JP3525428B2 - Multi-channel signal processor - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a multi-channel signal processing device.

[0002]

2. Description of the Related Art FIG. 16 shows a conventional multi-channel signal processing device. The front left digital signal FL is delayed by the delay circuit DL.
1 is delayed for a predetermined time, and the D / A converter DAC
It is converted into an analog signal by 1 and output as a front left analog signal L _OUT . Front right digital signal FR
Is delayed by the delay circuit DL2 for a predetermined time, and D / A
Converted into an analog signal by the converter DAC2,
It is output as a front right analog signal R _OUT . Similarly,
The surround left digital signal LS, the surround right digital signal RS, the front center digital signal C, and the low-frequency digital signal LFE are delay circuits DL3, DL4, and DL, respectively.
5, DL6, D / A converter DAC3, DAC4, D
It is output as a surround left analog signal LS _OUT , a surround right analog signal RS _OUT , a front center analog signal C _OUT , and a low frequency analog signal SW _OUT via the AC 5 and the DAC 6.

These front left analog signal L _OUT , front right analog signal R _OUT , surround left analog signal L
The front left speaker L, the front right speaker R, the surround left speaker LS, and the surround right speaker shown in FIG. 17 are S _OUT , surround right analog signal RS _OUT , front center analog signal C _OUT , and low-frequency analog signal SW _OUT , respectively. Playback is performed by the RS, the front center speaker C, and the low frequency speaker SW. As a result, the listener 2 can obtain a realistic surround sound field.

As shown in FIG. 17, each speaker L, R,
When the LS, RS, C, and SW are not arranged at the same distance with respect to the listener 2, the delay circuits DL1, DL2,
The delay time is set by DL3, DL4, DL5, and DL6 to compensate for the deviation of the arrival time based on the distance difference. Therefore, an optimum sound field can be obtained irrespective of the arrangement position of each speaker with respect to the listener 2.

When the low frequency speaker SW is not used, as shown in FIG. 18, the front left analog signal L _OUT ,
The low frequency analog signal is added to the front right analog signal R _OUT , and the low frequency signal is reproduced from the front left speaker L and the front right speaker R.

Further, as shown in FIG. 19, the low-frequency digital signal LFE is added to the front left digital signal FL and the front right digital signal FR to reproduce the low-frequency signal from the front left speaker L and the front right speaker R. There is also a method.

[0007]

In the method shown in FIG. 18, the low frequency digital signal is subjected to delay processing and analog conversion processing, and then added to the front left analog signal and the front right analog signal. Therefore, FIG.
As shown in, when the distances from the front left speaker L and the front right speaker R are not equal, the arrival time difference between the low frequency signal from the front left speaker L and the low frequency signal from the front right speaker R is compensated. Creates the problem of being unable to.

On the other hand, as shown in FIG. 19, if the low frequency digital signal LFE is added to the front left digital signal FL and the front right digital signal FR, the low frequency signal from the front left speaker L is obtained. The arrival time difference from the low frequency signal from the front right speaker R can be compensated by the delay circuits DAC1 and DAC2. However, in the method of FIG. 19, since the addition processing is performed by digital signals, the following problems occur. Overflow occurs when adding full-scale digital signals. For this reason,
In the digital addition process, when two digital signals are added, the amplitude value of the digital signal is halved and then the addition process is performed. Therefore, in the digital addition processing, there arise problems of deterioration of signal accuracy and increase of noise.

The present invention solves the above-mentioned problems and can perform appropriate arrival time compensation according to the arrangement of speakers, and thus multi-channel signal processing which does not cause deterioration of signal accuracy and increase of noise. The purpose is to provide a device.

[0010]

According to the multi-channel signal processing apparatus of claim 1 and the multi-channel signal processing method of claim 8, after the front left digital signal is subjected to delay processing by digital processing, , After converting to an analog signal to generate a front left analog signal and performing delay processing by digital processing on the front right digital signal,
Generates a front right analog signal by converting to an analog signal,
The low-frequency digital signal for the left separated from the low-frequency digital signal for the front left speaker is subjected to a delay process by digital processing, and then converted into an analog signal to generate a low-frequency analog signal for the left, which is converted from the low-frequency digital signal. The low-frequency digital signal for the right separated for the front right speaker is subjected to delay processing by digital processing, then converted into an analog signal to generate a low-frequency analog signal for the right, and a front left analog signal,
It is characterized in that a low-frequency analog signal for left is added to generate a front-left speaker analog signal, and a low-frequency analog signal for right is added to a front-right analog signal to generate a front-right speaker analog signal.

