JP2009206612A - Audio apparatus, sound reproduction method, sound reproduction program and recording medium thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a comfortable bass by using a woofer. <P>SOLUTION: A low-pass component generating part 310 generates a low-pass component signal SAA<SB>j</SB>(j=C to SR) corresponding to the woofer from separated channel signals SCA<SB>C</SB>to SCA<SB>SR</SB>being other channel signals. A correlation evaluating part 330 evaluates correlation between a separated channel signal SCA<SB>LFE</SB>being a low-pass sound effect channel signal and a separated channel signal SCA<SB>j</SB>. A bass signal generating part 340 performs adjustment by reducing the amount when the correlation is strong, while increasing it when weak with respect to the low-pass component signal SAA<SB>j</SB>, and adds the adjusted signal to a low-pass delay signal SDA<SB>LFE</SB>delayed by a delaying part 320. A sub-woofer speaker 131<SB>SW</SB>being the woofer outputs sound resulting from the addition. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an audio device, an audio reproduction method, an audio reproduction program, and a recording medium on which the audio reproduction 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. Such an acoustic device sometimes lacks a low-pitched feeling.

  For this reason, in order to compensate for the lack of bass feeling, an acoustic apparatus that can obtain a clear bass effect by generating a bass signal from an audio channel signal has been proposed (see Patent Document 1: hereinafter, “conventional example”). "). This prior art technique enhances a bass signal by generating a bass component from an audio channel signal and adding the bass component to the audio channel signal itself.

JP 2007-67628 A

  However, in the above-described conventional technique, the generated bass component is added to the audio channel signal itself, so that a speaker for an audio channel (for example, a left channel, a right channel, etc. in the 2-channel stereo system) that is not dedicated to the bass is used. When the aperture is small, the generated bass signal may not be effectively reproduced and output. For this reason, the conventional technique often cannot obtain a sufficient bass effect.

  By the way, with the spread of DVD (Digital Versatile Disk) and the like, acoustic devices that support multi-channel surround systems such as 5.1 channels and 7.1 channels have spread. In the 5.1 channel or 7.1 channel multi-channel surround system, a low-frequency sound effect channel (LFE channel) is prepared as an audio channel, and a subwoofer speaker that is a low-frequency speaker for the LFE channel is used.

  Since such an LFE channel signal is an auxiliary audio channel signal to the last, bass sounds derived from the LFE channel signal are often not output from the subwoofer speaker, which is a low-frequency dedicated speaker. In such a case, the user feels low bass.

  For this reason, there is a demand for a new technology capable of reproducing and outputting low-frequency sound capable of producing an appropriate low-frequency effect from a low-frequency speaker such as a subwoofer speaker that is good at low-frequency reproduction output. Meeting this demand is one of the problems to be solved by the present invention.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an audio device and a sound reproduction method that can obtain a comfortable low-frequency sound using a low-frequency speaker.

  The invention according to claim 1 is an acoustic device that outputs a sound from a plurality of speakers including a bass speaker and at least one other speaker to a sound field space, as a result of reproducing audio content having a predetermined channel configuration. Channel signal generating means for generating a plurality of channel signals including a low-frequency effect channel signal from the audio content; and having a correlation with each of at least one other channel signal other than the low-frequency effect channel signal; A low-frequency component generating means for generating a low-frequency component low-frequency component signal corresponding to the low-frequency speaker; and evaluating the correlation between the low-frequency effect sound channel signal and each of the at least one other channel signal Each of the low-frequency component signals at a ratio determined based on an evaluation result by the evaluation unit An acoustic device, characterized in that it comprises a; superimposed to a bass signal generating means for generating a bass signal output toward the woofer.

  According to a tenth aspect of the present invention, there is provided an acoustic apparatus for outputting sound from a plurality of speakers including a low-frequency speaker and at least one other speaker to a sound field space as a result of reproducing audio content having a predetermined channel configuration. An audio reproduction method used for generating a plurality of channel signals including a low-frequency effect channel signal from the audio content; and at least one other channel signal other than the low-frequency effect channel signal; A low-frequency component generating step for generating a low-frequency component signal having a correlation with each of the low-frequency component signal; an evaluation step for evaluating a correlation between the low-frequency sound effect channel signal and each of the at least one other channel signal; Each of the low-frequency component signals is superimposed at a ratio determined based on the evaluation result in the evaluation step. The bass signal generation step of generating a bass signal output toward the woofer; an audio reproducing method characterized by comprising a.

