JP2009225407A - Acoustic apparatus, audio reproducing method, audio reproducing program and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an acoustic apparatus capable of imparting a proper reflected reverberation effect. <P>SOLUTION: In an individual reflected reverberation sound imparting section 210A<SB>1</SB>, a non-correlation section 215 which has received signals SCD<SB>L</SB>and SCD<SB>SR</SB>applies non-correlation processing for removing correlation between the signal SCD<SB>L</SB>and the signal SCD<SB>SR</SB>to the signal SCD<SB>L</SB>, and generates a signal NCD<SB>L</SB>. Subsequently, a reflected sound signal generating section 216 generates a reflected reverberation sound signal RDA<SB>L</SB>based on the signal NCD<SB>L</SB>. Then, an adding section 212 adds the signal SCD<SB>SR</SB>to the reflected reverberation sound signal RDA<SB>L</SB>, superimposes the reflected reverberation sound signal RDA<SB>L</SB>having no correlation with the signal SCD<SB>SR</SB>to the signal SCD<SB>SR</SB>, and generates a signal PCD<SB>SR</SB>transmitted to a speaker unit corresponding to the signal SCD<SB>SR</SB>. In an individual reflected reverberation sound imparting section 210A<SB>2</SB>, similarly to the case of the individual reflection reverberation sound imparting section 210A<SB>1</SB>, the adding section 212 superimposes a reflected reverberation sound signal RDA<SB>R</SB>having no correlation with a signal SCD<SB>SL</SB>to the signal SCD<SB>SL</SB>, and generates a signal PCD<SB>SL</SB>transmitted to a speaker unit corresponding to the signal SCD<SB>SL</SB>. <P>COPYRIGHT: (C)2010,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.

  Conventionally, audio apparatuses that reproduce music and the like have been widely used. Such an acoustic device is generally installed in a general house or vehicle and is used by a user. The technology related to such an audio device has been remarkably developed, and a technology has been proposed in which a reflected reverberation sound generated in a concert hall or the like is simulated (see Patent Document 1, etc .: hereinafter referred to as “conventional example”).

  In such a conventional technique, a reflected reverberation signal whose amplitude level and delay time regularly change is generated based on a predetermined channel signal of the main sound signal. The generated reflected reverberation signal and the channel signal corresponding to the speaker to which the reflected reverberation sound should be output are added.

No. 8-2720

  In the conventional technique, the generated reflected reverberation signal and the channel signal corresponding to the speaker to which the reflected reverberation sound is to be output are added to generate an acoustic signal to be reproduced and output from the speaker. As a result, if the reflected reverberation effect is already taken into account in the channel signal on which the reflected reverberation signal is superimposed and has a strong in-phase correlation, the signals to be added strengthen each other. A reflection reverberation sound effect will be produced. In addition, when the channel signal on which the reflected reverberation signal is superimposed has a strong anti-phase correlation with the reflected reverberation signal, the added signals cancel each other, so that the reflected reverberation effect cannot be realized. Instead, the sound effect intended to be expressed by the channel signal is reduced.

  For this reason, in consideration of the aspect of the channel signal on which the reflected reverberant signal is superimposed, a technique that can appropriately exhibit the reflected reverberant effect is desired. Meeting this requirement 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 thereof is to provide an audio device and an audio reproduction method capable of imparting an appropriate reflected reverberation effect.

  The invention according to claim 1 is an acoustic device that outputs sound from a plurality of speakers including a first speaker and a second speaker toward a sound field space, and outputs a first channel signal corresponding to the first speaker. Based on a reverberation sound signal corresponding to the reverberation sound of the reproduced sound from the first speaker; and the reflection reverberation signal generated by the generation means; and the second speaker. Synthesizing the second channel signal and supplying the second channel signal to the second speaker; and the generating unit generates the reflected reverberation signal in consideration of a correlation with the second channel signal. It is a characteristic acoustic device.

  A sixth aspect of the present invention is an audio reproduction method for outputting audio from a plurality of speakers including a first speaker and a second speaker to a sound field space, and a first channel signal corresponding to the first speaker. Generating a reflected reverberant signal corresponding to the reflected reverberant sound of the reproduced sound from the first speaker, and corresponding to the reflected reverberant signal generated in the generating step and the second speaker Synthesizing the second channel signal to be supplied to the second speaker, and generating the reflected reverberation signal in consideration of the correlation with the second channel signal in the generating step. Is an audio reproduction method characterized by the above.

  According to a seventh aspect of the present invention, there is provided a voice reproduction program characterized by causing a calculation means to execute the voice reproduction method according to the sixth aspect.

  The invention according to claim 8 is a recording medium in which the sound reproduction program according to claim 7 is recorded so as to be readable by the 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.

<Configuration>
FIG. 1 is a block diagram illustrating a schematic configuration of an acoustic device 100A according to the first embodiment. In the following description, it is assumed that the acoustic device 100A is a device mounted on the vehicle CR (see FIG. 2). In addition, the acoustic device 100A performs processing on an acoustic signal of a 4-channel surround system that is one of the multi-channel surround systems. Here, the 4-channel surround sound signal includes a left channel (hereinafter referred to as “L channel”), a right channel (hereinafter referred to as “R channel”), a surround left channel (hereinafter referred to as “SL channel”), and An acoustic signal having a 4-channel configuration of surround light channels (hereinafter referred to as “SR channels”) is assumed.

As shown in FIG. 1, the acoustic device 100 </ b> A includes a control unit 110 </ b> A and a drive unit 120. The acoustic device 100 </ b> A includes speaker units 130 _{L to} 130 _SR , a display unit 140, and an operation input unit 150.

  The control unit 110A performs overall control of the entire sound device 100A. Details of the control unit 110A 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 110A. When the drive unit 120 receives the audio content reproduction instruction DVC from the control unit 110A 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 110A as content data CTD that is an audio signal. It is assumed that audio content is recorded on the recording medium RM in a 4-channel surround system.

The speaker units 130 _{L to} 130 _SR correspond to the _{L to SR} channels. Each of these speaker units 130 _j (j = L to SR) reproduces and outputs sound in accordance with the output audio signal AOS _j in the output audio signal sent from the control unit 110A.

In the present embodiment, as shown in FIG. 2, the speaker unit 130 _L is arranged in front door housing the passenger side. The speaker unit 130 _L is arranged so as to face the front passenger seat side.

The speaker unit 130 _R is disposed in the front door housing on the driver's seat side. The speaker unit 130 _R is arranged to face the driver's seat side.

The speaker unit 130 _SL is arranged in the housing on the rear side of the passenger seat. The speaker unit 130 _SL is arranged to face the rear seat on the passenger seat side.

In addition, speaker unit 130 _SR is disposed in a housing on the rear side of the driver's seat. The speaker unit 130 _SR is disposed so as to face the rear seat on the driver's seat side.

Sound is output from the speaker units 130 _{L to} 130 _SR arranged as described above toward the sound field space ASP.

It is assumed that the assumed listening position P is at the position of the driver's seat in the sound field space ASP. As a result, with respect to the assumed listening position P, the speaker unit 130 _L and the speaker unit 130 _SR are arranged at diagonal positions, and the speaker unit 130 _R and the speaker unit 130 _SL are arranged at diagonal positions. It has become.