Therefore, the arrival time of the low-frequency signal output from the front left speaker and the arrival time of the low-frequency signal output from the front right speaker can be matched by the delay process. Furthermore, since the addition is performed as an analog signal, it is possible to prevent a decrease in signal accuracy and an increase in noise.

A multi-channel signal processing device according to claim 2 is
At least front left digital signal, front right digital signal,
These signals are received by at least the front left speaker, front right speaker, surround left speaker with insufficient low-frequency reproduction capability, and surround right speaker with insufficient low-frequency reproduction capability after receiving the low-frequency digital signal, surround left digital signal, and surround right digital signal. The output of the surround left signal delay means and the surround left signal delay means that performs delay processing by digital processing on the signal obtained by removing the low frequency component from the surround left digital signal. And a surround left signal conversion means for converting the analog signal to output a surround left analog signal, and a surround right signal delay means for performing delay processing by digital processing on the signal obtained by removing the low frequency component from the surround right digital signal. , The output of the surround right signal delay means, Surround right signal conversion means for converting to a analog signal and outputting a surround right analog signal is provided, and a signal obtained by extracting the low frequency component of the surround left digital signal is added to the low frequency digital signal for left, and a signal delay means for left is provided. The signal obtained by extracting the low-frequency component of the surround right digital signal is added to the low-frequency digital signal for right, and the signal is applied to the signal delay means for right.

Therefore, even if the low frequency reproduction capability of the surround left speaker and the surround right speaker is not sufficient, and the low frequency components of the surround left signal and the surround right signal are reproduced from the front left speaker and the front right speaker, respectively. ,
It is possible to prevent a difference in arrival time, a decrease in signal accuracy, and an increase in noise.

A multi-channel signal processing device according to claim 3 is
At least the front left digital signal, the front center digital signal, the front right digital signal, the low-frequency digital signal, the surround left digital signal, the surround right digital signal, at least the front left speaker, the front center speaker whose low-frequency reproduction capability is not sufficient, The front right speaker, the surround left speaker that does not have sufficient low-frequency reproduction capability, and the surround right speaker that does not have sufficient low-frequency reproduction capability generate analog signals to reproduce them. Front center signal delay means for performing delay processing by digital processing on the removed signal, and front center signal conversion means for converting the output of the front center signal delay means into an analog signal and outputting a front center analog signal. The signal from which the low frequency component of the front center digital signal is extracted The left front center digital signal separated for the left speaker is added to the signal obtained by extracting the low frequency component of the surround left digital signal, the left low frequency digital signal, and given to the left signal delay means to provide the low frequency range of the front center digital signal. The right front center digital signal separated for the front right speaker from the extracted signal is added to the low-frequency component signal of the surround right digital signal, the low-frequency digital signal for right, and the signal delay for right is added. It is characterized by giving means.

Therefore, even if the low-frequency reproduction capability of the front center speaker is not sufficient and the low-frequency component of the front center signal is reproduced from the front left speaker and the front right speaker, the arrival time difference and the signal accuracy are high. Can be prevented and increase in noise can be prevented.

A multi-channel signal processing device according to claim 4 is
Front left digital signal, front center digital signal, front right digital signal, surround left digital signal, surround right digital signal, low frequency digital signal, each input line and front left connected to front left digital signal line Signal delay means, front right signal delay means connected to the front right digital signal line, surround left signal delay means connected to the surround left digital signal line,
Surround right signal delay means connected to the surround right digital signal line and the front center digital signal line,
Front center signal delay means connected via the switch means, low frequency digital signal line, front center signal line connected to the low center / center signal delay means via the switch means, and front left digital signal To each of the line, the front center digital signal line, and the surround left digital signal line, to the low-frequency component extraction means for left, the output of the low-frequency component extraction means for left, and the low-frequency digital signal line, respectively. , The signal delay means for the left connected through the switch means, the front right digital signal line, the front center digital signal line, the surround right digital signal line, respectively, the low frequency component extraction for the right connected through the switch means Means, the output of the low-frequency component extraction means for the right, each of the low-frequency digital signal line, through the switch means Connected right signal delay means, front left signal conversion means for converting the output of the front left signal delay means into an analog signal, and front right signal conversion means for converting the output of the front right signal delay means into an analog signal, Surround left signal conversion means for converting the output of the surround left signal delay means into an analog signal, surround right signal conversion means for converting the output of the surround right signal delay means into an analog signal, and output of the front center signal delay means with an analog signal Front center signal converting means for converting the output of the low frequency / center signal delaying means into an analog signal, and a left center signal converting means for converting the output of the left signal delaying means into an analog signal A right signal conversion means for converting the output of the right signal delay means into an analog signal, a front left signal conversion means, a front right signal conversion means, and a salau Output left signal conversion means, surround right signal conversion means, front center signal conversion means, low frequency / center signal conversion means, left signal conversion means, right signal conversion means, and outputs are added and combined to form a front left speaker An output, an output for a front right speaker, an output for a surround left speaker, an output for a surround right speaker, an output for a front center speaker, an output for a woofer speaker, and whether to use each of the above speakers. Please select a combination of ON / OFF of each of the switch means and the output generating means based on whether or not the speaker to be used has sufficient low-frequency reproduction capability, and obtain an appropriate output according to the speaker to be used. It is characterized by doing so.