  The invention described in claim 11 is a sound reproduction program characterized by causing a calculation means to execute the sound reproduction method according to claim 10.

  A twelfth aspect of the present invention is a recording medium in which the sound reproduction program according to the eleventh aspect is recorded so as to be readable by a calculation means.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. In the following description and drawings, the same or equivalent elements will be denoted by the same reference numerals, and redundant description will be omitted.

[Constitution]
FIG. 1 is a block diagram illustrating a schematic configuration of an audio device 100 according to an embodiment. In the following description, it is assumed that the receiving apparatus 100 employs the 5.1 channel surround system, which is one of the multichannel surround systems.

  As shown in FIG. 1, the acoustic device 100 includes a control unit 110 and a drive unit 120.

In addition, the acoustic device 100 includes a sound output unit 130 _C , a sound output unit 130 _L , a sound output unit 130 _R , a sound output unit 130 _SL , a sound output unit 130 _SR, and a sound output unit 130 _SW. ing.

Here, the sound output unit 130 _C has a center speaker 131 _C. The sound output unit 130 _L includes a left speaker 131 _L , and the sound output unit 130 _R includes a right speaker 131 _R. The sound output unit 130 _SL has a surround left speaker 131 _SL , and the sound output unit 130 _SR has a surround right speaker 131 _SR . The sound output unit 130 _SW has a subwoofer speaker 131 _SW .

  Furthermore, the acoustic device 100 includes a display unit 140 and an operation input unit 150.

The elements 120, 130 _{C to} 130 _SW , 140, 150 other than the control unit 110 are connected to the control unit 110.

  The control unit 110 performs overall control of the audio device 100. Details of the control unit 110 will be described later.

  When a recording medium RM such as a DVD in which audio content is recorded is inserted into the drive unit 120, the drive unit 120 reports that fact to the control unit 110. When the drive unit 120 receives the audio content reproduction instruction DVC from the control unit 110 in a state where the recording medium RM is inserted, the drive unit 120 reads out the audio designated for reproduction from the recording medium RM. The result of reading out the audio content is sent to the control unit 110 as content data CTD that is an audio signal.

  It is assumed that audio content is recorded on the recording medium RM in the 5.1 channel surround system. In the 5.1 channel surround system, as an audio channel, a center channel (hereinafter also referred to as “C channel”), a left channel (hereinafter also referred to as “L channel”), a right channel (hereinafter also referred to as “R channel”). ), Surround left channel (hereinafter also referred to as “SL channel”), surround right channel (hereinafter also referred to as “SR channel”), and low-frequency sound effect channel (hereinafter also referred to as “LFE channel”). .

Each of the sound output units 130 _{C to} 130 _SW includes an amplifier that amplifies the sound output signals AOS _{C to} AOS _LFE received from the control unit 110 in addition to the speakers 131 _{C to} 131 _SW described above. These sound output units 130 _{C to} 130 _SW reproduce and output music in accordance with the audio output signals AOS _{C to} AOS _LFE sent from the control unit 110.

  The display unit 140 is based on, for example, (i) a display device such as a liquid crystal panel, an organic EL (Electro Luminescence) panel, or a PDP (Plasma Display Panel), and (ii) display control data sent from the control unit 110. 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 display data IMD from the control unit 110.

  The operation input unit 150 includes a key unit provided in the main body of the audio device 100 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 100 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 from the operation input unit 150 to the control unit 110 as operation input data IPD.

  Next, the control unit 110 will be described. As described above, the control unit 110 performs overall control of the audio device 100. The control unit 110 includes a control processing unit 111 and a channel signal processing unit 112 as shown in FIG. The control unit 110 also includes an analog conversion unit 113 and a volume adjustment unit 114.