  Returning to FIG. 1, the display unit 140 is sent from, 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) a control unit 110A. A display controller such as a graphic renderer for controlling the entire display unit 140 based on the display control data, and (iii) a display image memory for storing display image data are provided. The display unit 140 displays operation guidance information and the like according to display data IMD from the control 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 control unit 110A.

  Next, the control unit 110A will be described. As described above, the control unit 110A performs overall control of the acoustic device 100A. As shown in FIG. 3, the control unit 110 </ b> A includes a channel separation unit 111 and a reflected reverberation imparting unit 112 </ b> A. The control unit 110 </ b> A includes an analog processing unit 113 and a control processing unit 115.

The channel separation unit 111 receives the content data CTD from the drive unit 120. Then, the channel separation unit 111 expands the content data CTD and generates a digital sound data signal that is an audio signal. Subsequently, the channel separation unit 111 analyzes the generated digital sound data signal, and converts the digital sound data signal corresponding to the L to SR channels in the 4-channel surround system according to the channel designation information included in the digital sound data signal. The signals SCD _L , SCD _R , SCD _SL , and SCD _SR are separated. The signals SCD _{L to} SCD _SR separated in this way are sent to the reflected reverberation adding unit 112A.

Note that when the content data CTD is L, and the data of the two-channel stereo system R-channel, based on the contents data CTD, signal SCD _L, generates the SCD _R, signal SCD _SL, as SCD _SR, A so-called zero level signal is generated.

The reflected reverberation imparting unit 112A receives the signals SCD _{L to} SCD _SR from the channel separation unit 111. Then, the reverberant sound adding unit 112A performs a reflection reverberant applying process on the signals SCD _{L to} SCD _SR .

Incidentally, in the first embodiment, a reflection reverberation signal for the signal SCD _L corresponding to the speaker units 130 _L, to the speaker unit 130 _SR disposed in diagonal positions of the speaker unit 130 _L with respect to assumed listening position P and it is adapted to superimpose the corresponding signal SCD _SR. Moreover, superimposing a reflection reverberation sound signal for the signal SCD _R corresponding to the speaker unit 130 _R, the signal SCD _SL corresponding to the speaker units 130 _SL disposed in diagonal positions of the speaker unit 130 _R relative to assumed listening position P It is supposed to let you.

As shown in FIG. 4, the reflected reverberation imparting unit 112 </ _b > A having such a function includes individual reflected reverberation imparting units 210 </ _b > A ₁ and 210 </ _b > A ₂ . The reflection reverberation imparting unit 112A sends intact aspect signal SCD _L, and sends to the analog processing unit 113 as the signal PCD _L, as it aspect signal SCD _R, as a signal PCD _R to the analog processing unit 113 It is like that.

The individual reflection reverberation adding unit 210A ₁ receives the signals SCD _L and SCD _SR from the channel separation unit 111. The individual reflection reverberation imparting unit 210A ₁ superimposes the reflected reverberation sound signal for the signal SCD _L to the signal SCD _SR.

The individual reverberation reverberating unit 210A ₂ receives the signals SCD _R and SCD _SL from the channel separation unit 111. The individual reflection reverberation imparting unit 210A ₂ superimposes the reflected reverberation sound signal for the signal SCD _R to the signal SCD _SL.

As shown in FIG. 5, the individual reverberation reverberation unit 210A ₁ (210A ₂ ) having the above functions includes a reverberation reverberation signal generation unit 211A as a generation unit and an addition unit 212 as a synthesis unit. ing.

The reflected reverberation signal generation unit 211A receives the signals SCD _L (SCD _R ) and SCD _SR (SCD _SL ) from the channel separation unit 111. Then, the reflected reverberation signal generation unit 211A generates a reflected reverberation signal related to the signal SCD _L (SCD _R ). The reflected reverberation signal generation unit 211A having such a function includes a decorrelation unit 215 as a decorrelation unit and a reflection sound signal generation unit 216 as a signal generation unit.

The decorrelation unit 215 receives the signals SCD _L (SCD _R ) and SCD _SR (SCD _SL ) from the channel separation unit 111. Then, the decorrelation unit 215 performs a decorrelation process on the signal SCD _L (SCD _R ) to remove the correlation with the signal SCD _SR (SCD _SL ). The signal generated by the decorrelation process NCD _L (NCD _R) is sent to the reflected sound signal generation unit 216.

  In the first embodiment, the decorrelation unit 215 is configured as an adaptive filter. That is, the decorrelation unit 215 includes a digital filter unit 251, a subtraction unit 252, and a coefficient calculation unit 253, as shown in FIG.

In the present embodiment, the digital filter unit 251 is configured as a FIR (Finite Impulse Response) filter. The digital filter unit 251 receives the signal SCD _SR (SCD _SL ) from the channel separation unit 111. Then, the digital filter unit 251 performs a filtering operation in accordance with the coefficient designation CEF from the coefficient calculation unit 253. The digital filter unit 251 having such a function includes M delay units 256 _{1 to} 256 _M , (M + 1) coefficient multipliers 257 _{0 to} 257 _M, and an adder 258.

Each of the delay units 256 _j (j = 1 to M) delays the input signal X _j−1 (T) by a unit delay time τ and outputs it as a signal X _j (T). Here, the signal X ₀ (T) is the signal SCD _SR (SCD _SL ) from the channel separation unit 111. As a result, the relationship between the signal X _j (T) and the signal X ₀ (T) is expressed by the following equation (1).
X _j (T) = X ₀ (T−j · τ) (1)

In this embodiment, each of the delay units 256 _j samples and outputs the signal X _j−1 (T) in synchronization with a reference clock (not shown) having a period τ. For this reason, during the unit delay time τ, the sampling result is held in the delay unit 256 _j and output.

The signal X _j (T) generated by the delay unit 256 _j is sent to the coefficient multiplier 257 _j . A signal X ₀ (T) is sent to the coefficient multiplier 257 ₀ . The signal X _M (T) is also sent to the coefficient calculation unit 253.

Each of the coefficient multipliers 257 _m (m = 0 to M) receives the signal X _m (T) and the tap coefficient V _m (T) in the coefficient designation CEF from the coefficient calculation unit 253. Then, the coefficient multiplier 257 _m multiplies the signal X _m (T) by the tap coefficient V _m (T). The result of the multiplication is sent to the adding unit 258.

The adder 258 receives the multiplication results [X ₀ (T) · V ₀ (T)] to [X _M (T) · V _M (T)] by the coefficient multipliers 257 _{0 to} 257 _M. Then, the adding unit 258 calculates the signal Y (T) by the following equation (2) and sends it to the subtracting unit 252.
Y (T) = X ₀ (T) · V ₀ (T) +... + X _M (T) · V _M (T) (2)

The subtracting unit 252 receives the signal SCD _L (SCD _R ) (= Z (T)) from the channel separating unit 111 and the signal Y (T) from the digital filter unit 251. Then, the subtraction unit 252 calculates the error signal E (T) by the following equation (3).
E (T) = Z (T) -Y (T) (3)

The signal E (T) calculated in this way is sent to the reflected sound signal generation unit 216 and the coefficient calculation unit 253 as a signal NCD _L (NCD _R ).

