processing unit 111. In the first embodiment, the volume adjusting unit 242 is configured to include six electronic volume elements that are configured in the same manner, corresponding to six types of analog signals. A volume adjustment signal that is an adjustment result by the volume adjustment unit 242 is sent to the power amplification unit 243.

The power amplification unit 243 receives the volume adjustment signal from the volume adjustment unit 242. The power amplifier 243 power-amplifies the volume adjustment signal. The power amplifying unit 243 includes six power amplifiers configured similarly to each other corresponding to the six types of volume adjustment signals. Audio output signals AOS _{C to} AOS _SW that are amplification results by the power amplifier 243 are sent to the speakers 130 _{C to} 130 _SW .

  Next, the control processing unit 111 will be described. The control processing unit 111 exerts the function of the acoustic device 100A while controlling the other components described above. The control processing unit 111 outputs the display data IMD and causes the display unit 140 to display a guidance screen for assisting the user in specifying audio content to be reproduced. When a reproduction command designating audio content is input from the operation input unit 150, the control processing unit 111 issues a reading command CSL to the sound source unit 120 and controls reading of the content data CTD.

In addition, the control processing unit 111 controls the volume adjusting unit 242 to adjust the output volume from the speakers 130 _{L to} 130 _SR . When controlling the output volume, the control processing unit 111 generates a volume adjustment command VLC according to the volume designation input to the operation input unit 150 and sends it to the volume adjustment unit 242.

<Operation>
Next, the operation of the acoustic device 100A configured as described above will be described mainly focusing on the generation processing of the audio output signals AOS _{C to} AOS _SW output to the speakers 130 _{C to} 130 _SW .

When the user inputs a reproduction command specifying audio content to the operation input unit 150, a message to that effect is sent to the control processing unit 111 as operation input data IPD. When receiving the reproduction command, the control processing unit 111 issues a reading command CSL to the sound source unit 120 and controls reading of the content data CTD. Under such control, the content data CTD read from the sound source unit 120 is sent to the channel separation unit 112. Upon receiving the content data CTD, the channel separator 112 expands the content data CTD and separates it into six separated channel signals SCD _{C to} SCD _SW corresponding to the _{C to SW} channels in the 5.1 channel surround system. The separated channel signals SCD _{C to} SCD _SW separated in this way are sent to the signal processing unit 113A (see FIG. 1).

In the signal processing unit 113A, the signal distribution unit 210A receives the separation channel signals SCD _{C to} SCD _R (see FIG. 2). The signal selector 210A, correlation evaluation unit 211L, the 211R and the delay imparting section 213A receives a separated channel signal SCD _C. Furthermore, the signal selector 210A, a correlation evaluation part 211L and the delay imparting section 213A receives a separated channel signal SCD _L. Moreover, the correlation evaluating unit 211R and the delay imparting section 213A receives a separated channel signal SCD _R (see FIG. 3).

Correlation evaluation unit 211L having received the separation channel signal SCD _C and the separation channel signal SCD _L calculates the correlation coefficient of the two signals. This calculation result is sent to the distribution coefficient determination unit 212A. Moreover, the correlation evaluating unit 211R having received the separation channel signal SCD _C and the separation channel signal SCD _R calculates a correlation coefficient between the two signals. This calculation result is sent to the distribution coefficient determination unit 212A (see FIG. 3).

The distribution coefficient determination unit 212A that has received the calculation results by the correlation evaluation units 211L and 211R determines distribution coefficients for the C channel, L channel, and R channel of the separated channel signal SCCD _C. In determining the distribution coefficient, in the first embodiment, based on the average value (ACR) of the two correlation coefficients from the correlation evaluation unit 211L and the correlation evaluation unit 211R, the first distribution for the C channel is performed. A coefficient (DC) and a common second distribution coefficient (DLR) as a distribution coefficient to the L channel and the R channel are determined by a predetermined algorithm. The first and second distribution coefficients determined in this way are sent to the distribution processing unit 215A (see FIG. 3).

On the other hand, the delay imparting section 213A that has received the separation channel signal SCD _C ~SCD _R includes a separation channel signal SCD _C ~SCD _R, by the amount of offset timing differences between the first and second sorting coefficients determined, separated delaying the respective channel signal SCD _C ~SCD _R. The separated channel signals SCD _{C to} SCD _R thus provided with the delay are sent to the distribution processing unit 215A (see FIG. 3).

The distribution processing unit 215A, the multiplication unit 216C, 216L, 216R is subjected to separation channel signal SCD _C delay imparted by the delay imparting section 213A. The addition unit 217L is subjected to separation channel signal SCD _L delay imparted by the delay imparting section 213A. The addition unit 217R is subjected to separation channel signal SCD _R delay imparted by the delay imparting section 213A (see FIG. 3).