Therefore, an appropriate output can be obtained according to the capability and the number of speakers used. The multi-channel signal processing device according to claim 5, which is capable of preventing a difference in arrival time, a decrease in signal accuracy, and an increase in noise, is further provided with respective input signals for the center left digital signal and the center right digital signal. A center left digital signal line is connected to a front center signal line or a low-frequency digital signal line via a switch means, and the center left digital signal line is connected to a left low-frequency component extraction means via a switch means. , The center right digital signal line is connected to the low band digital signal line or the front center signal line via the switch means, and the center right digital signal line is connected to the right low band component extraction via the switch means. It is characterized in that it is connected to the means and the output generating means is further provided with an output for the center left speaker and an output for the center right speaker.

Therefore, it is possible to further input a digital signal including the center left digital signal and the center right digital signal to generate a speaker signal.

A multi-channel signal processing device according to claim 6 is
The output generating means switches between the output for the center left speaker and the first multi-source output, and switches between the output for the center right speaker and the second multi-source output.

Therefore, the output for the center left speaker, the output for the center right speaker, and the multi-source output can be switched and used.

A multi-channel signal processing device according to claim 7 is
The output of the left signal converting means is provided with a variable attenuating means, and the output of the right signal converting means is provided with a variable attenuating means.

Therefore, an appropriate gain can be set according to the selection state of the signal based on the switching of each switch means.

In the present invention, the "delay means" means a means for delaying a signal, and in the embodiment, the delay processes DL1 to DL8 correspond to this.

The "converting means" means means for converting a digital signal into an analog signal, and in the embodiment, the D / A converters DAC1 to DAC8 correspond to this.

The "low-frequency component extracting means" means means for extracting low-frequency components of a signal, and in the embodiment, the low-pass filters LP1 and LP2 correspond to this.

[0026]

FIG. 1 shows the overall configuration of a multi-channel signal processing device according to an embodiment of the present invention. In this embodiment, the low frequency signal L is used without using the low frequency speaker SW.
The FE is reproduced from the front left speaker L and the front right speaker R.

The front left digital signal FL, the front right digital signal FR, the surround left digital signal SL, the surround right digital signal SR, and the front center digital signal C are respectively the front left signal delay means DL1, the front right signal delay means DL2, A predetermined delay process is performed by the surround left signal delay means DL3, the surround right signal delay means DL4, and the front center signal delay means DL5. After that, respectively,
Front left signal conversion means DAC1, front right signal conversion means DA
C2, surround left signal conversion means DAC3, surround right signal conversion means DAC4, front center signal conversion means DAC
5 is converted into an analog signal.

Further, the low-frequency digital signal LFE is given to the left signal delay means DL7 and the right signal delay means DL8 to be given independent delay times. The outputs of the left signal delay means DL7 and the right signal delay means DL8 are converted into analog signals by the left signal conversion means DAC7 and the right signal conversion means DAC8, respectively.

The front left analog signal from the front left signal conversion means DAC1 and the low frequency analog signal from the left signal conversion means DAC7 are added as analog signals by the front left speaker signal generation means 2 to generate the front left speaker signal L. _OUT . Similarly, the front right signal conversion means DAC2
Front right analog signal from the right and right signal conversion means DAC
The low-frequency analog signal from 8 is added as an analog signal by the front right speaker signal generation means 4 to form a front right speaker signal R _OUT . Therefore, the low-frequency signal is output from the front left speaker L and the front right speaker R, and the low-frequency signal can be reproduced even when the low-frequency speaker SW cannot be prepared. Further, since the low-frequency digital signal LFE is separated into a left signal and a right signal, and independent delay means DL7 and DL8 are provided respectively, as shown in FIG. 17B, a front left speaker L and a front right speaker R are provided. Even when the distances are different, the arrival time difference of the low frequency signal can be compensated. Furthermore, since the addition of the front left analog signal and the low-frequency analog signal and the addition of the front right analog signal and the low-frequency analog signal are processed as analog signals, there is no decrease in precision as in the case of addition by digital signals. .