The coefficient calculation unit 253 receives the signal X _M (T) from the digital filter unit 251 and the signal E (T) from the subtraction unit 252. Then, the coefficient calculation unit 253 calculates the tap coefficient V _m (T + τ) to be used next time by the following equation (4).
V _m (T + τ) = V _m (T) + μ · E (T) · X _m (T) (4)
Here, the value μ is an update step parameter that determines the convergence strength in the adaptive control, and is determined in advance based on experiments, simulations, experiences, and the like from the viewpoint of exerting an appropriate reflected reverberation effect.

The tap coefficients V ₀ (T + τ) to V _M (T + τ) calculated in this way are sent to the digital filter unit 251 as coefficient designation CEF for use at time (T + τ). More specifically, the tap coefficient V _m (T + τ) is sent to the coefficient multiplier 257 _m described above. As a result, the tap coefficient supplied to the coefficient multiplier 257 _m is updated.

By the decorrelation unit 215 configured as described above, the correlation with the signal SCD _SR (SCD _SL ) is removed from the signal SCD _L (SCD _R ).

Returning to FIG. 5, the reflected sound signal generation unit 216 receives the signal NCD _L (NCD _R ) from the decorrelation unit 215. Then, the reflected sound signal generation unit 216, based on a signal NCD _L (NCD _R), generates a reflected sound. It reflected sound signal generation unit 216 having such a function, as shown in FIG. 7 includes a M delay unit 261 ₁ ~261 _M, and M damping unit 262 ₁ ~262 _M, an addition unit 263 ing.

Each of the delay units 261 _m (m = 1 to M) delays the input signal X _m−1 (T) by a delay time T _D to generate a signal X _m (T). The signal X _m (T) generated by the delay unit 261 _m is sent to the attenuation unit 262 _m .

Here, the signal X ₀ (T) is the signal NCD _L (NCD _R ) from the decorrelation unit 215. As a result, the relationship between the signal X ₀ (T) and the signal X _m (T) is expressed by the following equation (5).
X _m (T) = X ₀ (Tm · T _D ) (5)

The delay time T _D, in view of the reflected sound effects, experiments, simulations, based on experience and the like, are predetermined.

Each of the attenuation units 262 _m (m = 0 to M) receives the signal X _m (T). Then, the attenuation unit 262 _m multiplies the signal X _m (T) by the coefficient K _m . The multiplication result is sent to the adding unit 263.

Here, the coefficient K _m is expressed by the following equation (6).
K _m = r ^m (6)

  The constant r is a constant less than 1, and is determined in advance from the viewpoint of the reflected sound effect based on experiments, simulations, experiences, and the like.

The adder 263 receives the multiplication results [K ₁ · X ₁ (T)] to [K _M · X _M (T)] by the attenuators 262 _{1 to} 262 _M. Then, the adder 263 adds these multiplication results to generate a reflected sound signal. Thus the signal SCD _SR (SCD _SL) is generated reflected sound signal having no correlation, as reflected reverberation signal RDA _L (RDA _R), it is fed to the adder 212.

Returning to FIG. 5, the addition unit 212 receives a signal from the channel separation section 111 SCD _SR (SCD _SL) and reflected reverberation sound signal RDA _L from the reflection reverberation sound signal generation unit 211A (RDA _R). The adding unit 212 adds the signal SCD _SR (SCD _SL) and the reflection reverberation sound signal RDA _L (RDA _R).

As a result, the signal SCD _SR (SCD _SL) signal reflected reverberation signal RDA _L (RDA _R) is superimposed on the PCD _SR (PCD _SL) is generated. The signal PCD _SR (PCD _SL ) generated in this way is sent to the analog processing unit 113.

Returning to FIG. 3, the analog processing unit 113 receives the signals PCD _{L to} PCD _SR from the reflected reverberation applying unit 112A. Then, the analog processing unit 113 generates output audio signals AOS _{L to} AOS _SR under the control of the control processing unit 115 and sends them to the speaker units 130 _{L to} 130 _SR . As illustrated in FIG. 8, the analog processing unit 113 having such a function includes a DA (Digital to Analogue) conversion unit 231, a volume adjustment unit 232, and a power amplification unit 233.

The DA converter 231 receives the signals PCD _{L to} PCD _SR from the reflected reverberation generator 112A. Then, the DA converter 231 converts the signals PCD _{L to} PCD _SR into analog signals. The DA converter 231 includes four DA converters configured in the same manner, corresponding to four types of digital signals. Analog signals ACS _{L to} ACS _SR which are conversion results by the DA conversion unit 231 are sent to the volume adjustment unit 232.

The sound volume adjustment unit 232 receives the analog signals ACS _{L to} ACS _SR from the DA conversion unit 231. Then, the volume adjustment unit 232 performs volume adjustment processing on the analog signals ACS _{L to} ACS _{SR in} accordance with the volume adjustment command VLC from the control processing unit 115. In the present embodiment, the volume adjusting unit 232 includes four electronic volume elements and the like that are similarly configured to correspond to four analog signals. Analog signals VCS _{L to} VCS _SR that are adjustment results by the volume adjustment unit 232 are sent to the power amplification unit 233.

The power amplification unit 233 receives the analog signals VCS _{L to} VCS _SR from the volume adjustment unit 232. The power amplifying unit 233 power-amplifies the analog signals VCS _{L to} VCS _SR . The power amplifying unit 233 includes four power amplifiers configured in the same manner corresponding to four types of analog signals. Output audio signals AOS _{L to} AOS _SR which are amplification results by the power amplifier 233 are sent to the speaker units 130 _{L to} 130 _SR .

  Returning to FIG. 3, the control processing unit 115 will be described next. This control processing unit 115 exerts the function of the acoustic device 100A while controlling other components. The control processing unit 115 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 115 issues a reproduction command DVC to the drive unit 120, and controls data reading of the reproduction content.

In addition, the control processing unit 115 controls the volume adjustment unit 232 to adjust the output volume from the speaker units 130 _{L to} 130 _SR . When controlling the output volume, the control processing unit 115 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 232.

<Operation>
Next, the operation of the acoustic device 100A configured as described above will be described mainly focusing on the reflected reverberation processing.

  When the user inserts the recording medium RM into the drive unit 120 and inputs a reproduction command designating audio content to the operation input unit 150, this is sent to the control processing unit 115 as operation input data IPD (FIG. 3). Upon receiving this playback command, the control processing unit 115 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 111 (see FIG. 3). Upon receiving the content data CTD, the channel separation unit 111 develops and analyzes the content data CTD, and separates it into four signals SCD _{L to} SCD _SR corresponding to the _{L to SR} channels in the 4-channel surround system. The separated signals SCD _{L to} SCD _SR are sent to the reflected reverberation adding unit 112A (see FIG. 3).

Signal SCD _L ~SCD _SR reflection reverberation imparting unit 112A that received the intact aspect signal SCD _L, and sends to the analog processing unit 113 as the signal PCD _L, the signal SCD _R as it aspect, the signal PCD _R To the analog processing unit 113 (see FIG. 4). On the other hand, in the reverberation reverberation unit 112A, the individual reverberation units 210A ₁ and 210A ₂ perform the reverberation unit.

Such a reflective reverberation imparting process, individual reflection reverberation imparting unit 210A ₁ may be superimposed reflection reverberation sound signal concerning the signal SCD _L to the signal SCD _SR. Further, the individual reflections reverberation imparting unit 210A ₂ may be superimposed reflection reverberation sound signal for the signal SCD _R to the signal SCD _SL.