The multiplication unit 216C multiplies the first distribution coefficient determined by the distribution coefficient determination unit 212A by the separated channel signal SCD _C to which the delay is given, to generate a channel processing signal PCD _C. The generated channel processing signal PCD _C is sent to the analog processing unit 114 (see FIG. 3).

Multiplying unit 216L has a second distribution coefficient determined by the distribution coefficient determination unit 212A, multiplies the separation channel signal SCD _C delay was granted. The multiplication result signal is sent to the addition unit 217L. The adder 217 adds the separated channel signal SCD _L to which the delay is given by the delay grant unit 213A and the signal resulting from the multiplication by the multiplier 216L to generate a channel processing signal PCD _L. The generated channel processed signal PCD _L was is sent to the analog processing unit 114 (see FIG. 3).

Multiplying unit 216R includes a second distribution coefficient determined by the distribution coefficient determination unit 212A, is multiplied in the separation channel signal SCD _C delay was granted. The multiplication result signal is sent to the adder 217R. Addition unit 217R adds the separated channel signal SCD _R delay imparted by the delay imparting section 213A, and the signal of the multiplication result by the multiplier unit 216R, and generates a channel processing signals PCD _R. Channel processed signal PCD _R generated is sent to the analog processing unit 114 (see FIG. 3).

In parallel with the operation of the above signal allocating unit 210A, the delay applying unit 220 separates the amount corresponding to the timing difference between the separated channel signals SCD _{SL to} SCD _SW and the channel processing signals PCD _{C to} PCD _R described above. Each of the channel signals SCD _{SL to} SCD _SW is delayed. The delay result by the delay adding unit 220 is sent to the analog processing unit 114 as channel processing signals PCD _{SL to} PCD _SW (see FIG. 2).

Thereafter, the channel processing signals PCD _{C to} PCD _SW are converted into analog signals by the DA converter 241. Subsequently, the volume adjustment unit 242 performs volume adjustment processing on the analog signal from the DA conversion unit 241 in accordance with the volume adjustment command VLC from the control processing unit 111, and sends it to the power amplification unit 243 as a volume adjustment signal (FIG. 5).

Power amplification unit 243 which has received the volume control signal is a volume control signal to the power amplifier, to produce an audio output signal AOS _C ~AOS _SW, and sends to the speaker 130 _C to 130 DEG _SW. Then, the speakers 130 _{C to} 130 _SW reproduce and output sound according to the sound output signals AOS _{C to} AOS _SW .

As a result, the C channel signal included in the content data CTD read from the sound source unit 120 is distributed to the C, L, and R channels according to the correlation amount between the L channel signal and the R channel signal. Based on the distribution result, the reproduced sound is output from the C speaker 130 _C , the L speaker 130 _L , and the R speaker 130 _R. Also, the output of reproduced sound from the SL speaker 130 _SL based on the SL channel signal, the output of reproduced sound from the SR speaker 130 _SR based on the SR channel signal, and the reproduced sound from the SW speaker 130 _SW based on the SW channel signal Output is done.

As described above, in the first embodiment, the correlation evaluation unit 211L calculates the correlation coefficient between the C channel signal and the L channel signal. Further, the correlation evaluation unit 211R calculates a correlation coefficient between the C channel signal and the R channel signal. Subsequently, the distribution coefficient determination unit 212A, based on the correlation coefficient calculated by the correlation evaluation units 211L and 211R, the first distribution coefficient to the C channel of the separated channel signal SCCD _C , the L channel, and the R channel A second distribution coefficient is determined.

Here, when determining the first distribution coefficient, the distribution coefficient determination unit 212A evaluates that the correlation is high when the correlation between the separated channel signal SCD _C and the separated channel signals SCD _L and SCD _R is positive. The first distribution coefficient having a positive value is determined so as to decrease as much as possible. On the other hand, the distribution coefficient determination unit 212A has a positive value so that the correlation channel evaluation value SCD _C and the separation channel signals SCD _L and SCD _R are smaller as the correlation is evaluated higher even when the correlation between the separation channel signals SCD _L and SCD _R is negative. The first distribution coefficient is determined.

In determining the second distribution coefficient, the distribution coefficient determination unit 212A is evaluated to have a high correlation when the correlation between the separated channel signal SCD _C and the separated channel signals SCD _L and SCD _R is positive. The second distribution coefficient having a positive value is determined so as to increase. On the other hand, when the correlation between the separated channel signal SCD _C and the separated channel signals SCD _L , SCD _R is negative, the distribution coefficient determining unit 212A has a negative value so that the correlation becomes smaller as the correlation is evaluated to be higher. The second distribution coefficient is determined.

The distribution processing unit 215A is, in accordance with the first and second sorting coefficient determined by the distribution coefficient determination unit 212A, and distributes the separated channel signal SCD _C to C channel, L-channel and R channel, channel processed signal PCCD _{C to} PCD _R are generated. Sounds corresponding to the channel processing signals PCD _{C to} PCD _R generated in this way are reproduced and output from the speakers 130 _{C to} 130 _R.

