JPH077800A - Stereo sound field enlarging device - Google Patents

Abstract

PURPOSE:To prevent the change of the localization of sound images and the blur of the sound images and to enlarge a sound field by simple circuit constitution. CONSTITUTION:The sound sum signals (L+R) of input left and right channels are generated by a generation circuit 1 and are defined as the sound signals of a center channel. When input is stereo sound signals, a third sound volume control circuit 8 suppresses output and the sound image is localized in the speakers of the left and right channels. When the input is monoaural sound signals, first and second sound volume control circuits 6 and 7 suppress the output and the sound image is localized in the speaker of the center channel.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stereo sound field expansion apparatus for audio multiplex broadcasting, stereo broadcasting and the like.

[0002]

2. Description of the Related Art As a method of reproducing a stereo sound field, a center speaker is arranged in addition to the left and right speakers, and each of the left and right speakers has a left channel (L) and a right channel ( There is one that supplies the R) audio signal and supplies the left and right sum signals (L + R) to the center speaker.

In such a stereo sound field reproducing apparatus, when three speakers of the left channel (L), the right channel (R) and the center channel (C) are simultaneously operated, for example, the input is the left channel (L). In the case of only the audio signal, the output comes out from the left channel and the center channel, and the speaker L of the left channel (L) and the speaker C of the center channel (C) work, and the sound image is shown in FIG. As shown in (), it is localized at L'between the speakers L and C, and the spread becomes narrow. Also, when the input is a monaural audio signal, the sound image is blurred because it comes out from the left channel, center channel, and right channel speakers L, C, and R, and the listener is slightly displaced from the center position. As shown in (b), the sound image is localized as if the sound is coming from the position C '.

To solve this problem, there is a three-stereo reproducing circuit developed by Tolby, which circuit is shown in FIG. The input left channel audio signal (L) and right channel audio signal (R) are branched into three routes. The first is
Directly to the signal coupling / distributing network, the second to the circuit for creating the volume control voltages (E _L , E _R , E _C , E _S ), and the third to the four volume control circuits 121 of the volume control circuit 120, 12
2; 123,124; 125,126; 127,128
Is input to. Volume control voltage (E _L , E _R , E _C ,
E _S ) is generated by the circuit described below. The band-pass filter 101 extracts the audio signals of the left channel (L) and the right channel (R) which are band-limited by passing only the audible band. The first generation circuit 102 generates a voice sum signal (L + R) for both channels. This voice sum signal (L + R) becomes the center channel voice signal (C). The second generation circuit 103 generates an audio difference signal (LR) by subtracting the right channel audio signal (R) from the left channel audio signal (L). This voice difference signal (L-
R) becomes the surround signal S. The audio signals of the left channel (L), the right channel (R), the center channel (C), and the surround (S) are added to the full-wave rectification circuits 104 to 107, respectively. The full-wave rectifier circuits 104 to 107 extract the voltage level according to each audio signal. The first LOG differential amplifier 108 is
The level difference between the audio signals of the left channel (L) and the right channel is detected. The second LOG differential amplifier 109 detects the level difference between the center channel (C) and surround (S) audio signals. The first dual time constant circuit 110 gives its input a time constant corresponding to the output of the first LOG differential amplifier 108. The second dual time constant circuit 111 gives its input a time constant corresponding to the output of the second LOG differential amplifier 109. The first polarity division circuit 112 receives the output of the first dual time constant circuit 110 and receives two independent control voltages E _L for the left channel and the right channel.
Generate E _R. The second polarity division circuit 113 receives the output of the second dual time constant circuit 111 and generates two independent control voltages E _C and E _S for the center channel and the surround. The first volume control circuit 121 controls the audio signal (L) of the input left channel with the control voltage E _L to add the audio output E _LL to the signal coupling / distributing network 130. The second volume control circuit 122 controls the audio signal (R) of the input right channel with the control voltage E _L and _applies the audio output E _LR to the signal coupling / distributing network 130. The third volume control circuit 123 controls the audio signal (L) of the input left channel with the control voltage E _R to add the audio output E _RL to the signal coupling / distributing network 130. Fourth
The volume control circuit 124 controls the input right channel audio signal (R) with the control voltage E _R and adds the audio output E _RR to the signal coupling distribution network 130. The fifth volume control circuit 125 controls the audio signal (L) of the input left channel by the control voltage E _C and adds the audio output E _CL to the signal coupling / distributing network 130. The sixth volume control circuit 126
The audio signal (R) of the input right channel is controlled by the control voltage E _C to output the audio output E _CR to the signal combination distribution network 130.
Add to. The seventh volume control circuit 127 has its control terminal _grounded , generates an audio output E _SL from the input left channel audio signal (L), and outputs the audio output E _SL.
Add to 0. Similarly, the eighth volume control circuit 128 has its control terminal _grounded, and outputs the audio output E _SR from the input right channel audio signal (R) to the signal combination distribution network 1.
Add to 30. The signal combination distribution network 130 performs matrix addition of the input left channel (L) and right channel (R) audio signals and the outputs E _{LL to} E _SR from the volume control circuit, and outputs the left channel output audio signal (L _out ), the output audio signal of the right channel (R _out ) and the output audio signal of the center channel (C _out ) are obtained. As described above, the Dolby 3 stereo reproduction circuit has a complicated configuration and operation.