More specifically, in the individual reflection reverberation adding unit 210A ₁ , the decorrelation unit 215 that has received the signals SCD _L and SCD _SR removes the correlation with the signal SCD _{SR from the} signal SCD _L. The signal is processed and sent to the reflected sound signal generation unit 216 as a signal NCD _L. The reflected sound signal generation unit 216 that has received the signal NCD _L generates a reflected sound based on the signal NCD _L as described above, and sends the reflected sound to the adding unit 212 as a reflected reverberation sound signal RDA _L (see FIG. 5).

Then, the addition unit 212, by adding the signal SCD _SR and reflected reverberation sound signal RDA _L, the signal SCD _SR, is superimposed without reflection reverberation sound signal RDA _L correlation of the signal SCD _SR, signal PCD _SR Is generated. The signal PCD _SR generated in this way is sent to the analog processing unit 113 (see FIG. 5).

On the other hand, the individual reverberation reverberating unit 210A ₂ generates the signal PCD _SL by superimposing the reverberant reverberation signal RDA _R related to the signal SCD _R on the signal SCD _SL in the same manner as the individual reverberant reverberating unit 210A _1. To do. The signal PCD _SL generated in this way is sent to the analog processing unit 113 (see FIG. 5).

Thereafter, the signal PCD _L ~PCD _SR is converted at DA conversion unit 231 into an analog signal ACS _L ~ACS _SR. Subsequently, the volume adjustment unit 232 performs volume adjustment processing on the analog signals ACS _{L to} ACS _{SR in} accordance with the volume adjustment command VLC from the control processing unit 115, and outputs the analog signals VCS _{L to} VCS _SR to the power amplification unit 233. Send (see FIG. 8).

Power amplification unit 233 which has received the analog signal VCS _L ~VCS _SR is an analog signal VCS _L ~VCS _SR and power amplification, to produce an output audio signal AOS _L ~AOS _SR, and sends to the speaker units 130 _L to 130 DEG _SR . Then, the speaker units 130 _{L to} 130 _SR reproduce and output sound according to the output sound signals AOS _{L to} AOS _SR .

As a result, the L and R channel audio in the audio content is reproduced and output from the speaker units 130 _L and 130 _R. In addition, the speaker unit 130 _SL reproduces and outputs the sound in which the reflected reverberation sound of the R channel sound in an aspect not correlated with the SL channel sound is superimposed on the SL channel sound in the sound content. In addition, the speaker unit 130 _SR reproduces and outputs the sound in which the reflected reverberation sound of the L channel sound in an aspect not correlated with the SR channel sound is superimposed on the SR channel sound in the sound content.

As described above, in this first embodiment, in a separate reflection reverberation imparting unit 210A _1, the signal SCD _L, decorrelation unit 215 which receives the SCD _SR is, with respect to the signal SCD _L, and the signal SCD _SR The signal NCD _L is generated by performing decorrelation processing for removing the correlation. Subsequently, the reflected sound signal generation unit 216 generates a reflected reverberation signal RDA _L based on the signal NCD _L. Then, the addition unit 212, by adding the signal SCD _SR and reflected reverberation sound signal RDA _L, the signal SCD _SR, is superimposed without reflection reverberation sound signal RDA _L correlation of the signal SCD _SR, the speaker unit 130 _A signal PCD _SR to be supplied to the _SR is generated.

Further, in the individual reflection reverberation imparting unit 210A _2, as in the case of the deposition unit 210A ₁ individual reflection reverberation, the signal SCD _SL, is superimposed without reflection reverberation sound signals RDA _R correlation of the signal SCD _SL, A signal PCD _SL to be supplied to the speaker unit 130 _SL is generated.

For this reason, the speaker unit 130 _SL can reproduce and output a sound in which the reflected reverberation sound of the R channel sound in a manner not correlated with the SL channel sound is superimposed on the SL channel sound in the sound content. In addition, the speaker unit 130 _SR can reproduce and output the sound in which the reflected reverberation sound of the L channel sound in a manner not correlated with the SR channel sound is superimposed on the SR channel sound in the sound content.

  Therefore, according to the first embodiment, it is possible to prevent the reflection reverberation effect from becoming excessive or to reduce the acoustic effect intended to be expressed by the channel on which the reflection reverberation sound is superimposed. It is possible to realize a reverberant reverberation effect.

In the first embodiment, the reflected reverberation sound of the L channel sound reproduced and output from the speaker unit 130 _{L is} from the speaker unit 130 _SR arranged at the diagonal position of the speaker unit 130 _{L with} respect to the assumed listening position P. Output. Further, the reflected reverberation sound of the R channel sound reproduced and output from the speaker unit 130 _R is output from the speaker unit 130 _SL disposed at the diagonal position of the speaker unit 130 _{R with} respect to the assumed listening position P. For this reason, a more appropriate reflected sound effect can be realized.

[Second Embodiment]
Next, a second embodiment of the present invention will be described mainly with reference to FIGS.

<Configuration>
FIG. 9 is a block diagram illustrating a schematic configuration of the acoustic device 100B according to the second embodiment. As shown in FIG. 9, the acoustic device 100B is different from the acoustic device 100A of the first embodiment described above (see FIG. 1) in that a control unit 110B is provided instead of the control unit 110A. This control unit 110B is different from the above-described control unit 110A (see FIG. 3) only in that it includes a reverberation reverberation unit 112B having the configuration shown in FIG. 10 instead of the reverberation reverberation unit 112A. Is different. Hereinafter, this difference will be mainly described.

As shown in FIG. 10, the reflected reverberation sound providing unit 112 </ _b > B replaces the individual reverberation sound providing units 210 </ _b > A ₁ and 210 </ _b > A ₂ as compared with the above-described reflected reverberation sound applying unit 112 </ _b > B (see FIG. 4). The reverberation sound providing units 210B ₁ and 210B ₂ are provided. As shown in FIG. 11, these individual reverberation reverberation units 210B ₁ and 210B ₂ are replaced with the reverberation reverberation signal generator 211A as compared with the individual reverberation reverberation units 210A ₁ and 210A ₂ described above. The difference is that a reflected reverberation signal generator 211B is provided.

  As shown in FIG. 11, the reflected reverberation signal generation unit 211B includes a correlation evaluation unit 217 as an evaluation unit and an attenuation unit 218 as an attenuation unit. The reflected reverberation signal generation unit 211B includes a reflected sound generation unit 216 as a reflected sound signal generation unit.

The correlation evaluation unit 217 receives the signals SCD _L (SCD _R ) and SCD _SR (SCD _SL ) from the channel separation unit 111. Subsequently, the correlation evaluation unit 217 evaluates the correlation between the signal SCD _L (SCD _R ) and the signal SCD _SR (SCD _SL ), and as a result, the signal SCD _SR (SCD _SL ) and reflected reverberation sound described later. The correlation with the signal RDB _L (RDB _R ) is evaluated. Based on the result of the evaluation, an attenuation control signal ACB _L (ACB _R ) designating a coefficient to be set in the attenuation unit 218 is generated.

When generating such an attenuation control signal ACB _L (ACB _R ), the correlation evaluating unit 217 correlates in phase or in phase according to the amount of correlation between the signals SCD _L (SCD _R ) and SCD _SR (SCD _SL ). The value of the coefficient is determined in such a manner that the coefficient is reduced as the strength increases and the coefficient is increased as the correlation is weak. In the second embodiment, the coefficient changes in a range from “0” to “1”. The attenuation control signal ACB _L (ACB _R ) specifying the coefficient thus determined is sent to the attenuation unit 218.