In the first embodiment, the delay adding units 213A and 220 synchronize so that the synchronization relationship between the channel processing signals PCD _{C to} PCD _{SW and} the synchronization relationship between the channel separation signals SCD _{C to} SCD _SW are substantially the same. Make adjustments.

Further, in the first embodiment, the separation channel signal SCD _C and the separation channel signal SCD _L, when the correlation between SCD _R is negative, because the second sorting coefficient a negative value, the separation channel signal SCD _L, a SCD _R, in addition to the allocation result of the separation channel signal SCD _C, never separated component of the channel signal SCD _C is canceled.

Therefore, according to the first embodiment, the C channel signal can be appropriately distributed to the L speaker 130 _L and the R speaker 130 _R while respecting the intention of the creator of the audio content.

[Second Embodiment]
Next, a second embodiment of the present invention will be described mainly with reference to FIG. In the second embodiment, as in the case of the first embodiment described above, a case where the 5.1 channel surround system is adopted will be described as an example.

<Configuration>
The second embodiment is different from the first embodiment described above in that a signal sorting unit 210B having the configuration shown in FIG. 6 is provided instead of the signal sorting unit 210A. Compared with the above-described signal distribution unit 210A, the signal distribution unit 210B includes a distribution coefficient determination unit 212B instead of the distribution coefficient determination unit 212A, and includes a delay addition unit 213B instead of the delay addition unit 213A. Instead of the distribution processing unit 215A, a distribution processing unit 215B is provided. Further, the signal allocating unit 210B has a high-pass filter (HPF) 218 as a high-pass filter unit, a low-pass filter (LPF) 219C as a first filter unit, Further, low-pass filters (LPF) 219L and 219R as two-filter means are further provided. Hereinafter, description will be made mainly focusing on these differences.

  In the second embodiment, the correlation evaluation units 211L and 211R and the LPFs 219C to 219R constitute detection means.

The HPF 218 receives the separation channel signal SCD _C. Then, the HPF 218 selectively passes the high frequency range component in the separation channel signal SCD _C. The signal that has passed through the HPF 218 is sent to the delay adding unit 213B.

The LPF 219C receives the separation channel signal SCD _C. Then, the LPF 219C selectively passes the low-frequency component in the separation channel signal SCD _C. The signal that has passed through the LPF 219C is sent to the delay adding unit 213B, the correlation evaluation unit 211L, and the correlation evaluation unit 211R.

  Note that the first frequency band, which is the frequency band of the bass signal that the LPF 219C passes, is determined in advance based on experiments, simulations, experience, and the like. Further, the second frequency band, which is the frequency band of the high-frequency signal that the HPF 218 passes through, is a frequency band other than the first frequency band.

The LPF 219L has the same frequency characteristics as the LPF 219C described above. This LPF219L receives a separated channel signal SCD _L. Then, LPF219L selectively passes the low frequency components in the separation channel signal SCD _L. The signal that has passed through the LPF 219L is sent to the correlation evaluation unit 211L.

The LPF 219R has the same frequency characteristics as the LPFs 219C and 219L described above. This LPF219R receives a separated channel signal SCD _R. Then, LPF219R selectively passes the low frequency components in the separation channel signal SCD _R. The signal that has passed through the LPF 219R is sent to the correlation evaluation unit 211R.

As a result of employing the configuration as described above, the correlation evaluation unit 211L in the second embodiment calculates a correlation coefficient between the signal that has passed through the LPF 219C and the signal that has passed through the LPF 219L. That is, the correlation evaluation part 211L has a low-frequency component in the separation channel signal SCD _C, thereby calculating a correlation coefficient between the low frequency components in the separation channel signal SCD _L.

Further, the correlation evaluation unit 211R in the second embodiment calculates a correlation coefficient between the signal that has passed through the LPF 219C and the signal that has passed through the LPF 219R. That is, the correlation evaluation unit 211R includes a bass component in the separation channel signal SCD _C, thereby calculating a correlation coefficient between the low frequency components in the separation channel signal SCD _R.

The above allocation coefficient determining unit 212B, as with the distribution coefficient determination unit 212A described above, the correlation evaluating unit 211L, will determine the distribution coefficient based on the correlation coefficient from 211R, in the separation channel signal SCD _C The difference is that the distribution coefficients to the C channel, the L channel, and the R channel regarding the component of the first frequency band corresponding to the predetermined low frequency range are determined. That is, the distribution coefficient determination unit 212B is different in the distribution coefficient determination algorithm from the distribution coefficient determination unit 212A described above. The algorithm employed by the distribution coefficient determination unit 212B is determined in advance based on experiments, simulations, experiences, and the like.

