JPH08288999A - Voice conference equipment - Google Patents

Abstract

PURPOSE: To compensate the effect of surrounding noise by selecting automatically an active microphone in the case of transmission so as to eliminate the fluctuation in the frequency characteristic. CONSTITUTION: A noise detection circuit 17 detects a long time mean level of surrounding noise from output signals of microphones 121 , 122 . Then a comparator circuit 191 (192 ) compares the output signal of a circuit 17 with the output signal of the microphone 121 (122 ) and based on the result of comparison, variable loss circuits 1B1 , 1B2 release the attenuation applied to the output of the microphones 121 , 122 only when the output of the microphones 121 , 122 is higher than the output signal of the circuit 17. The output of the microphones 121 , 122 outputted via the circuits 1B1 , 1B2 is amplified by a differential amplifier circuit 1D. Thus, the microphone 121 or 122 to be active is automatically selected in the case of transmission.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voice conference apparatus, and more particularly to improvement of a desk-top type voice conference apparatus in which several persons surround the apparatus and connect with conference participants at remote locations by voice.

[0002]

2. Description of the Related Art In a voice conference apparatus in which a speaker and a microphone are unitized into an integrated structure, a received sound sent from the speaker is retransmitted to the microphone, and howling,
Or, echo is generated and the call quality is deteriorated.

In order to compensate for such deterioration of speech quality, a voice switch technology has been widely used for a long time, but this kind of voice switch technology compares transmission / reception levels and only the side with a low communication level is used. The loss is inserted to compensate for the acoustic coupling between the speaker and the microphone, but as a result, one-way communication is forced.

In recent years, digital signal processing (DS
P) Due to technological advances, echo cancellers are becoming widespread, but this type of echo canceller internally predicts / generates a pseudo echo and subtracts it from the actually generated echo, so that acoustic coupling between a speaker and a microphone is performed. In the case of eliminating the acoustic echo caused by, the line echo caused by the impedance mismatch of the two-wire / four-wire conversion circuit is 10
The echo erasing time is about twice as long, it is difficult to realize economically, and the ambient noise mixed in the echo cannot be eliminated.

Further, as a measure for compensating for this kind of call quality, the invention "a loudspeaker telephone handset unit (Japanese Patent Publication No. 63-2
2702) Announcement of May 12, 1988 "and" Sound and ambient noise prevention method (Japanese Patent Publication No. 5-29184)
Announcement of April 28, 2010 "is disclosed.

The above-mentioned invention "extended telephone transmission / reception unit" is
A pair or multiple pairs of microphones are placed at equal distances and target positions with respect to the center axis of the speaker, and the difference between the electrical output of each pair of microphones is taken to cancel the received sound output from the speaker. A dynamic amplification system is adopted, and the shape of the speaker box is flattened in order to mitigate the influence of reflection from the desk where the audio conference device is installed. In order to eliminate the dead point of, the microphones are arranged opposite to each other in the tangential direction of the center circle of the speaker.

Further, in the above-mentioned invention "sound and ambient noise prevention system", the speaker is arranged at the midpoint of the line segment connecting the two microphones, and the difference output of the two microphones is used as the transmission signal. The problem that the transmission sensitivity becomes a dead point on the vertical line passing through the midpoint of the line segment connecting the microphones, that is, from the direction equidistant from the two microphones has not been solved. However, it is said to be effective in preventing ambient noise.

[0008]

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention In the differential sound pickup system disclosed in these two inventions, a sound from a line segment connecting two microphones has a microphone whose half wavelength is two microphones. When it is equal to the distance between them (for example, around 20 cm) [at a frequency of around 850 Hz], the sound is picked up with twice the sensitivity of a single microphone.

For high frequency sounds with shorter wavelengths,
When one wavelength is the distance between microphones [17 in frequency
00 Hz], the sensitivity becomes extremely small, and a peak appears again at a frequency [around 2550 Hz] at which the distance between the microphones becomes 3/2 wavelength [around 2550 Hz].

With respect to the sound from the oblique direction, the distance between the microphones seems to be apparently short, and the frequency at which a peak first occurs transits in a direction in which the frequency is high. If the two microphones are always operating with equal sensitivity in this way, the transmitted voice is affected by the frequency characteristics with many peaks and valleys due to the phase difference of the sound collection points, and it is almost free from ambient noise at high frequencies. The effect of canceling is lost.

Further, in a room with a large echo, reflection from the opposite wall surface of the speaker is added, and an increasingly complicated transmission frequency characteristic is exhibited. That is, it is common that the simultaneous sound pickup by two microphones separated by a distance of about 20 cm includes the S / N ratio and does not necessarily result in preferable call quality when compared with the sound pickup by one microphone. There was a problem.

It is an object of the present invention to realize a voice conference device capable of eliminating fluctuations in frequency characteristics and compensating for the influence of ambient noise.

[0013]

FIG. 1 is a diagram showing the principle of the present invention. FIG. 1 (a) shows the principle of the present invention (claim 1) and FIG. 1 (b) shows the present invention (claim 1). The principle of item 2) is shown.

In FIG. 1, 10 is a voice conference device, and 11
Is a speaker, 12 ₁ and 12 ₂ are microphones, 17 is a noise detection circuit, 19 ₁ , 19 ₂ and 1G are comparison circuits, 1
B ₁ , 1B ₂ are variable loss circuits, 1D are differential amplifier circuits, 1
H is a level determination circuit, and 100 is a logic circuit.