The attenuating unit 218 receives the signal SCD _L (SCD _R ) from the channel separation unit 112 and the attenuation control signal ACB _L (ACB _R ) from the correlation evaluation unit 217. Then, the attenuation unit 218 multiplies the signal SCD _L (SCD _R ) by a coefficient specified by the attenuation control signal ACB _L (ACB _R ). As a result, the signal _{SCD L (SCD R), SCD} SR (SCD SL) is greater the stronger the correlation in phase or opposite phase, a small attenuation rate the weaker the correlation, the signal SCD _L (SCD _R) is attenuated. The multiplication result by the attenuation unit 218 is sent to the reflected sound signal generation unit 216 as a signal ATD _L (ATD _R ).

The reflected sound signal generation unit 216 operates based on the signal ATD _L (ATD _R ) in the same manner as in the first embodiment described above to generate a reflected sound signal. The reflected sound signal generated in this way is sent to the adding unit 212 as a reflected reverberation sound signal RDB _L (RDB _R ).

<Operation>
Next, the operation of the acoustic device 100B configured as described above will be described by mainly focusing on the reflected reverberation process.

  When the user inserts the recording medium RM into the drive unit 120 and inputs a playback command designating audio content to the operation input unit 150, as in the case of the first embodiment, this is indicated as the operation input data IPD. And sent to the control processing unit 115. Upon receiving this playback command, the control processing unit 115 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 111 as in the case of the first embodiment. Upon receiving the content data CTD, the channel separation unit 111 develops and analyzes the content data CTD, and separates it into four signals SCD _{L to} SCD _SR corresponding to the _{L to SR} channels in the 4-channel surround system. The separated signals SCD _{L to} SCD _SR are sent to the reflected reverberation adding unit 112B.

The reverberant sound giving unit 112B that has received the signals SCD _{L to} SCD _SR receives the signal SCD _L as it is as the signal PCD _L and sends it to the analog processing unit 113 in the same manner as the reflected reverberation giving unit 112A in the first embodiment. and it sends, as it aspect signal SCD _R, and sends a signal PCD _R to the analog processing unit 113 (see FIG. 10). On the other hand, in the reverberation reverberation imparting unit 112B, the individual reverberation reverberation imparting units 210B ₁ and 210B ₂ perform reflection reverberation imparting processing.

Such a reflective reverberation imparting process, individual reflection reverberation imparting unit 210B ₁ is, to superimpose the reflected reverberation sound signal concerning the signal SCD _L to the signal SCD _SR. Further, the individual reflections reverberation imparting unit 210B ₂ may be superimposed reflection reverberation sound signal for the signal SCD _R to the signal SCD _SL.

More specifically, in the individual reflection reverberation imparting unit 210B _1, the signal SCD _L, correlation evaluation section 217 which receives the SCD _SR is by evaluating the correlation between the signal SCD _L and the signal SCD _SR, therefore, a signal SCD _SR, the evaluation of the correlation between the reflection reverberation sound signals RDB _L to be described later performed. Then, the correlation evaluation part 217, based on the result of the evaluation, generates an attenuation control signal ACB _L specifying the coefficients to be set in the attenuation section 218, and sends to the attenuation section 218 (see FIG. 11).

Upon generation of such attenuation control signals ACB _L, the correlation evaluating unit 217, the signal SCD _L, corresponding to the amount of correlation between SCD _SR, to reduce the coefficient stronger the correlation in phase or opposite phase, the weaker the correlation coefficient The coefficient value is determined in a range from “0” to “1”.

Attenuation unit 218 which has received the attenuation control signal ACB _L is the signal SCD _L from the channel separation section 112, multiplied by a specified coefficient by the attenuation control signal ACB _L, the multiplication result as the signal ATD _L (ATD _R), It is sent to the reflected sound signal generator 216 (see FIG. 11). Here, the signal SCD _L, the stronger the correlation SCD _SR is in phase or reverse phase increases, a smaller attenuation rate the weaker the correlation, the signal SCD _L is attenuated, the signal ATD _L is generated.

The reflected sound signal generation unit 216 that has received the signal ATD _L generates a reflected sound signal based on the signal ATD _L in the same manner as in the first embodiment described above, and adds the reflected sound signal as the reflected reverberation sound signal RDB _L. 212 (see FIG. 11). Then, the addition unit 212, by adding the signal SCD _SR and reflected reverberation sound signals RDB _L, signal SCD _SR, signal SCD _L reflected reverberation sound signals the signal level corresponding to the correlation is adjusted with RDB _L is superimposed to generate a signal PCD _SR . The signal PCD _SR generated in this way is sent to the analog processing unit 113 (see FIG. 11).

On the other hand, in the individual reflection reverberation imparting unit 210B ₂ , the reflected reverberation signal RDB _R related to the signal SCD _R is superimposed on the signal SCD _SL in the same manner as in the individual reflection reverberation imparting unit 210B ₁ , and the signal PCD. Generate _SL . The signal PCD _SL generated in this way is sent to the analog processing unit 113 (see FIG. 11).

Thereafter, in the same manner as in the first embodiment, the signal PCD _L ~PCD _SR is converted into an analog signal ACS _L ~ACS _SR in DA conversion section 231. Subsequently, the volume adjustment unit 232 performs volume adjustment processing on the analog signals ACS _{L to} ACS _{SR in} accordance with the volume adjustment command VLC from the control processing unit 115, and outputs the analog signals VCS _{L to} VCS _RSR to the power amplification unit 233. Send (see FIG. 8).

Power amplification unit 233 which has received the analog signal VCS _L ~VCS _SR, as in the case of the first embodiment, and power amplifies the analog signal VCS _L ~VCS _SR, generating an output audio signal AOS _L ~AOS _SR And sent to the speaker units 130 _{L to} 130 _SR . Then, the speaker units 130 _{L to} 130 _SR reproduce and output sound according to the output sound signals AOS _{L to} AOS _SR .

As a result, the L and R channel audio in the audio content is reproduced and output from the speaker units 130 _L and 130 _R. In addition, the speaker unit 130 _SL reproduces and outputs the sound in which the reverberation sound of the R channel sound having the volume level corresponding to the correlation with the SL channel sound is superimposed on the SL channel sound in the sound content. In addition, the speaker unit 130 _SR reproduces and outputs the sound in which the reverberant sound of the L channel sound having the volume level corresponding to the correlation with the SR channel sound is superimposed on the SR channel sound in the sound content.

As described above, in the second embodiment, the correlation evaluation unit 217 that receives the signals SCD _L and SCD _SR in the individual reflected reverberation imparting unit 210B ₁ performs the correlation between the signal SCD _L and the signal SCD _SR. by evaluating, the evaluation of the correlation between the signal SCD _SR and the reflection reverberation sound signals RDB _L. Then, the correlation evaluation part 217, based on the result of the evaluation, to produce the specified attenuation control signal ACB _L coefficients to be set in the attenuation section 218, and sends to the attenuation section 218.

Subsequently, the attenuation unit 218 that has received the attenuation control signal ACB _L multiplies the signal SCD _L from the channel separation unit 112 by the coefficient specified by the attenuation control signal ACB _L and uses the multiplication result as the signal ATD _L to obtain the reflected sound. The signal is sent to the signal generator 216 (see FIG. 11). Here, the signal SCD _L, the stronger the correlation SCD _SR is in phase or reverse phase increases, a smaller attenuation rate the weaker the correlation, the signal SCD _L is attenuated, the signal ATD _L is generated.