Note that, similarly to the distribution coefficient determination unit 212A, the distribution coefficient determination unit 212B also uses the first distribution for the C channel based on the average value of the two correlation coefficients from the correlation evaluation unit 211L and the correlation evaluation unit 211R. A common second distribution coefficient is determined as the coefficient and the distribution coefficient to the L channel and the R channel. In determining such first sorting coefficient, distribution coefficient determining unit 212B, when the correlation between the low-frequency component of the separation channel signal SCD _C separation channel signal SCD _L, the low frequency components of the SCD _R is positive The first distribution coefficient is determined such that the higher the correlation is evaluated, that is, the smaller the average value of the correlation coefficient is, the larger the value is in the range of “0” to “1”. On the other hand, the distribution coefficient determining unit 212B evaluates that the correlation is high when the correlation between the low-frequency component of the separation channel signal SCD _{C and} the low-frequency component of the separation channel signals SCD _L and SCD _R is negative. That is, the first distribution coefficient is determined so that the average value (ACR) of the correlation coefficient becomes smaller as it becomes smaller in the range of “−1” to “0”.

Further, in determining the second distribution coefficient, distribution coefficient determining unit 212B, when the correlation between the low-frequency component of the separation channel signal SCD _C separation channel signal SCD _L, the low frequency components of the SCD _R is positive Determines the second distribution coefficient such that the higher the correlation is evaluated, that is, the larger the average value of the correlation coefficient is, the larger the value is in the range of “0” to “1”. On the other hand, the distribution coefficient determining unit 212B evaluates that the correlation is high when the correlation between the low-frequency component of the separation channel signal SCD _{C and} the low-frequency component of the separation channel signals SCD _L and SCD _R is negative. That is, the second distribution coefficient is determined so that the average value of the correlation coefficient decreases as it decreases in the range of “−1” to “0”.

The delay applying unit 213B receives the signal that has passed through the HPF 218, the signal that has passed through the LPF 219C, and the separated channel signals SCD _L and SCD _R. The delay adding unit 213B includes four individual delay adding units corresponding to these four signals. Then, the delay adding unit 213B includes a signal that has passed through the HPF 218, a signal that has passed through the LPF 219C, and a signal that has passed through the LPF 219C to compensate for the timing difference between the separated channel signals SCD _{C to} SCD _R and the determined first and second distribution coefficients. separation channel signal SCD _L, delaying the respective SCD _R. That is, the delay providing unit 213B delays each of the received four signals by the processing time in the correlation evaluation units 211L and 211R and the distribution coefficient determination unit 212B. The signal thus provided with the delay is sent to the distribution processing unit 215B.

The distribution processing unit 215B further includes an addition unit 217C as a first addition unit, as compared with the above-described distribution processing unit 215A. The multiplication units 216C, 216L, and 216R are supplied with the low-frequency component of the separated channel signal SCCD _C to which the delay is added by the delay adding unit 213B.

The adder 217C receives the high frequency range component of the separated channel signal SCCD _C to which the delay is added by the delay adder 213B and the multiplication result signal from the multiplier 216C. Then, the adding unit 217C adds both signals to generate a channel processing signal PCD _C. The generated channel processing signal PCD _C is sent to the analog processing unit 114.

  In the second embodiment, the addition units 217L and 217R constitute a second addition unit.

  In the following description, a signal processing unit (corresponding to the signal processing unit 113A in the first embodiment) including the signal distribution unit 210B having the above-described configuration is referred to as a “signal processing unit 113B”.

<Operation>
Next, the operation of the audio apparatus according to the second embodiment configured as described above will be described mainly focusing on signal distribution processing.

When the user inputs a reproduction command specifying audio content to the operation input unit 150, content reading from the sound source unit 120 is performed in the same manner as in the first embodiment, and the read content data CTD is It is sent to the channel separation unit 112. Upon receiving the content data CTD, the channel separation unit 112 develops the content data CTD, separates it into six separated channel signals SCD _{C to} SCD _SW corresponding to the _{C to SW} channels in the 5.1 channel surround system, and performs signal processing Send to section 113B.

In the signal processing section 113B, the signal selector 210B receives the separated channel signal SCD _C ~SCD _R. In the signal distribution unit 210B, the HPF 218 and the LPF 219C receive the separation channel signal SCD _C. The delay imparting section 213B and LPF219L receives a separated channel signal SCD _L. The delay imparting section 213B and LPF219R receives a separated channel signal SCD _R.

Upon receiving the separation channel signal SCD _C , the HPF 218 selectively passes the high frequency range component in the separation channel signal SCD _C. The signal that has passed through the HPF 218 is sent to the delay adding unit 213B.

LPF219C which receives the separated channel signal SCD _C selectively passes the low frequency components in the separation channel signal SCD _C. The signal that has passed through the LPF 219C is sent to the delay adding unit 213B, the correlation evaluation unit 211L, and the correlation evaluation unit 211R.

LPF219L which receives the separated channel signal SCD _L selectively passes the low frequency components in the separation channel signal SCD _L. The signal that has passed through the LPF 219L is sent to the correlation evaluation unit 211L.