FIG. 2 shows the overall configuration of a multi-channel signal processing device according to another embodiment. In this embodiment, the surround left speaker LS and the surround right speaker RS
However, since it does not have sufficient low frequency reproduction capability, the low frequency components of the surround left signal SL and the surround right signal SR are reproduced from the front left speaker L and the front right speaker R.

The surround left digital signal SL and the surround right digital signal SR are respectively in the low frequency band removing means HP.
3, after removing low frequency components by HP4, surround left signal delay means DL3, surround right signal delay means DL
Given to 4. Therefore, the surround left speaker L
A surround signal containing no low frequency component is given to the S and surround right speakers RS.

Further, the surround left digital signal SL and the surround right digital signal SR are added to the low frequency digital signal LFE by the adding means 6 and 8 after the low frequency components are extracted by the low frequency extracting means LP3 and LP4, respectively. To be done. Therefore, the low frequency components of the surround left signal and the surround right signal are the front left speaker L and the front right speaker R, respectively.
Played from.

FIG. 3 shows the overall configuration of a multi-channel signal processing device according to another embodiment. In this embodiment, since the front center speaker C does not have sufficient low-frequency reproduction capability, the low-frequency component of the front center digital signal C is reproduced from the front left speaker L and the front right speaker R. .

The front center digital signal C has its low band removed by the low band removing means HP5, and the front center signal delaying means D
Given to L5. Therefore, the front center speaker C reproduces the front center signal from which the low frequency components have been removed.

The front center digital signal C has its low frequency band extracted by the low frequency band extracting means LP3 and LP4, is separated into a left signal and a right signal, and is added by the adding means 6 and 8 respectively. It is given to the left signal delay means DL7 and the right signal delay means DL8. Therefore, the low frequency component of the front center signal is reproduced from the front left speaker L and the front right speaker R.

FIGS. 4 and 5 show the hardware configuration when the multi-channel signal processing device shown in FIGS. 1 to 3 is realized by using a DSP. I-IX in FIG. 4 are connected to I-IX in FIG. 5, respectively. The digital processing unit 1
0 is represented as a signal flow indicating the processing content by the digital signal processor.

The actual hardware configuration of the digital processing unit 10 is as shown in FIG. Digital signal FL,
FR, LS, RS, C, and LFE input data to a multi-channel surround decoder (not shown) for decoding by decoding digital data of a surround-encoded digital bit stream or an analog signal by an A / D converter. It is obtained by doing. These signals are provided to a digital signal processor (DSP) 58. The multi-channel surround decoder
It may be separated from the DSP 58 or may be built in the DSP 58.

The DSP 58 performs processing such as addition, filtering and delay on the digital data according to the program stored in the memory 56, and the DAC 1 to DAC 1
Generates output to DAC8.

The microprocessor 54 performs processing such as storing the program in the memory 54. This program may be pre-burned in a ROM or the like, or may be installed from another recording medium such as a CD-ROM.

The operation section 50 receives an operation input by the operator. Further, the display unit 52 displays the content of operation input of the liquid crystal display device and the like. In FIG.
A display example on the display unit 52 is shown. Each speaker is LAR
It is possible to select which of GE (speaker capable of reproducing low frequencies), SMALL (speaker having low low frequency reproducibility), and NONE (not used) according to the operation of the operation unit 50. For the subwoofer, it is possible to select YES (use) or NO (do not use).

The distance from each speaker to the listener 2 can be input according to the operation of the operation unit 50. In the example shown in FIG. 10, the front left speaker L
Is "LARGE" and is 10 m away from the listener 2, the front right speaker R is "LARGE" and 9 m away from the listener 2, and the front center speaker C is "LARGE". 9 m away from listener 2, surround left speaker LS is "LARGE" and 8 m away from listener 2, surround right speaker RS is "LARGE" and 9 m away from listener 2. , The subwoofer SW is not used. That is, it is the usage status of the speaker corresponding to the configuration shown in FIG.

4 and 5, the mode shown in FIGS. 1 to 3 can be changed by switching the switches S2 to S58 by the MPU in response to the input from the operation unit 50. ing. For example, by switching the switches S2 to S58 as shown in FIGS. 7 and 8, the configuration shown in FIG. 1 can be realized.

The front left analog signal FL, the front right analog signal FR, the surround left analog signal LS, the surround right analog signal RS, the front center analog signal C, and the low frequency analog signal LFE are the front left analog signal line 80 and the front, respectively. The right analog signal line 82, the surround left analog signal line 84, the surround right analog signal line 86, the front center analog signal line 88, and the low frequency analog signal line 90 are connected.