Next, the reflected sound signal generation unit 216 that has received the signal ATD _L generates a reflected sound signal based on the signal ATD _L and sends it to the adding unit 212 as a reflected reverberation sound signal RDB _L. Then, the addition unit 212, by adding the signal SCD _SR and reflected reverberation sound signals RDB _L, signal SCD _SR, signal SCD _L reflected reverberation sound signals the signal level corresponding to the correlation is adjusted with RDB _L is superimposed, and generates a signal PCD _SR to be supplied toward the speaker unit 130 _SR.

Moreover, individual reflection reverberation imparting unit 210B ₂ may operate in substantially the same manner as the deposition unit 210B ₁ individual reflection reverberation, the signal SCD _SL, reflection reverberation signal level corresponding to the correlation is adjusted with the signal SCD _R It superimposes a sound signal RDB _R, generates a signal PCD _SL to be fed toward the speaker unit 130 _SL.

For this reason, the speaker unit 130 _SL reproduces and outputs the sound in which the reflected reverberation sound of the R channel sound at the volume level corresponding to the correlation with the R channel sound is superimposed on the SL channel sound in the sound content. In addition, the speaker unit 130 _SR reproduces and outputs a sound in which the reverberant sound of the L channel sound having a volume level corresponding to the correlation with the L channel sound is superimposed on the SR channel sound in the sound content.

  Therefore, according to the second embodiment, as in the case of the first embodiment described above, the sound that is intended to be expressed by a channel in which the reflection reverberation effect is excessive or the reflection reverberation sound is superimposed. It is possible to suppress an effect from being reduced and to realize an appropriate reflected reverberation effect.

In the second embodiment, the reflected reverberation sound of the L channel sound reproduced and output from the speaker unit 130 _{L is} from the speaker unit 130 _SR arranged at the diagonal position of the speaker unit 130 _{L with} respect to the assumed listening position P. Output. Further, the reflected reverberation sound of the R channel sound reproduced and output from the speaker unit 130 _R is output from the speaker unit 130 _SL disposed at the diagonal position of the speaker unit 130 _{R with} respect to the assumed listening position P. For this reason, as in the case of the first embodiment described above, a more appropriate reflected sound effect can be realized.

[Third Embodiment]
Next, a third embodiment of the present invention will be described mainly with reference to FIGS.

<Configuration>
FIG. 12 is a block diagram illustrating a schematic configuration of an acoustic device 100C according to the third embodiment. As shown in FIG. 12, the acoustic device 100C is different from the acoustic device 100A of the first embodiment described above (see FIG. 1) in that a control unit 110C is provided instead of the control unit 110A. This control unit 110C is different from the above-described control unit 110A (see FIG. 3) only in that it includes a reverberation reverberation unit 112C having the configuration shown in FIG. 13 instead of the reverberation reverberation unit 112A. Is different. Hereinafter, this difference will be mainly described.

As shown in FIG. 13, the reflected reverberation sound imparting unit 112 </ b> C replaces the individual reverberation sound imparting units 210 </ _b > A ₁ and 210 </ _b > A ₂ as compared with the above-described reflected reverberation sound imparting unit 112 </ _b > A (see FIG. 4). The reverberation sound providing units 210C ₁ and 210C ₂ are provided. As shown in FIG. 14, these individual reverberation reverberation units 210C ₁ and 210C ₂ are replaced with the reverberation reverberation signal generator 211A as compared with the individual reverberation unit 210A ₁ and 210A ₂ described above. The difference is that a reflected reverberation signal generator 211C is provided.

  As shown in FIG. 14, the reflected reverberation sound signal generation unit 211C includes a reflected sound generation unit 216 as a reflected sound signal generation unit and a correlation evaluation unit 217 as an evaluation unit. The reflected reverberation signal generation unit 211B includes an attenuation unit 218 as an attenuation unit.

The reflected sound signal generation unit 216 operates based on the signal SCD _L (SCD _R ) from the channel separation unit 111 in the same manner as in the first and second embodiments described above, and the reflected sound signal RFD _L (RFD _R ) is generated. The reflected sound signal RFD _L (RFD _R ) generated in this way is sent to the correlation evaluation unit 217 and the attenuation unit 218.

The correlation evaluation unit 217 receives the signal SCD _SR (SCD _SL ) from the channel separation unit 111 and the reflected sound signal RFD _L (RFD _R ) from the reflected sound signal generation unit 216. Subsequently, the correlation evaluation unit 217 operates in the same manner as in the second embodiment, and evaluates the correlation between the signal SCD _SR (SCD _SL ) and the reflected sound signal RFD _L (RFD _R ). performs the signal SCD _SR (SCD _SL), the evaluation of the correlation between the later reflected reverberation sound signal RDC _L (RDC _R). Based on the result of the evaluation, an attenuation control signal ACC _L (ACC _R ) specifying a coefficient to be set in the attenuation unit 218 is generated.

Upon generation of such attenuation control signal ACC _L (ACC _R), the correlation evaluating unit 217, the signal SCD _SR (SCD _SL), corresponding to the RDC _L (RDC _R) the amount of correlation between, the second embodiment described above Similarly to the case, the coefficient value is determined in such a manner that the coefficient is decreased as the correlation is strong in the in-phase or anti-phase, and the coefficient is increased as the correlation is weak. In the third embodiment as well, in the same manner as in the second embodiment, the coefficient changes in a range from “0” to “1”. The attenuation control signal ACC _L (ACC _R ) specifying the coefficient thus determined is sent to the attenuation unit 218.

The attenuating unit 218 receives the reflected sound signal RFD _L (RFD _R ) from the reflected sound signal generating unit 216 and receives the attenuation control signal ACC _L (ACC _R ) from the correlation evaluating unit 217. Then, the attenuation unit 218 multiplies the signal reflected sound signal RFD _L (RFD _R ) by a coefficient specified by the attenuation control signal ACC _L (ACC _R ). As a result, the signal _{SCD SR (SCD SL), RDC} L (RDC R) is greater the stronger the correlation in phase or opposite phase, a small attenuation rate the weaker the correlation signal RFD _L (RFD _R) is attenuated. The multiplied damping unit 218 as a reflected reverberation signal RDC _L (RDC _R), is fed to the adder 212.

<Operation>
Next, the operation of the acoustic device 100 </ b> C configured as described above will be described mainly focusing on the reflected reverberation sound applying process.

  When the user inserts the recording medium RM into the drive unit 120 and inputs a playback command designating audio content to the operation input unit 150, as in the case of the first and second embodiments, this fact is indicated by the operation input. The data is sent to the control processing unit 115 as the data IPD. Upon receiving this playback command, the control processing unit 115 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 111 as in the first and second embodiments. Upon receiving the content data CTD, the channel separation unit 111 develops and analyzes the content data CTD, and separates it into four signals SCD _{L to} SCD _SR corresponding to the _{L to SR} channels in the 4-channel surround system. The separated signals SCD _{L to} SCD _SR are sent to the reflected reverberation adding unit 112C.