LPF219R which receives the separated channel signal SCD _R selectively passes the low frequency components in the separation channel signal SCD _R. The signal that has passed through the LPF 219R is sent to the correlation evaluation unit 211R.

The correlation evaluation unit 211L that has received the signal that has passed through the LPF 219C and the signal that has passed through the LPF 219L calculates the correlation coefficient of both signals. That is, the correlation evaluation part 211L calculates the low-frequency component in the separation channel signal SCD _C, the correlation coefficient between the low frequency components in the separation channel signal SCD _L. This calculation result is sent to the distribution coefficient determination unit 212B.

Further, the correlation evaluation unit 211R that has received the signal that has passed through the LPF 219C and the signal that has passed through the LPF 219R calculates the correlation coefficient of both signals. That is, the correlation evaluation unit 211R calculates a low-frequency component in the separation channel signal SCD _C, the correlation coefficient between the low frequency components in the separation channel signal SCD _R. This calculation result is sent to the distribution coefficient determination unit 212B.

The distribution coefficient determination unit 212B that has received the calculation results by the correlation evaluation units 211L and 211R determines the distribution coefficient for the C channel, L channel, and R channel of the low frequency component of the separated channel signal SCCD _C. In determining the distribution coefficient, in the second embodiment, based on the average value of the two correlation coefficients from the correlation evaluation unit 211L and the correlation evaluation unit 211R, A common second distribution coefficient as the distribution coefficient for the L channel and the R channel is determined by a predetermined algorithm. The first and second distribution coefficients determined in this way are sent to the distribution processing unit 215B.

On the other hand, the delay applying unit 213B that receives the signal that has passed through the HPF 218, the signal that has passed through the LPF 219C, and the separation channel signals SCD _L and SCD _R has separated channel signals SCD _{C to} SCD _R and the determined first and second oscillations. Each received signal is delayed by an amount corresponding to the timing difference from the division coefficient. The signal thus provided with the delay is sent to the distribution processing unit 215B.

In the distribution processing unit 215B, the multiplication units 216C, 216L, and 216R receive the low frequency range component of the separated channel signal SCCD _C to which the delay is added by the delay adding unit 213B. Further, the adding unit 217C receives the high frequency range component of the separated channel signal SCCD _C to which the delay is added by the delay adding unit 213B. The addition unit 217L is subjected to separation channel signal SCD _L delay imparted by the delay imparting section 213B. The addition unit 217R is subjected to separation channel signal SCD _R delay imparted by the delay imparting section 213B.

The multiplication unit 216C multiplies the low frequency range component of the separated channel signal SCCD _C to which the delay has been added by the first distribution coefficient determined by the distribution coefficient determination unit 212B. The multiplication result signal is sent to the addition unit 217C. The adder 217C adds the high frequency range component of the separated channel signal SCD _C to which the delay is added by the delay adder 213B and the signal resulting from the multiplication by the multiplier 216C to generate a channel processing signal PCD _C. The generated channel processing signal PCD _C is sent to the analog processing unit 114.

The multiplication unit 216L multiplies the low frequency range component of the separated channel signal SCCD _C to which the delay has been added by the second distribution coefficient determined by the distribution coefficient determination unit 212B. The multiplication result signal is sent to the addition unit 217L. The adding unit 217L adds the separated channel signal SCD _L to which the delay is given by the delay giving unit 213B and the signal resulting from the multiplication by the multiplication unit 216L to generate a channel processing signal PCD _L. The generated channel processed signal PCD _L was is sent to the analog processing unit 114.

The multiplication unit 216R multiplies the low-frequency component of the separated channel signal SCCD _C to which the delay is added by the second distribution coefficient determined by the distribution coefficient determination unit 212B. The multiplication result signal is sent to the adder 217R. Addition unit 217R adds the separated channel signal SCD _R delay imparted by the delay imparting section 213B, and a signal of the multiplication result by the multiplier unit 216R, and generates a channel processing signals PCD _R. Channel processed signal PCD _R generated is sent to the analog processing unit 114.

In parallel with the operation of the signal allocating unit 210B, as in the case of the first embodiment described above, the delay applying unit 220 includes the separation channel signals SCD _{SL to} SCD _SW and the channel processing signal PCD _C to by an amount to compensate the timing difference between the PCD _R, delaying the respective separation channel signal SCD _SL ~SCD _SW. The delay result by the delay adding unit 220 is sent to the analog processing unit 114 as channel processing signals PCD _{SL to} PCD _SW .

Thereafter, channel processed signal PCD _C ~PCD _SW is in the same manner as in the first embodiment described above, DA conversion unit 241, by passing through the volume adjusting unit 242 and the power amplifier unit 243, an audio output signal AOS _C ～AOS _SW is generated and sent to the speaker 130 _C to 130 DEG _SW. Then, the speakers 130 _{C to} 130 _SW reproduce and output sound according to the sound output signals AOS _{C to} AOS _SW .