  The control processing unit 111 controls the drive unit 120, the display unit 140, and the sound volume adjustment 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 signal processing unit 112 processes the content data CTD sent from the drive unit 120 and generates channel processing signals PCD _{C to} PCD _LFE corresponding to the speakers 131 _{C to} 131 _SW , respectively. As shown in FIG. 3, the channel signal processing unit 112 having such a function includes a channel separation unit 210 as a channel signal generation unit, a bass enhancement unit 220, and a delay unit 230 as another channel signal delay unit. ing.

The channel separation unit 210 receives the content data CTD from the drive unit 120. Then, the channel separation unit 210 expands the content data CTD and generates a digital sound data signal that is an audio signal. Subsequently, the channel separation unit 210 analyzes the generated digital sound data signal and corresponds the digital sound data signal to the C to LFE channels in the 5.1 channel surround system according to the channel designation information included in the digital sound data signal. Are separated into six separated channel signals SCA _C , SCA _L , SCA _SL , SCA _R , SCA _SR and SCA _LFE . Of the separated signals, separated channel signals SCA _{C to} SCA _SR are sent to the bass emphasis unit 220 and the delay unit 230. The separated channel signal SCA _LFE is sent to the bass emphasis unit 220.

The bass enhancement unit 220 receives the separated channel signals SCA _{C to} SCA _LFE from the channel separation unit 210 and generates a channel processing signal PCD _LFE , which is a bass signal output to the subwoofer speaker 131 _SW . As shown in FIG. 4, the bass enhancement unit 220 having such a function includes a low-frequency component generation unit 310 as low-frequency component generation means and a delay unit 320 as low-frequency effect sound channel signal delay means. Yes. Further, the bass emphasis unit 220 includes a correlation evaluation unit 330 as an evaluation unit and a bass signal generation unit 340 as a bass signal generation unit.

The low frequency component generation unit 310 receives the separation channel signals SCA _{C to} SCA _LFE from the channel separation unit 210 and generates low frequency component signals SAA _{C to} SAA _LFE . As shown in FIG. 5, the low-frequency component generation unit 310 having such a function includes a low-frequency enhancement unit 311 as a low-frequency enhancement unit, a low-pass filter (LPF) unit 312 as a filter unit, and a compensation unit. And an all-pass filter (APF) unit 313.

The low frequency enhancement unit 311 includes individual low frequency enhancement units 311 _{C to} 311 _SR . Each of the individual low frequency enhancement units 311 _j (j = C to SR) receives, for example, a separation channel signal SCA _j having a frequency distribution of sound pressure levels shown in FIG. Then, the individual low frequency enhancing unit 311 _j extracts a signal of a predetermined frequency band from the separated channel signal SCA _j, and generates a low frequency signal having a frequency of 1 / N (N times period) based on the extracted signal. To do. Subsequently, the individual low-frequency enhancement unit 311 _j compares the sound pressure level of the separated channel signal SCA _{j with} the sound pressure level of the generated low-frequency signal, and the sound pressure level of the low-frequency signal so that both signals are smoothly connected. Adjust. Thereafter, the individual low-frequency enhancement unit 311 _j adds the low-frequency signal subjected to level adjustment and the separated channel signal SCA _j . The signal thus added is output to the LPF unit 312 as, for example, the low-frequency enhancement signal SSA _j having the frequency distribution of the sound pressure level shown in FIG.

Here, the value of N is larger than 1. The N and the predetermined frequency band are determined in advance based on experiments, simulations, experiences, and the like from the viewpoint of generating a low-frequency component signal in a low frequency band corresponding to the subwoofer speaker 131 _SW . In the present embodiment, N is an integer of 2 or more.

Note that the low-frequency enhancement signal SSA _j generated by the low-frequency enhancement unit 311 has a delay of time DL1 compared to the separated channel signal SCA _j .

Returning to FIG. 5, the LPF unit 312 includes LPFs 312 _{C to} 312 _SR . Each of the LPFs 312 _j (j = C to SR) is configured as a digital filter such as an infinite impulse response filter (IIR), and the low-frequency enhancement signal SSA from the individual low-frequency enhancement unit 311 _j of the low-frequency enhancement unit 311. Receive _j . The LPF 312 _j selectively allows a frequency component lower than a predetermined frequency to pass. The signal passing through the LPF 312 _j in this manner is sent to the APF unit 313 as a signal SLA _j .