[0005]

As described above, in the means for simultaneously operating three speakers simultaneously, the sound image changes to narrow the sound field, or when the input is a monaural audio signal, the sound image becomes blurred. The localization of the sound image changes. The Dolby-3 stereo reproduction circuit improved in this respect has a complicated structure and operation.

It is an object of the present invention to provide a stereo sound field expansion device which has a simple circuit structure and which prevents a blur of a sound image and a change in localization of the sound image to expand a sound field.

[0007]

(Structure example 1) Left channel and right channel audio signal supplying means, and signal generating means for adding left and right channel audio signals to generate a center channel audio signal , Input terminals,
It has an output terminal and a control terminal. Left, right, and center channel audio signals are supplied to each input terminal, and audio signals whose signal level is controlled at each output terminal according to the control voltage supplied to each control terminal. Of the first, second, and third volume control circuits for obtaining signals, first and second detection circuits for detecting the respective audio signal levels of the left and right channels, and the first and second detection circuits A means for comparing the outputs, supplying a control voltage according to the level difference between the left and right channel audio signals to the control terminals of the first, second and third volume control circuits, and when the level difference is large Enhances the audio signal output level of the left and right channels and suppresses the output level of the audio signal of the center channel. When the level difference is small, the left,
Suppresses the audio signal output level of the right channel,
And a control circuit for controlling to increase the output level of the audio signal of the channel.

(Structural Example 2) First channel and second channel audio signal supply means and first signal generation for subtracting the first and second channel audio signals to generate a third channel audio signal Means, second signal generation means for adding the audio signals of the first and second channels to generate an audio signal of the fourth channel, and an inverting circuit for inverting the phase of the audio signal of the third channel, respectively. A fourth channel having an input terminal, an output terminal and a control terminal, wherein the audio signal of the fourth channel is supplied to each input terminal, and the signal level is controlled at each output terminal according to the control voltage supplied to each control terminal. From the inversion circuit, first and second volume control circuits for obtaining a channel audio signal, a first addition circuit for adding the third channel audio signal and the output of the first volume control circuit, and the inverting circuit. A second adding circuit for adding an audio signal and an output of the first volume control circuit; first and second detecting circuits for detecting respective audio signal levels of the first and second channels; A control voltage corresponding to the level difference between the audio signals of the first and second channels is supplied to the control terminals of the first and second volume control circuits, including means for comparing the outputs of the first and second detection circuits. When the level difference is large, the audio signal is output from the first volume control circuit without being suppressed, and the audio signal is output from the second volume control circuit while being suppressed, and the level difference is small. The first volume control circuit outputs the audio signal while suppressing the audio signal, and the second volume control circuit outputs the audio signal without suppressing the audio signal. 1, a second adder circuit and the above First from each second volume control circuit to obtain a second and third output signals.