As a result, the low-frequency component of the C channel signal included in the content data CTD read from the sound source unit 120 corresponds to C, C, according to the correlation amount between the low-frequency component of the L-channel signal and the low-frequency component of the R channel signal. Sorted into L and R channels. Based on the distribution result, the reproduced sound is output from the C speaker 130 _C , the L speaker 130 _L , and the R speaker 130 _R. Also, the output of reproduced sound from the SL speaker 130 _SL based on the SL channel signal, the output of reproduced sound from the SR speaker 130 _SR based on the SR channel signal, and the reproduced sound from the SW speaker 130 _SW based on the SW channel signal Output is done.

As described above, in the second embodiment, the correlation evaluation unit 211L calculates the correlation coefficient between the low frequency component of the C channel signal and the low frequency component of the L channel signal. Further, the correlation evaluation unit 211R calculates a correlation coefficient between the low frequency range component of the C channel signal and the low frequency range component of the R channel signal. Subsequently, based on the correlation coefficient calculated by the correlation evaluation units 211L and 211R, the distribution coefficient determination unit 212B, the first distribution coefficient to the C channel of the low frequency component of the separated channel signal SCD _C , and L A second distribution coefficient for the channel and the R channel is determined.

Here, when determining the first distribution coefficient, the distribution coefficient determination unit 212B determines that the correlation between the low-frequency component of the separation channel signal SCCD _C and the separation channel signals SCD _L and SCD _R is positive. The first distribution coefficient is determined so as to become smaller as it is evaluated as higher. On the other hand, the distribution coefficient determining unit 212B is evaluated as having a high correlation even when the low-frequency component of the separation channel signal SCD _{C and} the low-frequency component of the separation channel signals SCD _L and SCD _R are negative. A positive first distribution coefficient is determined so as to be smaller.

Further, in determining the second distribution coefficient, distribution coefficient determining unit 212B, when the correlation between the low-frequency component of the separation channel signal SCD _C separation channel signal SCD _L, the low frequency components of the SCD _R is positive Determines a positive second distribution coefficient so as to increase as the correlation is evaluated to be higher. On the other hand, the distribution coefficient determining unit 212B evaluates that the correlation is high when the correlation between the low-frequency component of the separation channel signal SCD _{C and} the low-frequency component of the separation channel signals SCD _L and SCD _R is negative. The negative second distribution coefficient is determined so as to be smaller.

Then, the distribution processing unit 215B distributes the low frequency range component of the separated channel signal SCCD _C to the C channel, the L channel, and the R channel according to the first and second distribution coefficients determined by the distribution coefficient determination unit 212B. The channel processing signals PCD _{C to} PCD _R are generated. Sounds corresponding to the channel processing signals PCD _{C to} PCD _R generated in this way are reproduced and output from the speakers 130 _{C to} 130 _R.

In the second embodiment, similarly to the case of the first embodiment described above, the delay adding units 213B and 220 have the synchronization relationship between the channel processing signals PCD _{C to} PCD _SW and the channel separation signals SCD _{C to} SCD _SW. The synchronization adjustment is performed so that the synchronization relationship is substantially the same.

Further, in the second embodiment, when the low frequency components and the separation channel signal SCD _L of the separation channel signal SCD _C, the correlation between the low frequency components of the SCD _R is negative, a negative value of the second distribution coefficient since the separation channel signal SCD _L, the low frequency components of the SCD _R, in addition to the allocation result of the low-frequency component of the separation channel signal SCD _C, never low frequency components of the separation channel signal SCD _C is canceled .

Therefore, according to the second embodiment, the low frequency range component of the C channel signal can be appropriately distributed to the L speaker 130 _L and the R speaker 130 _R while respecting the intention of the audio content producer.

[Modification of Embodiment]
The present invention is not limited to the above-described embodiment, and various modifications are possible.

  For example, in the first and second embodiments described above, the present invention is applied to an acoustic apparatus that outputs sound by a 5.1 channel surround system. On the other hand, the present invention can be applied to any acoustic apparatus that employs a multi-channel surround system having, for example, three or more channels as the number of speakers.

  In the first and second embodiments described above, the components of the predetermined frequency band of the C channel signal are distributed to the C to R channels, but can be distributed to other channels.

  In the first and second embodiments described above, it is assumed that the L speaker and the R speaker are symmetrically arranged with the arrangement position of the C speaker as the center, and the L channel of the component in the predetermined frequency band of the C channel signal. The distribution coefficient to the R channel and the distribution coefficient to the R channel are set to the same value. However, the distribution coefficient to the L channel and the distribution coefficient to the R channel are set in accordance with the relationship of the arrangement positions of the C to L speakers. The fraction coefficients may be different from each other.