In FIGS. 4 and 5, LP4, LP
6, LP7, LP8, LP9, LP10, LP11, L
P13 and LP14 are low-pass filters for removing noise. Further, the adders 24 to 34 are respectively provided with amplifiers Q1 to Q6, and are for adding analog signals.

The low-frequency digital signal LFE is delayed by the delay processing DL.
7, D / A converter DAC7, low-pass filter LP
After being processed by 13, it is given to the attenuator VR9 as a low frequency signal for left. Also, the low frequency digital signal L
FE is a delay processing DL8, a D / A converter DAC8,
After being processed by the low-pass filter LP14, it is given to the attenuator VR10 as a right low-pass signal.

The delay processes DL1 to DL8 perform a delay process in accordance with the distance input from the operation unit 50 so that the time required to reach the listener 2 from each speaker is the same. For example,
The delay time of the other speaker may be determined so as to match the farthest speaker among the speakers.

The attenuators VR9 and VR10 have an attenuation amount corresponding to the scaling value in the addition processing 12, 14, 16 and 18, depending on the number and type of speakers used (whether reproduction is possible up to the low frequency range). It is controlled by the attenuation amount control circuit 20.

The output of the attenuator VR9 is given to the resistor R42 of the adder 24, and the output of the attenuator VR10 is given to the resistor R47 of the adder 26. The ratio at the time of addition by the adder 24 is determined by the resistors R39 to R42.
Further, the ratio at the time of addition by the adder 26 is determined by resistors R44 to R47
Determined by The ratio at the time of this addition is determined according to the number and type of speakers used (whether or not reproduction is possible up to low frequencies). The resistances of the resistors R42 and R47 are set to such resistance values that the addition ratio matches the switching mode.
Note that the resistors R48 to
The addition ratio is determined by R60, and this addition ratio is determined according to the number and type of speakers used (whether reproduction is possible up to low frequencies).

In the switching mode, in the adder 24, D
The front left signal from AC1 and LP4 and the left low frequency signal are added. The output of the adder 24 is the volume VR1,
It is output as the front left speaker signal L _OUT via the amplifier Q7. In this embodiment, the adder 24,
The volume VR1 and the amplifier Q7 constitute the front left speaker signal generating means 2.

In addition, in the adder 26, DAC2, L
The front right signal from P6 and the right low frequency signal are added. The output of the adder 26 is the volume VR2 and the amplifier Q8.
_Is output as a front right speaker signal R _OUT . In this embodiment, the adder 26, the volume VR2, and the amplifier Q8 constitute the front right speaker signal generation means 4.

As described above, the front left speaker signal L
_OUT , a front right speaker signal R _OUT is generated.

The surround left digital signal SL is given to the resistor R48 of the adder 28 as a surround left analog signal via the delay processing DL3, the D / A converter DAC3, and the low pass filter LP7 for removing noise. In the connection form, since the switch S40 is off, the adder 28 outputs the surround left analog signal as it is. The output of the adder 28 is output as the surround left speaker signal LS _OUT via the volume VR3 and the amplifier Q9.

The surround right digital signal SR is given to the resistor R51 of the adder 30 as a surround right analog signal via the delay processing DL4, the D / A converter DAC4, and the low pass filter LP8 for removing noise. In the connection form, since the switch S43 is off, the adder 30 outputs the surround right analog signal as it is. The output of the adder 30 is output as a surround right speaker signal RS _OUT via the volume VR4 and the amplifier Q10.

The central digital signal C is processed by the switch process S.
2, through S24, delay processing DL5, D / A converter DAC5, low-pass filter LP for noise removal
It is given to the resistor R53 of the adder 32 via 9 as a central analog signal. In the connection form, since the switches S45, S46, and S47 are off, the adder 32
The central analog signal is output as is. The output from the adder 32 is output as a surround right speaker signal C _OUT via the volume VR5 and the amplifier Q11.

The circuit shown in FIG. 1 is realized as described above. The circuit shown in FIG. 2 is realized by the connection forms of FIGS. 7 and 8, and the circuit shown in FIG. 3 is realized by the connection forms. In addition, connection configurations other than these are also applicable to the switch S2.
This can be realized by switching S58 to S58.

FIG. 9 shows how the switches S2 to S58 are switched depending on the type of speaker used. In the figure, FL / FR, C, SL / SR, SW in the speaker setting column are
A front speaker, a front center speaker, a surround speaker, and a subwoofer speaker are shown, respectively. For each speaker, L indicates a speaker having low-frequency reproduction capability, S indicates a speaker having low low-frequency reproduction capability, and N indicates no speaker. Regarding the subwoofer, Y indicates that it is used and N indicates that it is not used.