Incidentally, in the filtering process in the LPF 312 _j, a signal SLA _j having passed through the LPF 312 _j has occurred delay time DL2. Further, the signal SLA _{j that} has passed through the LPF 312 _j has a phase change having frequency characteristics as shown in FIG. 7A, for example, in the vicinity of the cutoff frequency FC.

Returning to FIG. 5, the APF unit 313 includes APFs 313 _{C to} 313 _SR . Each of the APFs 313 _j (j = C to SR) is configured as a digital filter such as an infinite impulse response filter (IIR). The APF unit 313 has a frequency phase characteristic that cancels out the phase change in the above-described LPF 312 _j as shown in FIG. 7B, for example.

APF313 _j receives the signal SLA _j from LPF 312 _j of the LPF 312, together with the passing signals SLA _j at all frequency ranges, for example, as shown in FIG. 7 (C), was varied in the LPF 312 _j Compensate the phase of the signal SLA _j . The signal that has passed through the APF 313 _j in this manner is sent to the bass signal generator 340 as the low-frequency component signal SAA _j .

Returning to FIG. 4, the delay unit 320 receives the separated channel signal SCA _LFE from the channel separation unit 210. Then, the delay unit 320 delays the separated channel signal SCA _LFE by a time (DL1 + DL2) that substantially matches the delay time generated in the process in the low frequency component generation unit 310 described above. Thereby, the separated channel signal SCA _LFE and the low frequency component signal SAA _j (j = C to SR) output from the low frequency component generator 310 are synchronized. The delay result is sent to the bass signal generator 340 as a low-frequency delay signal SDA _LFE .

The correlation evaluation unit 330 includes individual correlation evaluation units 331 _{C to} 331 _SR as shown in FIG. Each of the individual correlation evaluation units 331 _j (j = C to SR) receives the separation channel signal SCA _j and the separation channel signal SCA _LFE from the channel separation unit 210. Then, the individual correlation evaluation unit 331 _j evaluates the correlation between the separated channel signal SCA _LFE and the separated channel signal SCA _j that is another channel signal. Here, this correlation is evaluated using a known correlation coefficient R _j .

The correlation coefficient R _j takes a value in the range from −1 to 1. The correlation coefficient R _j is a positive value if the correlation (hereinafter also simply referred to as “correlation”) between the separated channel signal SCA _LFE and the separated channel signal SCA _j that is another channel signal is positive. If it is out of phase, it takes a negative value. The correlation coefficient R _j takes a value close to “1” if the correlation is strong, and takes a value close to “0” if the correlation is weak.

Subsequently, the individual correlation evaluation unit 331 _j generates the individual gain control signal MXS _j based on the evaluation result using the correlation coefficient R _j . When generating the individual gain control signal MXS _j , if the correlation is strong, the individual correlation evaluation unit 331 _j performs an adjustment to reduce the gain of the low-frequency component signal SAA _j with respect to a bass signal generation unit 340 described later so that the correlation is If it is weak, adjustment is performed to increase the gain of the low-frequency component signal SAA _j . As a result, it is possible to suppress excessive reproduction of bass sounds when the correlation is strong in the normal phase, or cancellation and reproduction of bass sounds when the correlation is strong in the reverse phase. In addition, when the correlation is weak, the bass can be emphasized, and a comfortable bass feeling can be obtained. The gain control signal MXS including the individual gain control signals MXS _{C to} MXS _SR generated in this way is sent to the bass signal generation unit 340.

The bass signal generator 340 includes variable multipliers 341 _{C to} 341 _SR and an adder 342 as shown in FIG.

Each of the variable multipliers 341 _j (j = C to SR) receives the low frequency component signal SAA _j from the low frequency component generator 310 and the individual gain control signal MXS _j from the correlation evaluation unit 330. Then, the variable multiplier 341 _j multiplies the low-frequency component signal SAA _j by the coefficient specified by the individual gain control signal MXS _j . The variable multiplier 341 _j outputs this multiplication result to the adder 342.