In the first and second embodiments, the relationship shown in FIG. 4 is exemplified as the relationship between the average value of the correlation coefficient and the distribution coefficient. However, the relationship shown in FIG. You can also. That is, as illustrated in FIG. 7A, when the average value (ACR) of the correlation coefficient is in the range of “−1” to “0”, the distribution coefficient (DC) to the C speaker is a constant value ( DC _MAX ), and in the range where the average value (ACR) of the correlation coefficient is “0” to “1”, the distribution coefficient to the C speaker is increased as the average value (ACR) of the correlation coefficient increases. (DC) can be monotonically non-increasing in the range of positive values. Further, as illustrated in FIG. 7B, when the average value (ACR) of the correlation coefficient is in the range of “−1” to “0”, the distribution coefficient (DLR) to the L and R speakers is constant. with the value (DLR _MIN), in the range of the average value of the correlation coefficient (ACR) is "0" to "1", with increasing average value of the correlation coefficient (ACR), L, to R speaker Can be monotonically non-decreasing.

  Furthermore, the relationship between the average value of the correlation coefficient and the distribution coefficient can be the relationship shown in FIG. That is, as illustrated in FIG. 8A, in the entire range where the average value (ACR) of the correlation coefficient is “−1” to “1”, the average value (ACR) of the correlation coefficient increases. Thus, the distribution coefficient (DC) to the C speaker can be monotonously non-increasing within a positive value range. Further, as illustrated in FIG. 8B, with the increase in the average value (ACR) of the correlation coefficient in the entire range where the average value (ACR) of the correlation coefficient is “−1” to “1”. Thus, the distribution coefficient (DLR) to the L and R speakers can be monotonously non-decreasing.

  In the second embodiment, the distribution coefficient of the low frequency component of the C channel signal is determined based on the correlation coefficient between the low frequency component of the C channel signal and the low frequency component of the L and R channel signals. I tried to do it. On the other hand, the distribution coefficient of the C channel signal itself may be determined based on the correlation coefficient between the low frequency component of the C channel signal and the low frequency component of the L and R channel signals. Further, in accordance with the frequency characteristics of the reproduction capability of the C speaker, a predetermined frequency band of the C channel signal is determined based on a correlation coefficient between the component of the C channel signal in an arbitrary frequency band and the components of the L and R channel signals It is also possible to sort the components.

  In the first and second embodiments, the correlation coefficient is used for evaluating the correlation between the predetermined frequency band component of the C channel signal and the predetermined frequency component of the L and R channel signals. Other methods may be employed as the correlation evaluation method.

  In the first and second embodiments, the correlation evaluation result between the predetermined frequency band component of the C channel signal and the predetermined frequency band components of the L and R channel signals regardless of the signal level of the C channel signal. Based on the above, the distribution coefficient of the predetermined frequency band component of the C channel signal is determined. However, the distribution coefficient may be determined in consideration of the signal level of the C channel signal.

  The signal processing unit in the first and second embodiments is configured as a computer system including a central processing unit (CPU) and a DSP (Digital Signal Processor), and includes a control processing unit, a channel separation unit, and an auxiliary unit. The function of the audio signal generation unit can also be realized by executing a program. These programs may be acquired in a form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in a form distributed via a network such as the Internet. Good.

1 is a block diagram schematically showing the configuration of an acoustic device according to a first embodiment of the present invention. It is a block diagram which shows the structure of the signal processing part of FIG. It is a block diagram which shows the structure of the signal distribution part of FIG. It is a figure which shows the example of the relationship between the average value of a correlation coefficient, and a distribution coefficient. It is a block diagram which shows the structure of the analog process part of FIG. It is a block diagram which shows the structure of the signal distribution part in 2nd Embodiment of this invention. It is FIG. (1) which shows the modification of the relationship between the average value of a correlation coefficient, and a distribution coefficient. It is FIG. (2) which shows the modification of the relationship between the average value of a correlation coefficient, and a distribution coefficient.

Explanation of symbols

100A ... audio device 130 _C to 130 DEG _SW ... speaker 211L, 211R ... correlation evaluation section (detecting means)
212A, 212B ... Distribution coefficient determination unit (determination means)
213A, 213B ... Delay applying unit (part of synchronization adjusting means)
215A, 215B ... Distribution processing unit (generation means)
216C: Multiplication unit (first multiplication means)
216L, 216R ... Multiplication unit (second multiplication means)
217C ... Adder (first adding means)
217L, 217R ... Adder (addition means and second addition means)
218... High pass filter (high pass filter means)
219C: Low-pass filter (first filter means)
219L, 219R: Low-pass filter (second filter means)
220... Delay imparting unit (part of synchronization adjusting means)

Claims (19)