The switches S51, S56, S52, S57, S53, S5 corresponding to the usage modes of the speakers.
8, S39, S42, S40, S43, S44, S4
5, the switching mode of S46, S47, S48, and S49 is shown. "TURE" indicates on, "FALSE" indicates off.

In FIG. 9, the setting validity column indicates whether or not the input speaker combination is appropriate. "TRUE" indicates appropriate, "FALSE" indicates inappropriate.
For example, if S is input for all the speakers, there is no speaker that reproduces the low frequency range, and the result is "FALSE". In the case of "FALSE", the display unit 52 displays a warning such as "There is no speaker that reproduces low frequencies".

As described above, according to the embodiments shown in FIGS. 4 and 5, the low-frequency signal extracted from the signal given to the speaker having the low low-frequency reproduction capability is determined according to the type of the speaker used and the presence / absence of the speaker. Is applied to a speaker having a low-frequency reproduction capability to reproduce the low frequency.
Further, at that time, it is separated into a left digital signal and a right digital signal, each signal is independently subjected to digital delay processing, and then converted into a left analog signal and a right analog signal. Further, addition processing is performed as an analog signal.

Therefore, an appropriate output can be obtained according to the ability and the number of speakers to be used. Further, FIG. 11 and FIG. 12 capable of preventing the deviation of the arrival time, the deterioration of the signal accuracy, and the increase of the noise are shown in FIG. 11 and FIG. Front left analog signal line 92 for front left analog signal LC, front right analog signal line 94 for front right analog signal RC
Is provided. In this embodiment, the attenuator V
Without using R9 and VR10, the resistors RF4, RF5, and RF1 of the adders 36 to 46 are selected according to the respective switching modes.
1, RF9, RF10, RS2, RS4, RC2, RC
The attenuation value is changed by selecting 3, RSM1, RSM2, RSM3, and RSM4.

Further, in this embodiment, as shown in FIG. 13, an MPEG 7.1 channel configuration in which a central left speaker LC and a central right speaker RC are added is also applicable. Input terminal for center left digital signal LC, center right digital signal RC, output terminal for center left speaker signal, center right speaker signal MULTI / LC
_OUT and MULTI / RC _OUT are provided.

14 and 15, the speaker to be used and the switching mode of the switches S1 to S65 and the HPF in the DSP are shown.
The following is a list of ON / OFF and scaling values.

In the "HPF inside DSP" column,
The item FL / FR turns on (TRUE) or turns off (FAL) the high-pass filters HP1 and HP2 for the forward signals FL and FR.
SE), item C is high-pass filter HP5 for front center signal C turned on (TRUE) or off (FALSE), item LS / RS is high-pass filter for surround signals LS, RS. Whether HP3 and HP4 are turned on (TRUE) or turned off (FALSE), the item LC / RC is the high-pass filters HP6 and H for the central left and right signals LC and RC.
It indicates whether P7 is turned on (TRUE) or turned off (FALSE).

Further, in this embodiment, the switch S5
By controlling ON / OFF of S8 and S59, the output from the amplifier Q15 can be switched to the center left speaker signal LC _OUT and the multi-source left signal MULTSL. Similarly, switches S64 and S6
The output from the amplifier Q16 can be switched to the center left speaker signal RC _OUT and the multi-source left signal MULTSR by controlling the ON / OFF of the signal Q5. Therefore, the volumes R14, R1
5, the amplifiers Q15 and Q16 can be shared by these signals. In addition, multi-source terminals MULTSL, M
If an analog signal is given to ULTSR and the output is switched to multi-source, each speaker signal L _OUT , R _OUT , LS
_{OUT, RS O UT, C OUT} , the SW _OUT can be output independent signal output terminal MULTI / LC _OUT, from MULTI / RC _OUT.

[Brief description of drawings]

FIG. 1 is a diagram showing an overall configuration of a multi-channel audio signal processing device according to an embodiment of the present invention.

FIG. 2 is a diagram showing an overall configuration of a multi-channel audio signal processing device according to another embodiment of the present invention.

FIG. 3 is a diagram showing an overall configuration of a multi-channel audio signal processing device according to another embodiment of the present invention.

FIG. 4 is a diagram showing the multi-channel audio signal processing device of FIG.
FIG. 3 is a diagram showing a hardware configuration and a signal flow when realized by using.

5 is a diagram showing the multi-channel audio signal processing device of FIG.
It is a figure which shows the hardware constitutions when it implement | achieves using.

FIG. 6 is a diagram showing a hardware configuration of a DSP portion.

FIG. 7 is a diagram showing a switching mode of switches S2 to S58.

FIG. 8 is a diagram showing a switching mode of switches S2 to S58.