[0009]

(Structure example 1) When the difference between the audio signal levels of the input left channel and the right channel is large, that is, when a stereo audio signal is input, it works to suppress the output level of the audio signal of the center channel, Next stage center
Turn down the volume from the channel speaker. As a result, the sound image is localized at the left and right channel speakers. When the difference between the audio levels of the left channel and the right channel is small, that is, when a monaural audio signal is input, it works to suppress the output levels of the audio signals of the left channel and the right channel, and the left channel and the right channel of the next stage. Decrease the volume of the channel speaker. As a result, the sound image is localized on the speaker of the center channel.

As described above, the blur of the sound image and the change of the localization of the sound image are prevented, and the sound field is expanded.

(Structural Example 2) When the difference between the audio signal levels of the first channel and the second channel is large, the audio signal of the fourth channel is output from the first volume control circuit without being suppressed. Therefore, the first addition circuit outputs the double-level audio signal of the first channel, and the second addition circuit outputs the double-level audio signal of the second channel. At this time, the audio output signal from the second volume control circuit is suppressed.

When the audio signal level difference between the first channel and the second channel is small, the audio signal of the fourth channel from the first volume control circuit is suppressed. Therefore, the level of the audio output signal from the first and second adder circuits becomes small. At this time, the audio output signal from the second volume control circuit is not suppressed. As described above, the blur of the sound and the change of the localization of the sound image are prevented and the sound field is expanded.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the stereo sound field expanding apparatus of the present invention is shown in FIG. The audio signal (L) of the input left channel is
It is added to the first volume control circuit 6 of the volume control means 5. The audio signal (R) of the input right channel is applied to the second volume control circuit 7 of the volume control means 5. The generation circuit 1 adds the input left channel audio signals and the right channel audio signals to generate an audio sum signal (L + R). This voice sum signal (L + R)
Is used as the center channel audio signal (C). The voice sum signal (L + R) is applied to the third volume control circuit 8 of the volume control means 5.

The first detection circuit 2 detects the level of the audio signal (L) of the input left channel. Second detection circuit 3
Detects the level of the audio signal (R) of the input right channel. The comparison circuit 4 compares the outputs of the first and second detection circuits 2 and 3 and outputs the control voltage output corresponding to the level difference between the audio signals of the input left channel (L) and the right channel (R). It is added to the first to third volume control circuits 6, 7, and 8. This allows the left, right and center channel outputs (L
_out , R _out , C _out ).

The relationship between the level ratio (R / L) of the audio signals of the input left channel (L) and the right channel (R) and the control voltage to the first and second volume control circuits 6 and 7 is shown in FIG.
The graph is shown in (a). At this time, the left channel (L
the output level of the relationship _out) or the right channel (R _{ou t)} is a graph shown in FIG. 2 (b). As can be seen from the graph, when R / L = 1, that is, the control voltage is the lowest when a monaural audio signal is input, the output of the left channel (L _out ) and right channel (R _out ) audio signals is accompanied with this. Is the lowest level. The control voltage increases with increasing distance to both sides of R / L = 1, that is, when a stereo audio signal is being input, and the output voltage of the left channel (L _out ) and right channel (R _out ) audio signals is accordingly increased. The level increases.

The relationship between the level ratio (R / L) of the audio signals of the input left channel (L) and the right channel (R) and the control voltage to the third volume control circuit 8 is shown in FIG. 2 (C). It becomes a graph. At this time, the relationship between the output levels of the audio signals of the center channel (C _out ) becomes the graph shown in FIG. 2 (d). As can be seen from the graph, the control voltage is maximum when R / L = 1, that is, the monaural audio signal is input, and the output level of the audio signal of the center channel (C _out ) is maximum with this. The control voltage becomes smaller as the distance from both sides of R / L = 1, that is, when the stereo audio signal is input, and the audio output of the center channel (C _out ) becomes smaller accordingly.