The reverberant sound adding unit 112C that has received the signals SCD _{L to} SCD _SR receives the signal SCD _L as it is as the signal PCD _{L in} the same manner as the reflected reverberant units 112A and 112B in the first and second embodiments. and it sends to the analog processing unit 113, as it aspect signal SCD _R, and sends a signal PCD _R to the analog processing unit 113 (see FIG. 13). On the other hand, in the reverberation reverberation imparting unit 112C, the individual reverberation reverberation units 210C ₁ and 210C ₂ perform the reverberation reverberation imparting process.

Such a reflective reverberation imparting process, individual reflection reverberation imparting unit 210C ₁ is to superimpose the reflected reverberation sound signal concerning the signal SCD _L to the signal SCD _SR. Further, the individual reflections reverberation imparting unit 210C ₂ may be superimposed reflection reverberation sound signal for the signal SCD _R to the signal SCD _SL.

More specifically, in applying unit 210C ₁ individual reflection reverberation, the reflected sound signal generation unit 216 which receives the signal SCD _L from the channel separation section 111, based on the signal SCD _L, generates a reflected sound signal RFD _L . The reflected sound signal RFD _L generated in this way is sent to the correlation evaluation unit 217 and the attenuation unit 218 (see FIG. 14).

Subsequently, the correlation evaluating unit 217 which receives the reflected sound signal RFD _L from the signal SCD _SR and reflected sound signal generation unit 216 from the channel separation section 111, evaluation of the correlation between the signal SCD _SR and the reflected sound signal RFD _L by, to evaluate the correlation between the signal SCD _SR and the reflection reverberation sound signals RDB _L. Then, the correlation evaluating unit 217, based on the result of the evaluation, to produce the specified attenuation control signal ACC _L coefficients to be set in the attenuation section 218, and sends to the attenuation section 218 (see FIG. 14).

Upon generation of such attenuation control signal ACC _L, the correlation evaluating unit 217, in response to the amount of correlation between the signal SCD _SR and the reflected sound signal RFD _L, to reduce the coefficient the more there is a strong correlation in phase or anti-phase The coefficient value is determined in the range from “0” to “1” in such a manner that the coefficient is increased as the correlation is weaker.

Upon receiving the attenuation control signal ACC _L , the attenuation unit 218 multiplies the reflected sound signal RFD _L from the reflected sound signal generation unit 216 by the coefficient specified by the attenuation control signal ACC _L, and multiplies the multiplication result by the winner reverberation sound signal RDC. _L is sent to the adder 212 (see FIG. 14). Here, the signal SCD _SR and reflected sound signal RFD _L is, the stronger the correlation in phase or reverse phase increases, correlation weak enough small damping factor, reflected sound signal RFD _L is attenuated, reflected reverberation signal RDC _L Is generated.

Then, the addition unit 212, by adding the signal SCD _SR and the reflection reverberation sound signal RDC _L, signal SCD _SR, reflected sound signal RFD _L and reflection reverberation signal level is adjusted to correspond to the correlation of superimposed signal RDC _L, generates a signal PCD _SR. The signal PCD _SR generated in this way is sent to the analog processing unit 113 (see FIG. 14).

On the other hand, the individual reflections reverberation imparting unit 210C _2, as in the case of the above individual reflection reverberation imparting unit 210C _1, superimposes the reflected reverberation sound signal RDC _R related to the signal SCD _R to the signal SCD _SL, the signal PCD Generate _SL . The signal PCD _SL generated in this way is sent to the analog processing unit 113 (see FIG. 14).

Thereafter, in the same manner as in the first and second embodiments, the signal PCD _L ~PCD _SR is converted at DA conversion unit 231 into an analog signal ACS _L ~ACS _SR. Subsequently, the volume adjustment unit 232 performs volume adjustment processing on the analog signals ACS _{L to} ACS _{SR in} accordance with the volume adjustment command VLC from the control processing unit 115, and outputs the analog signals VCS _{L to} VCS _RSR to the power amplification unit 233. Send (see FIG. 8).

Power amplification unit 233 which has received the analog signal VCS _L ~VCS _SR, as in the case of the first and second embodiments, the analog signal VCS _L ~VCS _SR and power amplification, the output audio signal AOS _L ~AOS _SR is generated and sent to speaker units 130 _{L to} 130 _SR . Then, the speaker units 130 _{L to} 130 _SR reproduce and output sound according to the output sound signals AOS _{L to} AOS _SR .

As a result, the L and R channel audio in the audio content is reproduced and output from the speaker units 130 _L and 130 _R. In addition, the speaker unit 130 _SL reproduces and outputs the sound in which the reverberation sound of the R channel sound having the volume level corresponding to the correlation with the SL channel sound is superimposed on the SL channel sound in the sound content. In addition, the speaker unit 130 _SR reproduces and outputs the sound in which the reverberant sound of the L channel sound having the volume level corresponding to the correlation with the SR channel sound is superimposed on the SR channel sound in the sound content.

As described above, in the third embodiment, the reflected sound signal generation unit 216 that has received the signal SCD _L in the individual reflected reverberation giving unit 210C ₁ generates the reflected sound signal RFD _L based on the signal SCD _L. It is generated and sent to the correlation evaluation unit 217 and the attenuation unit 218. Subsequently, the correlation evaluating unit 217, by evaluating the correlation between the signal SCD _SR and the reflected sound signal RFD _L, to evaluate the correlation between the signal SCD _SR and the reflection reverberation sound signals RDB _L. Then, the correlation evaluation part 217, based on the result of the evaluation, to produce the specified attenuation control signal ACC _L coefficients to be set in the attenuation section 218, and sends to the attenuation section 218.

Then, the attenuation control signal ACC _L attenuation unit 218 which has received are reflected sound by a coefficient specified by the attenuation control signal ACC _L to the reflection sound signal RFD _L from the signal generating unit 216, the multiplication result of the reflection reverberation signal RDC _L is sent to the adder 212. Here, the reflected sound signal RFD _L is attenuated at a smaller attenuation rate as the correlation between the signal SCD _SR and the reflected sound signal RFD _L increases in phase or in reverse phase, and decreases as the correlation decreases. _L is generated.

Then, the addition unit 212, by adding the signal SCD _SR and the reflection reverberation sound signal RDC _L, signal SCD _SR, reflected sound signal RFD _L and reflection reverberation signal level is adjusted to correspond to the correlation of superimposed signal RDC _L, generates a signal PCD _SR to be supplied toward the speaker unit 130 _SR.

Further, the individual reflection reverberation imparting section 210C ₂ operates in the same manner as the individual reflection reverberation provision section 210C _1, and the signal level is adjusted in accordance with the correlation between the signal SCD _SL and the reflected sound signal RFD _R. The reflected reverberation signal RDB _R is superimposed to generate a signal PCD _SL to be supplied to the speaker unit 130 _SL .

For this reason, the speaker unit 130 _SL reproduces and outputs a sound in which the reverberant sound of the R channel sound having a volume level corresponding to the correlation with the reflected sound of the R channel sound is superimposed on the SL channel sound in the sound content. In addition, the speaker unit 130 _SR reproduces and outputs the sound in which the reverberant sound of the L channel sound having the volume level corresponding to the correlation with the reflected sound of the L channel sound is superimposed on the SR channel sound in the sound content.

  Therefore, according to the third embodiment, as in the case of the first and second embodiments described above, the reflection reverberation effect is excessive, or is intended to be expressed by a channel on which the reflection reverberation sound is superimposed. It is possible to suppress the reduction of the sound effect, and to realize an appropriate reflected reverberation sound effect.