Adder 342 receives the multiplication results from variable multipliers 341 _{C to} 341 _SR and also receives low-frequency delayed signal SDA _LFE from delay unit 320. Then, the adding unit 342 adds these multiplication results and the low-frequency delay signal SDA _LFE . The addition unit 342 outputs the addition result to the analog conversion unit 113 as a channel processing signal (bass signal) PCD _LFE .

Returning to FIG. 3, the delay unit 230 receives the separated channel signals SCA _{C to} SCA _SR from the channel separation unit 210. Then, each of the separation channel signals SCA _{C to} SCA _SR is delayed by a time (DL1 + DL2) that substantially matches the delay time generated in the processing process in the low frequency component generation unit 310 of the bass enhancement unit 220 described above. As a result, synchronization between the separated channel signal SCA _j (j = C to SR) and the channel processing signal PCD _LFE that is a bass signal output from the bass emphasis unit 220 is achieved. The delay results are output to the analog conversion unit 113 as channel processing signals PCD _{C to} PCD _SR .

Returning to FIG. 2, the analog conversion unit 113 converts the channel processing signals PCD _{C to} PCD _LFE , which are digital signals sent from the channel signal processing unit 112, into analog signals. The analog conversion unit 113 includes six DA (Digital to Analogue) converters configured similarly to each other corresponding to the six types of digital signals. Analog signals PBS _{C to} PBS _LFE , which are conversion results by the analog conversion unit 113, are sent to the volume adjustment unit 114.

The volume controller 114 receives the analog signals PBS _{C to} PBS _LFE from the analog converter 113. Then, the volume adjustment unit 114 adjusts the volume in accordance with the volume adjustment command VLC from the control processing unit 111 for each of the analog signals PBS _{C to} PBS _LFE . The adjustment result is output to the sound output units 130 _{C to} 130 _SW as audio output signals AOS _{C to} AOS _LFE .

  Next, the control processing unit 111 will be described. This control processing part 111 demonstrates the function of the audio equipment 100, controlling the other component mentioned 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 reproduction command DVC to the drive unit 120, and controls data reading of the reproduction content.

The control unit 111 controls the sound volume adjustment section 114 adjusts the output volume from the speaker 131 _C to 131 _SW of the sound output unit 130 _C to 130 DEG _SW. 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 114.

[Operation]
Next, the operation of the acoustic device 100 configured as described above will be described mainly focusing on bass signal generation processing.

When a user inserts a recording medium RM such as a DVD into the drive unit 120 and inputs a playback command designating audio content to the operation input unit 150, the fact is sent to the control processing unit 111 as operation input data IPD. (See FIG. 2). Upon receiving this playback command, the control processing unit 111 issues a playback command DVC to the drive unit 120 and controls data reading of the playback content. Under such control, the content data CTD read from the recording medium RM is sent to the channel separation unit 210 (see FIG. 3). Upon receiving the content data CTD, the channel separation unit 210 expands and analyzes the content data CTD, and six SCA _C , SCA _L , SCA _SL , SCA _R corresponding to the _C to LFE channels in the 5.1 channel surround system. , SCA _SR and SCA _LFE . Of the separated signals, separated channel signals SCA _{C to} SCA _SR are sent to the bass emphasis unit 220 and the delay unit 230. The separated channel signal SCA _LFE is sent to the bass emphasis unit 220.

In the bass enhancement unit 220, the low frequency component generation unit 310 receives the separated channel signals SCA _{C to} SCA _SR , and the delay unit 320 receives the separated channel signal SCA _LFE . Further, the correlation evaluation unit 330 receives the separated channel signals SCA _{C to} SCA _LFE (see FIG. 4).