As a result, when the input is only the audio signal (L) of the left channel or the right channel, the center
The audio output of the channel (C _out ) is suppressed, and the sound image is spun on the left channel (L) or the right channel (R).
Localize to the position of mosquito. When the input is a monaural audio signal, the audio output of the left channel (L _out ) and the right channel (R _out ) is suppressed, and the sound image is localized at the position of the speaker of the center channel (C). Even if the listener shifts the listening position to the left or right, the sound image remains localized at the position of the speaker of the center channel (C).

A second embodiment of the stereo sound field expanding apparatus of the present invention is shown in FIG. The first generation circuit 50 generates a sound difference signal (LR) by subtracting the sound signal (R) of the input right channel from the sound signal (L) of the input left channel.
The inverting amplifier circuit 51 creates an audio difference signal (-L + R) by inverting the output of the first generation circuit 50. First adder 5
The sound difference signal (LR) which is the output of the first generation circuit 50 is added to one end of the signal 2. The voice difference signal (-L + R) which is the output of the inverting amplifier 51 is added to one end of the second adder 53. The second generation circuit 54 generates an audio sum signal (L + R) by adding the audio signal (L) of the input left channel to the audio signal (L) of the input left channel. This voice sum signal (L + R) is used as the center channel voice signal (C)
And The first volume control circuit 55 uses the second generation circuit 5
4 and the common and other input terminals of the first and second adders 52 and 53. The first sound volume control circuit 55 is responsive to a first control voltage, which will be described later, to determine the first and second adders 52,
The level of the voice sum signal (L + R) applied to 53 is changed.

The second volume control circuit 56 has a second volume which will be described later.
The level of the voice sum signal (L + R) applied to the output terminal of the center channel (C) is changed in accordance with the control voltage of. The first detection circuit 57 detects the level of the audio signal (L) of the input left channel. The second detection circuit 58 detects the level of the audio signal (R) of the input right channel. The comparison circuit 59 includes the first and second detection circuits 5
The outputs of 7 and 58 are compared, and the second control voltage corresponding to the level difference between the input left channel (L) and right channel (R) audio signals is applied to the control terminal of the second volume control circuit 56. . The inverting amplifier circuit 60 inverts the control voltage output of the comparison circuit 59 and applies the first control voltage to the control terminal of the first volume control circuit 55.

When the level difference between the input left channel audio signal (L) and the right channel audio signal (R) is large, that is, when a stereo audio signal is input, the second control voltage becomes small, and The second volume control circuit 56 suppresses the output so that the voice sum signal (L + R) is not output to the output terminal of the center channel C _out . On the other hand, the first control voltage increases and the first volume control circuit 55
Passes the voice sum signal (L + R) almost as it is and adds it to the common other terminal of the first and second adders 52 and 53. At this time, the output of the first adder 52 becomes a 2L left channel audio signal (L _out ). Second adder 5
The output of 3 is the audio signal of the right channel of 2R (R _out )
Becomes As a result, the sound image is localized on the speakers of the left channel (L) and the right channel (R). When the level difference between the input left channel audio signal (L) and the right channel audio signal (R) is small, that is, when a monaural audio signal is input, the second control voltage increases and the second volume increases. The control circuit 56 outputs the voice sum signal (L + R) almost as it is to the center channel (C _out ).
Add to the output terminal of. As a result, the sound image is localized on the speaker of the center channel (C). On the other hand, the first control voltage is reduced, the first volume control circuit 55 suppresses the output, and the voice sum signal (L + R) is applied to the common other terminals of the first and second adders 52 and 53. Try not to join. At this time, the output of the first adder 52 is the audio difference signal (LR). The output of the second adder 53 is the voice difference signal (-L + R). Since the level difference between the input left channel audio signal (L) and the right channel audio signal (R) is small, the above audio difference signals (LR), (-L).
+ R) becomes a very small level, and the left and right spread sounds of the left channel (L) and right channel (R) speakers are produced.