Based on a plurality of channel signals including a center channel signal supplied from a sound source, an audio device that outputs sound from a plurality of speakers including a center speaker installed corresponding to the center channel signal,
Detection means for detecting a correlation between a first frequency band component of the center channel signal and each of the first frequency band components of at least one other channel signal other than the center channel signal in the signals of the plurality of channels. When;
Determining means for determining a distribution coefficient to each of the center speaker and the speaker corresponding to the other channel signal of a component of the second frequency band of the center channel signal based on a detection result by the detecting means;
Generating means for generating an acoustic signal to be supplied to each of the speaker corresponding to the center speaker and the other channel signal according to the determination result by the determining means;
An acoustic device comprising:   At least when the correlation is positive, the distribution coefficient to the center speaker is monotonically non-increasing as the correlation increases, and the distribution coefficient to each of the speakers corresponding to the other channel signals is The acoustic apparatus according to claim 1, wherein the acoustic apparatus is monotonously non-decreasing as the correlation increases.   3. The acoustic device according to claim 2, wherein when the correlation is negative, the distribution coefficient to the center speaker is monotonically non-increasing as the correlation becomes higher.   The acoustic device according to claim 3, wherein when the correlation is negative, a distribution coefficient to the center speaker is a predetermined constant value.   When the correlation is negative, the distribution coefficient to each of the speakers corresponding to the other channel signal is a negative value, and monotonously non-increasing as the correlation increases. Item 4. The acoustic device according to Item 3.   The acoustic device according to any one of claims 1 to 5, wherein both the first frequency band and the second frequency band are all frequency bands. The generating means includes
First multiplying means for multiplying the center channel signal by the distribution coefficient to the center speaker determined by the determining means and supplying the center channel signal to the center speaker;
Second multiplying means for multiplying the center channel signal by a distribution coefficient to each speaker corresponding to the other channel signal determined by the determining means;
Adding means for adding each of the other channel signals and the corresponding multiplication result of the second multiplying means and supplying the result to each of the speakers corresponding to the other channel signals;
The acoustic device according to claim 6, comprising:   The acoustic apparatus according to claim 1, wherein the first frequency band is a predetermined low frequency band. The detection means includes
First filter means for extracting a component of the first frequency band from the center channel signal;
Second filter means for extracting a component of the first frequency band from each of the other channel signals;
Calculating means for calculating a correlation between each of the extraction results obtained by the second filter means and the extraction results obtained by the first filter means;
The acoustic device according to claim 8, comprising:   The acoustic device according to claim 8, wherein the second frequency band is a full frequency band. The generating means includes
First multiplying means for multiplying the center channel signal by the distribution coefficient for the center speaker determined by the determining means and supplying the center channel signal to the center speaker;
Second multiplying means for multiplying the center channel signal by a distribution coefficient to each speaker corresponding to the other channel signal determined by the determining means;
Adding means for adding each of the other channel signals and the corresponding multiplication result of the second multiplying means and supplying the result to each of the speakers corresponding to the other channel signals;
The acoustic device according to claim 10, comprising:   The acoustic device according to claim 8 or 9, wherein the second frequency band is the same band as the first frequency band. The generating means includes
First multiplying means for multiplying a component of the first frequency band of the center channel signal by a distribution coefficient to the center speaker determined by the determining means;
High-pass filter means for passing a component in a band other than the first frequency band of the center channel signal;
First addition means for adding the multiplication result by the first multiplication means and the component that has passed through the high-pass filter means and supplying the result to the center speaker;
Second multiplying means for multiplying a component of the first frequency band of the center channel signal by a distribution coefficient to each speaker corresponding to the other channel signal determined by the determining means;
Second addition means for adding each of the other channel signals and the corresponding multiplication result by the second multiplication means and supplying the result to each of the speakers corresponding to the other channel signals;
The acoustic device according to claim 12, comprising:   14. The speaker corresponding to the other channel signal includes a pair of speakers arranged symmetrically with respect to the position of the center speaker. Acoustic device.   15. The acoustic device according to claim 14, wherein the center channel signal distribution coefficients to the pair of speakers are the same as each other.   The synchronization adjustment means for adjusting a timing relationship between signals supplied to each of the plurality of speakers so as to be the same as a timing relationship between the plurality of channel signals. The acoustic device described in 1. An acoustic signal processing method for outputting sound from a plurality of speakers including a center speaker installed corresponding to the center channel signal based on a plurality of channel signals including a center channel signal supplied from a sound source,
A detection step of detecting a correlation between a component of the first frequency band of the center channel signal and each of the components of the first frequency band of at least one other channel signal other than the center channel signal in the signals of the plurality of channels. When;
A determination step of determining a distribution coefficient to each of the center speaker and the speaker corresponding to the other channel signal of the component of the second frequency band of the center channel signal based on the detection result in the detection step;
Generating a sound signal to be supplied to each of the speaker corresponding to the center speaker and the other channel signal according to the determination result in the determining step;
An acoustic signal processing method comprising:   An acoustic signal processing program for causing an arithmetic means to execute the acoustic signal processing method according to claim 17.   19. A recording medium, wherein the acoustic signal processing program according to claim 18 is recorded so as to be readable by an arithmetic means.

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