In the low frequency component generation unit 310 that has received the separated channel signal SCA _j (j = C to SR), first, the low frequency enhancement signal SSA _j is generated in each of the individual low frequency enhancement units 311 _{j in} the low frequency enhancement unit 311. (See FIG. 5). When generating the low-frequency enhancement signal SSA _j , the individual low-frequency enhancement unit 311 _j extracts a signal of a predetermined frequency band from the separated channel signal SCA _j and, based on the extracted signal, reduces the frequency of the 1 / N frequency. Generate a band signal. The individual low frequency enhancement unit 311 _j compares the sound pressure level of the separated channel signal SCA _{j with} the sound pressure level of the low frequency signal, and adjusts the sound pressure level of the low frequency signal so that both signals are smoothly connected. Then, the low-frequency signal subjected to level adjustment and the separated channel signal SCA _j are added. The low frequency enhancement signal SSA _j generated in this way is output toward the LPF unit 312.

In the LPF unit 312 that has received the low frequency enhancement signal SSA _j , each of the LPFs 312 _j selectively passes a frequency component lower than a predetermined frequency. The signal that has passed through the LPF 312 _j is output to the APF unit 313 as the signal SLA _j .

In the APF unit 313, each of the APFs 313 _j compensates for a phase change that occurs in the filtering process in the LPF 312 _j . The signal that has passed through the APF 313 _j is output to the bass signal generation unit 340 as the low-frequency component signal SAA _j .

The delay unit 320 receives the separated channel signals SCA _LFE is only time to substantially coincide with the delay time caused in the process in the low-frequency component generation unit 310 (DL1 + DL2), delays the separation channel signal SCA _LFE. The delay result is output to the bass signal generation unit 340 as the low-frequency delay signal SDA _LFE .

Further, in the correlation evaluation unit 330 that has received the separated channel signals SCA _{C to} SCA _LFE , the individual correlation evaluation unit 331 _{j in} the correlation evaluation unit 330 uses the correlation coefficient R _j , and the separated channel signal SCA _LFE The correlation with the separated channel signal SCA _j which is another channel signal is evaluated (see FIG. 8). Then, the individual correlation evaluation unit 331 _j generates the individual gain control signal MXS _j based on the correlation evaluation result. The individual gain control signals MXS _{C to} MXS _SR generated in this way are sent to the bass signal generation unit 340 as the gain control signal MXS.

In the bass signal generator 340 that has received the low-frequency component signals SAA _{C to} SAA _SR and the low-frequency delay signal SDA _LFE , first, the variable multiplier 341 _j (j = C to SR) is designated by the individual gain control signal MXS _j. The low frequency component signal SAA _j is multiplied by the obtained coefficient (see FIG. 9). The multiplication result is sent to the adding unit 342. The adder 342 adds these multiplication results and the low frequency delay signal SDA _LFE, and outputs the result to the analog converter 113 as a channel processing signal PCD _LFE which is a bass signal.

Further, the analog processing unit 113 receives the channel processing signal PCD _j obtained by delaying the separated channel signal SCA _j by time (DL1 + DL2) in the delay unit 230.

Thereafter, the channel processing signals PCD _{C to} PCD _LFE are converted into analog signals by the analog conversion unit 113, and further, the volume adjustment unit 114 performs volume adjustment to generate audio output signals AOS _{C to} AOS _LFE. . Then, the audio output signals AOS _{C to} AOS _LFE are supplied to the sound output units 130 _{C to} 130 _SW (see FIG. 2).

As a result, the sound reflecting the other channel signal recorded on the CD is output from the speakers 131 _{C to} 131 _SR, and the sound reflecting the LFE channel signal and the bass signal generated from the other channel signal is output from the subwoofer speaker. 131 is output from _SW .

As described above, in the present embodiment, the low-frequency component generation unit 310 uses the low-frequency component signal SAA _j (in the low frequency band corresponding to the bass speaker from the separated channel signals SCA _{C to} SCA _SR which are other channel signals. j = C to SR). In addition, the correlation evaluation unit 330 performs correlation evaluation between the separated channel signal SCA _LFE that is a low-frequency effect sound channel signal and the separated channel signal SCA _j that is another channel signal. Then, the bass signal generation unit 340 performs gain adjustment for the low frequency component signal SAA _j if the correlation is strong, and decreases the gain amount, and if the correlation is weak, the gain adjustment increases the gain amount. It is added to the low-frequency delay signal SDA _LFE . The sound reflecting the addition result is output from the subwoofer speaker 131 _SW which is a bass speaker. For this reason, it is possible to suppress excessive reproduction of bass sounds when the correlation is strong in the normal phase, or cancellation and reproduction of bass sounds when the correlation is strong in the reverse phase. Further, when the correlation is weak, bass can be emphasized. Further, since the sound derived from the bass signal is output from the subwoofer speaker 131 _SW, which is a bass speaker, the output speaker corresponding to the other channel signal does not need to have a diameter that follows the low frequency band.