[0021]

According to the stereo sound field expanding apparatus of the present invention, when the level difference between the input left channel audio signal (L) and the right channel audio signal (R) is large, that is, the stereo audio signal is input. When it is present, the sound image is localized at the positions of the left channel (L) and right channel (R) speakers. When the level difference is small, that is, when the monaural audio signal is input, the sound image is localized at the position of the speaker of the center channel (C). As a result, the sound image does not blur, and the localization position of the sound image does not change even if the listener shifts the listening position to the left or right. And expand the sound field. The circuit configuration and operation are simple as compared with the Dolby-3 stereo reproduction circuit.

[Brief description of drawings]

FIG. 1 is a circuit block diagram showing a first embodiment of a stereo sound field expansion device of the present invention.

FIG. 2 is a graph showing an operational relationship of the first embodiment shown in FIG.

FIG. 3 is a circuit block diagram showing a second embodiment of the stereo sound field expansion apparatus of the present invention.

FIG. 4 is a diagram showing a sound image localization state of a conventional three-speaker.

FIG. 5 is a diagram showing a configuration of a conventional 3 stereo reproduction circuit.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Voice sum signal (L + R) generation circuit, 2 ... 1st detection circuit, 3 ... 2nd detection circuit, 4 ... Comparison circuit, 5 ... Volume control means, 6 ... 1st volume control circuit, 7 ... Second volume control circuit, 8 ... Third volume control circuit, 50 ... Audio difference signal (L
-R) generating first generation circuit, 51 ... First inverting amplification circuit, 52 ... First adder, 53 ... Second adder, 5
4, a second generation circuit that generates a voice sum signal (L + R),
55 ... 1st volume control circuit, 56 ... 2nd volume control circuit, 57 ... 1st detection circuit, 58 ... 2nd detection circuit, 5
9 ... Comparison circuit, 60 ... Second inverting amplifier circuit.

Claims (2)

[Claims] 1. A first channel and a second channel audio signal supplying means, a signal generating means for adding the first and second channel audio signals to generate a third channel audio signal, and input terminals respectively. , An output terminal and a control terminal, wherein the audio signals of the first, second, and third channels are supplied to the respective input terminals, and the signal level of each of the output terminals is changed according to the control voltage supplied to the respective control terminals. First to get a controlled audio signal
The outputs of the second and third volume control circuits, the first and second detection circuits for detecting the respective audio signal levels of the first and second channels, and the outputs of the first and second detection circuits are compared. Means for supplying a control voltage according to the level difference between the audio signals of the first and second channels to the control terminals of the first, second and third volume control circuits, and when the level difference is large, Enhances the audio signal output levels of the first and second channels and suppresses the output level of the audio signal of the third channel, and when the level difference is small, the audio signal output levels of the first and second channels And a control circuit for controlling so as to reinforce the output level of the audio signal of the third channel. 2. A first channel and second channel audio signal supply means, and a first signal generation means for subtracting the first and second channel audio signals to generate a third channel audio signal. Second signal generating means for adding the audio signals of the first and second channels to generate an audio signal of the fourth channel; an inverting circuit for inverting the phase of the audio signal of the third channel; input terminals; An output terminal and a control terminal, the audio signal of the fourth channel is supplied to each input terminal,
First and second volume control circuits for obtaining a fourth-channel audio signal whose signal level is controlled at each output terminal in accordance with a control voltage supplied to each control terminal; the third-channel audio signal; A first addition circuit for adding the output of the first volume control circuit; a second addition circuit for adding the audio signal from the inverting circuit and the output of the first volume control circuit; Audio signals of the first and second channels, including first and second detection circuits for detecting respective audio signal levels of the first and second channels, and means for comparing outputs of the first and second detection circuits. A control voltage according to a signal level difference is supplied to the control terminals of the first and second volume control circuits, and when the level difference is large, the first voltage is supplied to the first terminal.
The volume control circuit outputs the voice signal without suppressing, the second volume control circuit outputs the voice signal while suppressing, and when the level difference is small, outputs the voice signal from the first volume control circuit. A control circuit for suppressing and outputting, and controlling so as to output the audio signal from the second volume control circuit without suppressing, the first and second addition circuits and the second volume control A stereo sound field expansion device characterized in that first, second and third output signals are respectively obtained from a circuit.