In the third embodiment, the reflected reverberation sound of the L channel sound reproduced and output from the speaker unit 130 _{L is} from the speaker unit 130 _SR arranged at the diagonal position of the speaker unit 130 _{L with} respect to the assumed listening position P. Output. Further, the reflected reverberation sound of the R channel sound reproduced and output from the speaker unit 130 _R is output from the speaker unit 130 _SL disposed at the diagonal position of the speaker unit 130 _{R with} respect to the assumed listening position P. For this reason, as in the case of the first and second embodiments described above, a more appropriate reflected sound effect can be realized.

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

  For example, in the first to third embodiments, the reflected reverberation sound of the L and R channel sounds in the 4-channel surround configuration is output from the speaker unit for the SR and SL channel sounds. On the other hand, reflected reverberation sound of SL and SR channel sound can be output from the speaker unit for R and L channel sound.

  In the first to third embodiments described above, the present invention is applied to a 4-channel surround system audio device. However, for an audio device that employs a 5.1-channel surround system or a 7.1-channel surround system. Also, the present invention can be applied.

  Further, the correlation evaluation performed by the correlation evaluation unit 217 in the second and third embodiments may be performed using a known correlation coefficient. The absolute value of the correlation coefficient takes a value closer to “1” as the correlation is stronger in phase or opposite phase, and takes a value closer to “0” as the correlation is weaker. Therefore, the correlation evaluation unit 217 sets the coefficient set in the attenuation unit 218 to “0” when the absolute value of the correlation coefficient is “1”, and “0” when the absolute value of the correlation coefficient is “0”. 1 ”.

  In the second and third embodiments described above, the variable range of the coefficient value set in the attenuation unit 218 is 0 to 1, but can be any range.

In the second embodiment, the signal SCD _L (SCD _R ) from the channel separation unit 111 is attenuated by the attenuating unit 217. However, as in the case of the third embodiment, the signal SCD _L ( The reflected sound signal generated by the reflected sound signal generation unit 216 based on (SCD _R ) may be attenuated.

  Further, in the second and third embodiments, the variable range of the coefficient set in the attenuation unit 218 and the change mode of the coefficient with respect to the change in the correlation evaluation are fixed. On the other hand, for example, in response to the designation by the user via the operation input unit 150, the control processing unit 115 designates the variable range of the coefficient and the change mode of the coefficient to the correlation evaluation unit 216. You may be able to do that.

  In the first to third embodiments, the reflected sound signal generation mode of the reflected sound signal generation unit 216 is fixed. On the other hand, for example, in response to the designation by the user via the operation input unit 150, the control processing unit 115 may designate the value of the attenuation coefficient r to the reflected sound signal generation unit 216. .

  In the first to third embodiments, the audio content recorded on the recording medium RM is read by the drive unit 120. However, the audio content is acquired by receiving a radio broadcast or a digital terrestrial television broadcast. It can also be.

  The control unit in the first to third embodiments is configured as a computer system including a central processing unit (CPU: Central Processor Unit) and a DSP (Digital Signal Processor), and includes a channel separation unit, a reverberation reverberation unit, The function of the control processing unit can also be realized by executing a program. 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 diagram schematically illustrating a configuration of an audio device according to a first embodiment of the present invention. It is a figure for demonstrating the arrangement position and assumption listening position of four speakers of FIG. It is a block diagram for demonstrating the structure of the control unit of FIG. It is a block diagram for demonstrating the structure of the reflection reverberation sound provision part of FIG. It is a block diagram for demonstrating the structure of the separate reflection reverberation sound provision part of FIG. It is a block diagram for demonstrating the structure of the decorrelation part of FIG. It is a block diagram for demonstrating the structure of the reflected sound signal generation part of FIG. It is a block diagram for demonstrating the structure of the analog process part of FIG. It is a figure which shows schematically the structure of the audio equipment which concerns on 2nd Embodiment of this invention. It is a block diagram for demonstrating the structure of the reverberation reverberation provision part in the control unit of FIG. It is a block diagram for demonstrating the structure of the separate reflection reverberation sound provision part of FIG. It is a figure which shows schematically the structure of the audio equipment concerning 3rd Embodiment of this invention. It is a block diagram for demonstrating the structure of the reflection reverberation sound provision part in the control unit of FIG. It is a block diagram for demonstrating the structure of the separate reflection reverberation sound provision part of FIG.

Explanation of symbols

100A to 100C ... Acoustic device 211A to 211C ... Reflected reverberation signal generation unit (generation means)
212 ... Adder (combining means)
215 ... decorrelation unit (correlation means)
216... Reflected sound signal generating unit (signal generating means, reflected sound signal generating means)
217 ... Correlation evaluation unit (evaluation means)
218 ... Attenuator (attenuator)

Claims (8)

An acoustic device that outputs sound from a plurality of speakers including a first speaker and a second speaker toward a sound field space,
Generating means for generating a reflected reverberant signal corresponding to the reflected reverberant sound of the reproduced sound from the first speaker based on the first channel signal corresponding to the first speaker;
Synthesis means for synthesizing the reflected reverberation signal generated by the generation means and a second channel signal corresponding to the second speaker, and supplying the synthesized signal to the second speaker;
The generating means generates the reflected reverberation signal in consideration of the correlation with the second channel signal;
An acoustic device characterized by that. The generating means includes
Decorrelating means for reducing the correlation of the first channel signal to the second channel signal;
Signal generation means for generating the reflected reverberation signal based on the decorrelation signal generated by the decorrelation means;
The acoustic device according to claim 1, comprising: The generating means includes
Evaluation means for evaluating a correlation between the first channel signal and the second channel signal;
Attenuating means for attenuating the first channel signal at an attenuation rate determined based on the evaluation result by the evaluating means;
Reflected sound signal generation means for generating the reflected reverberation sound signal based on the attenuation result by the attenuation means;
The acoustic device according to claim 1, comprising: The generating means includes
Reflected sound generation means for generating a reflected sound signal based on the first channel signal;
Evaluation means for evaluating the correlation between the reflected sound signal and the second channel signal;
Attenuating means for attenuating the reflected sound signal with an attenuation rate determined based on the evaluation result by the evaluating means to generate the reflected reverberant sound signal;
The acoustic device according to claim 1, comprising:   The said 2nd speaker is arrange | positioned in the position on the opposite side to the arrangement position of a said 1st speaker with respect to the assumption listening position in the said sound field space, The Claim 1 characterized by the above-mentioned. The acoustic device described. An audio reproduction method for outputting audio from a plurality of speakers including a first speaker and a second speaker toward a sound field space,
Generating a reflected reverberation signal corresponding to the reflected reverberation sound of the reproduced sound from the first speaker based on the first channel signal corresponding to the first speaker;
Synthesizing the reflected reverberation signal generated in the generating step and a second channel signal corresponding to the second speaker, and supplying the synthesized signal to the second speaker;
In the generation step, the reflected reverberation signal is generated in consideration of the correlation with the second channel signal.
An audio reproduction method characterized by the above.   A sound reproduction program for causing a calculation means to execute the sound reproduction method according to claim 6.   8. A recording medium in which the audio reproduction program according to claim 7 is recorded so as to be readable by an arithmetic means.

Images