In the present embodiment, an APF unit 313 is provided to compensate for a phase change of the signal SLA _j (j = C to SR) that occurs when the signal passes through the LPF unit 312. For this reason, in the bass signal generation unit 340, signals in phase can be added.

In the present embodiment, the delay units 230 and 320 are provided, and the low frequency component signal SAA _j (j = C to SR) input to the bass signal generation unit 340 and the low frequency delay signal SDA _LFE are synchronized. ing. For this reason, the bass signal generation unit 340 can perform addition of synchronized signals.

  Therefore, according to the present embodiment, a comfortable bass feeling can be obtained using the bass speaker.

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

For example, in the above embodiment, the correlation evaluation unit performs a correlation evaluation between the separated channel signal SCA _j (j = C to SR), which is another channel signal, and the separated channel signal SCA _LFE . On the other hand, for example, as shown in FIG. 10, the correlation evaluation unit 330 _</ b> B generates the low frequency component signal SAA _j generated by the low frequency component generation unit 310 and the low frequency delay signal output from the delay unit 320. You may make it perform correlation evaluation between SDA _LFE . Further, correlation evaluation may be performed between the signal SLA _j that has passed through the LPF unit 312 of the low-frequency component generation unit 310 and the low-frequency delay signal SDA _LFE output from the delay unit 320.

  In the above embodiment, the cut-off frequency in the LPF unit 312 is a fixed value. However, the control processing unit 111 may control the cut-off frequency according to the user's designation. In this case, the control processing unit 111 also controls the phase guarantee function in the APF unit 113.

  In the above embodiment, the signal output from the channel separation unit is a digital acoustic signal, and the bass enhancement unit performs bass enhancement processing on the digital acoustic signal. On the other hand, the signal output from the channel separation unit may be converted into an analog sound signal, and the bass emphasis unit may perform bass emphasis processing on the analog sound signal.

  In the above embodiment, it is assumed that the audio content has a channel configuration including the LFE channel. However, in the case where the audio content has a channel configuration not including the LFE channel, the channel separation unit is used as the LFE channel signal. A cello level signal may be generated.

  In the above embodiment, six speakers are provided. However, if the speaker includes a low-frequency speaker and a speaker that outputs sound reflecting other channel signals, the speaker configuration may be any way. Also good.

  In the above-described embodiment, the drive unit 120 is a drive unit for a recording medium such as a DVD, but may be a fixed disk. Furthermore, it can be a broadcast wave receiving circuit for radio broadcasting or terrestrial digital television broadcasting, an audio input circuit for an external device, or the like.

  The control unit in the above embodiment is configured as a computer system including a central processing unit (CPU: Central Processor Unit) and a DSP (Digital Signal Processor), and functions of the control processing unit and the like are also realized by executing a program. Can be. These programs may be acquired in the form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in the form of delivery via a network such as the Internet. Good.

1 is a block diagram schematically showing a configuration of an audio device according to an embodiment of the present invention. It is a block diagram which shows the structure of the control unit of FIG. It is a block diagram which shows the structure of the channel signal processing part of FIG. It is a block diagram which shows the structure of the bass emphasis part of FIG. It is a block diagram which shows the structure of the low frequency component production | generation part of FIG. It is a figure for demonstrating the production | generation process of a low region reinforcement signal. It is a figure for demonstrating the phase change in a low-pass filter, and the phase compensation in an all-pass filter. It is a block diagram which shows the structure of the correlation evaluation part of FIG. It is a block diagram which shows the structure of the bass signal production | generation part of FIG. It is a figure for demonstrating a modification.