FIG. 9 is a diagram showing the relationship between the type of speaker to be used, whether or not the speaker is used, and the switching mode of the switches S2 to S58.

10 is a diagram showing a display example on the display unit 52. FIG.

FIG. 11 is a diagram showing a hardware configuration and a signal flow when a multi-channel audio signal processing device according to another embodiment is realized by using a DSP.

FIG. 12 is a diagram showing a hardware configuration when a multi-channel audio signal processing device according to another embodiment is realized by using a DSP.

FIG. 13 is a diagram showing an arrangement of speakers in an MPEG7.1 channel.

FIG. 14 is a diagram showing the relationship between the type of speaker to be used, whether or not the speaker is used, and the switching mode of the switches S2 to S58.

FIG. 15 is a diagram showing the relationship between the type of speaker used, whether or not the speaker is used, and the switching mode of the switches S2 to S58.

FIG. 16 is a diagram showing a circuit configuration of a conventional multi-channel audio signal processing device.

FIG. 17 is a diagram showing an arrangement of speakers.

FIG. 18 is a diagram showing a circuit configuration of a conventional multi-channel audio signal processing device.

FIG. 19 is a diagram showing a circuit configuration of a conventional multi-channel audio signal processing device.

[Explanation of symbols]

2 ... Signal generating means for front left speaker 4. Front right speaker signal generation means 6, 8 ... Addition means DL7 ... Left signal delay means DL8 ... Right signal delay means DAC7 ... left signal conversion means DAC8 ... Right signal conversion means

Claims (8)