Explanation of symbols

100: Acoustic device 131 _{C to} 131 _SR : Speaker (other speaker)
131 _SW … Speaker (low-frequency speaker)
210: Channel separation unit (channel signal generation means)
230 ... Delay section (other channel signal delay means)
310 ... Low frequency component generation unit (low frequency component generation means)
311 ... Low frequency enhancement part (low frequency enhancement means)
312 ... Low-pass filter section (filter means)
313 ... All-pass filter section (compensation means)
320 ... Delay unit (low-frequency effect sound channel signal delay means)
330 ... Correlation evaluation unit (evaluation means)
340 ... Bass signal generator (bass signal generator)

Claims (12)

An audio device that outputs audio from a plurality of speakers including a low-frequency speaker and at least one other speaker to a sound field space, as a result of reproducing audio content having a predetermined channel configuration,
Channel signal generating means for generating a plurality of channel signals including low-frequency sound effect channel signals from the audio content;
Low-frequency component generating means for generating a low-frequency component signal in a low frequency band corresponding to the low-frequency speaker, having a correlation with each of at least one other channel signal other than the low-frequency effect sound channel signal;
Evaluation means for evaluating a correlation between the low-frequency sound channel signal and each of the at least one other channel signal;
A bass signal generating means for generating a bass signal to be output to the bass speaker by superimposing each of the low-frequency component signals at a ratio determined based on an evaluation result by the evaluation means;
An acoustic device comprising: The low frequency component generating means includes
Low-frequency enhancing means for enhancing the component of the low frequency band in each of at least one other channel signal other than the low-frequency sound effect channel signal;
Filter means for extracting a component of the low frequency band in each of the signals enhanced by the low frequency enhancement means;
The acoustic device according to claim 1, comprising:   The acoustic apparatus according to claim 2, wherein the low-frequency component generation unit further includes a compensation unit that compensates for a phase change caused by the filter unit. The predetermined channel configuration includes a low frequency sound effect channel,
The low-frequency sound channel signal is a signal corresponding to a component of the low-frequency sound channel in the audio content.
The acoustic device according to any one of claims 1 to 3, wherein A low-frequency effect sound channel signal delay means for delaying the low-frequency effect sound channel signal by a time corresponding to a generation time in the low-frequency component generation means;
The bass signal generating means superimposes each of the low-frequency component signals at a ratio determined based on an evaluation result by the evaluation means on the signal via the low-frequency effect sound channel signal delay means.
The acoustic device according to claim 4.   The acoustic device according to claim 5, wherein the evaluation unit performs the evaluation based on the low-frequency sound effect channel signal and each of the at least one other channel signal.   The evaluation means performs the evaluation based on the low-frequency effect channel signal and the low-frequency band signal generated intermediately or finally in the low-frequency component generation means. The acoustic device according to claim 5. The predetermined channel configuration does not include a low-frequency sound effect channel,
The low-frequency sound channel signal is a zero level signal;
The evaluation means evaluates that there is no correlation between the low-frequency sound channel signal and each of the at least one other channel signal;
The acoustic device according to any one of claims 1 to 3, wherein Further comprising other channel signal delay means for delaying the other channel signal by a time corresponding to the generation time in the low frequency component generating means,
The other channel signal delay means is arranged in a path toward the other speaker after the other channel signal branches to the low frequency component generation means.
The acoustic device according to any one of claims 1 to 8, wherein An audio playback method used in an audio device that outputs audio content reproduction results having a predetermined channel configuration from a plurality of speakers including a low-frequency speaker and at least one other speaker to a sound field space. ,
A channel signal generating step of generating a plurality of channel signals including a low-frequency effect channel signal from the audio content;
A low-frequency component generation step of generating a low-frequency component signal having a correlation with each of at least one other channel signal other than the low-frequency effect sound channel signal;
An evaluation step of evaluating a correlation between the low-frequency sound effect channel signal and each of the at least one other channel signal;
A bass signal generation step of generating a bass signal to be output to the bass speaker by superimposing each of the low-frequency component signals at a ratio determined based on an evaluation result in the evaluation step;
An audio playback method comprising:   An audio reproduction program for causing an arithmetic means to execute the audio reproduction method according to claim 10.   12. A recording medium in which the sound reproduction program according to claim 11 is recorded so as to be readable by an arithmetic means.

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