(57) [Claims] 1. A multi-channel signal processing device for receiving at least a front left digital signal, a front right digital signal, and a low-frequency digital signal and generating an analog signal for reproducing them by at least a front left speaker and a front right speaker. A front left signal delaying means for delaying the front left digital signal by digital processing, and a front left signal converting means for converting an output of the front left signal delaying means into an analog signal and outputting a front left analog signal. A front right / left signal delay means for delaying the front right digital signal by digital processing, and a front right signal conversion means for converting an output of the front right signal delay means into an analog signal and outputting a front right analog signal. , Digital processing is performed on the left low-frequency digital signal separated from the low-frequency digital signal for the front left speaker. Left signal delay means for performing delay processing by means of, and a left signal conversion means for converting the output of the left signal delay means into an analog signal to output a low frequency analog signal for the left, and a low frequency digital signal for separating the front right speaker The right signal delay unit that performs delay processing by digital processing on the right low-frequency digital signal and the output of the right signal delay unit is converted into an analog signal to output the right low-frequency analog signal. A signal converting means, a front left analog signal from the front left signal converting means, and an output signal from the left signal converting means to generate an analog signal for the front left speaker; A front right speaker signal for generating a front right speaker analog signal by adding the output signal from the right signal conversion means to the front right analog signal from the signal conversion means. Multichannel signal processing apparatus including a generation unit, a. 2. The multi-channel signal processing device according to claim 1, wherein the signal processing device is at least a front left digital signal,
Front right digital signal, low frequency digital signal, surround left digital signal, surround right digital signal received, at least front left speaker, front right speaker, low range reproduction capability surround left speaker, low range reproduction capability is not sufficient The surround right speaker is used to generate analog signals to reproduce these signals. Surround left signal delay means that performs delay processing by digital processing on the signal obtained by removing the low-frequency component from the surround left digital signal, and surround left signal Surround left signal conversion means that converts the output of the signal delay means to an analog signal and outputs a surround left analog signal, and surround that applies delay processing by digital processing to the signal from which the low frequency component has been removed from the surround right digital signal Right signal delay means and surround right Surround right signal conversion means for converting the output of the signal delay means to an analog signal and outputting a surround right analog signal is provided, and the signal obtained by extracting the low frequency component of the surround left digital signal is converted into the low frequency digital signal for left. It is characterized in that the signal is added and given to the left signal delay means, and the signal obtained by extracting the low-frequency component of the surround right digital signal is added to the right low-frequency digital signal and given to the right signal delay means. 3. The multi-channel signal processing device according to claim 1, wherein the signal processing device is at least a front left digital signal,
Front center digital signal, front right digital signal, low frequency digital signal, surround left digital signal, surround right digital signal, at least front left speaker, front center speaker with low low frequency reproduction capability, front right speaker, low frequency Surround left speaker, which does not have sufficient reproduction capability
It generates analog signals to reproduce these signals by the surround right speaker that does not have sufficient low-frequency reproduction capability. Front center Digital signal with the low-frequency component removed A signal delay unit and a front center signal conversion unit that converts the output of the front center signal delay unit into an analog signal and outputs a front center analog signal are provided. ,
The left front center digital signal separated for the front left speaker is added to the signal obtained by extracting the low-frequency component of the surround left digital signal, the left low-frequency digital signal, and given to the left signal delay means to reduce the front center digital signal. From the signal that extracted the range component,
The front center digital signal for the right separated for the front right speaker is added to the signal obtained by extracting the low-frequency component of the surround right digital signal, the low-frequency digital signal for the right, and given to the right signal delay means. What to do. 4. A front left digital signal, a front center digital signal, a front right digital signal, a surround left digital signal,
Input signals for surround right digital signal and low frequency digital signal, front left signal delay means connected to front left digital signal line, front right signal delay means connected to front right digital signal line Surround left signal delay means connected to the surround left digital signal line, surround right signal delay means connected to the surround right digital signal line, front center Digital signal line, front center connected via switch means Signal delay means, low-pass digital signal line, front center signal line, low-pass / center signal delay means connected via switch means, front left digital signal line, front center digital signal line, surround left Left digital low connected to each of the digital signal lines via switch means. A low-frequency component extracting means, an output of the low-frequency component extracting means for the left, each of the low-frequency digital signal line, a signal delay means for the left connected through a switch means, a front right digital signal line, a front center digital signal line, Each of the surround right digital signal lines is connected to each of the right low-frequency component extraction means and the output of the right low-frequency component extraction means via the switching means, and each of the low-frequency digital signal lines is connected to each of the surround low digital signal lines via the switching means. A connected right signal delay means, a front left signal conversion means for converting the output of the front left signal delay means into an analog signal, and a front right signal conversion means for converting the output of the front right signal delay means into an analog signal, Surround left signal conversion means for converting the output of the surround left signal delay means into an analog signal, and the output of the surround right signal delay means for analog signal Right center signal converting means for converting the output of the front center signal delay means into an analog signal, and low range / center converting the output of the low frequency / center signal delay means into an analog signal Signal conversion means, left signal conversion means for converting the output of the left signal delay means into an analog signal, right signal conversion means for converting the output of the right signal delay means into an analog signal, front left signal conversion means, front Outputs from the right signal converting means, the surround left signal converting means, the surround right signal converting means, the front center signal converting means, the low frequency / center signal converting means, the left signal converting means, and the right signal converting means are added and combined. , Front left speaker output, front right speaker output,
In a multi-channel signal processing device including an output for a surround left speaker, an output for a surround right speaker, an output for a front center speaker, and an output for a woofer speaker, whether or not to use each speaker Based on whether or not the speaker to be reproduced has sufficient low-frequency reproduction capability, the combination of ON / OFF of each of the switch means and the output generation means is selected to obtain an appropriate output according to the speaker used. Characterized by 5. The multi-channel signal processing device according to claim 4, further comprising respective input lines for the central left digital signal and the central right digital signal, the central left digital signal line being provided via a switch means. ,
Connect to the front center signal line or low frequency digital signal line, the center left digital signal line through the switch means,
Connected to the low frequency component extraction means for the left, the center right digital signal line, through the switch means,
Connect to the low-frequency digital signal line or the front center signal line, the center right digital signal line through the switch means,
It is characterized in that it is connected to the right low-frequency component extraction means, and the output generation means is further provided with an output for the center left speaker and an output for the center right speaker. 6. The multi-channel signal processing device according to claim 5, wherein the output generation means switches between the output for the center left speaker and the first multi-source output, and switches between the output for the center right speaker and the second multi-source output. Things characterized by being things. 7. The multi-channel signal processing device according to claim 1, wherein a variable attenuating means is provided at an output of the left signal converting means, and a variable attenuating means is provided at an output of the right signal converting means. What is characteristic. 8. A multi-channel signal processing method for receiving at least a front left digital signal, a front right digital signal, and a low frequency digital signal, and generating an analog signal for reproducing them by at least a front left speaker and a front right speaker. , The front left digital signal is subjected to digital delay processing, then converted to an analog signal to generate the front left analog signal, and the front right digital signal is subjected to digital delay processing and then analog The signal is converted to a signal to generate the front right analog signal, the low frequency digital signal for the left separated from the low frequency digital signal for the front left speaker is subjected to delay processing by digital processing, and then converted to an analog signal for the left. Generates a low frequency analog signal and separates it from the low frequency digital signal for the front right speaker. The digital signal is subjected to delay processing by digital processing, then converted to an analog signal to generate a low-frequency analog signal for the right, and the low-frequency analog signal for the left is added to the front-left analog signal for the front-left speaker. A multi-channel signal processing method characterized in that an analog signal is generated, a low-frequency analog signal for the right is added to the front right analog signal, and an analog signal for the front right speaker is generated.