Speaker boxes (1 _A ) and (1 _B )
And (1 _C ) are shown in FIGS. 4, 5 and 6, respectively.

[0016]

In FIG. 1 (a), the noise detection circuit (17) is
The long-term average level of ambient noise is detected from the output signals from the microphones (12 ₁ ) and (12 ₂ ).

The comparison circuits (19 ₁ ) and (19 ₂ ) are
Each microphone (1
The output signal from 2 ₁ , 12 ₂ ) and the noise detection circuit (1
The output signal from 7) is compared, and when receiving, the output signal of each microphone (12 ₁ , 12 ₂ ) is compared with the input signal to the speaker (11).

Variable loss circuits (1B ₁ ) and (1B ₂ )
Is the comparison result of each comparison circuit (19 ₁ , 19 ₂ ),
Only when the output signals of the microphones (12 ₁ ) and (12 ₂ ) are higher than the output signal of the noise detection circuit (17), the attenuation applied to the output signals of the respective microphones (12 ₁ , 12 ₂ ) is canceled.

The differential amplifier circuit (1D) differentially amplifies the output signal of each microphone (12 ₁ , 12 ₂ ) output via each variable loss circuit (1B ₁ , 1B ₂ ). As described above, the microphone (12 ₁ ) or (12 ₂ ) that operates when transmitting is automatically selected.

In FIG. 1 (b), the comparison circuit (1G) is
The output signals from both microphones (12 ₁ , 12 ₂ ) are compared. The level determination circuit (1H) determines the magnitude of the level difference between the output signals from both microphones (12 ₁ , 12 ₂ ).

The logic circuit (100) includes a speaker (11).
The audio conferencing device (1) receives the received signal to the voice conference device (1G) and the output signal from the level determination circuit (1H).
0) Identify the call state.

Variable loss circuits (1B ₁ ) and (1B ₂ )
Is based on the identification result of the logic circuit (100) and cancels the attenuation applied to the output signal of the high-output side microphone (12 ₁ or 12 ₂ ) according to the comparison result of the comparison circuit (1G) during transmission. However, the cancellation of the attenuation applied to the output signals of both microphones (12 ₁ and 12 ₂ ) is prohibited during a silent call or a receiving call.

The differential amplifier circuit (1D) differentially amplifies the output signal of each microphone (12 ₁ , 12 ₂ ) output through each variable loss circuit (1B ₁ , 1B ₂ ). As described above, the microphone (12 ₁ or 1) that operates when transmitting
2 ₂ ) and the transmission level of the microphone (12 ₁ or 12 ₂ ) are automatically selected.

Regarding the acoustic configuration of the audio conference apparatus (10), the flat closed type speaker box (1 _A ) is provided with a speaker (11) facing the outside at the center of the upper surface (2 _A ) of the speaker box (1 _A ). 1 _A ) on two sides (3 _A1 ,
3 _A2 ) is provided with parallel cutting side surfaces (4 _A1 , 4 _A2 ) facing each other equidistant from the center of the speaker (11), and a pair of unidirectional microphones is provided on each parallel cutting side surface (4 _A1 , 4 _A2 ). (1
2 ₁ , 12 ₂ ) and each microphone (12 ₁ , 12 2
₂ ) has an acoustic configuration in which the directional axis is arranged in the tangential direction and the opposite direction of the center circle drawn with the center of the speaker (11) as the center.

In the present invention (claim 3), the cut side surfaces (4 _A1 , 4 _A2 ) are two circular side surfaces (3 _A1 , 3 _A2 ) of the flat cylindrical closed type speaker box (1 _A ). In the present invention (Claim 4), the flat rhomboid closed speaker box (1 _B ) is provided such that two opposite corners are cut off. Further, in the present invention (Claim 5), Flat rhomboid closed speaker box (1 _C )
Of the resection side (4
_It may be considered to provide _C1 , 4 _C2 ) so that the plane after excision is S-shaped.

It is also envisaged that the selected microphone (12 ₁ or 12 ₂ ) comprises means capable of visible display. Therefore, according to the present invention, by forming the speaker box with the cut-off side surface, it is possible to identify the transmission from all directions without blind spots, and only one of the two microphones closer to the transmission direction is standard. Since it operates with the sensitivity of the other, and the other is given an appropriate attenuation, it is possible to eliminate the disturbance of the transmission frequency characteristic due to the two-point sound collection method, it is also possible to suppress the invalid sound collection of ambient noise, and no call In this state, both microphones are properly attenuated, and unnecessary ambient noise can be suppressed and transmitted. Furthermore, even in the receiving state, both microphones are properly attenuated and canceled by the differential amplifier circuit. Since the effect is added, the acoustic coupling from the speaker to the microphone can be significantly improved as compared with a single microphone, and a high quality call can be made.

[0027]

An embodiment of the present invention will be described below with reference to the drawings. 2 is a diagram showing a circuit configuration of a voice conference apparatus according to an embodiment of the present invention (claims 1 and 6), and FIG. 3 is a diagram of a voice conference apparatus according to an embodiment of the present invention (claims 2 and 6). FIG. 4 is a diagram showing a circuit configuration, and FIG. 4 shows the present invention (claim 3).
6 is a diagram showing an acoustic configuration of a voice conference device according to an embodiment of the present invention, FIG. 5 is a diagram showing an acoustic configuration of a voice conference device according to an embodiment of the present invention (claim 4), and FIG. It is a figure which shows the audio constitution of the audio conference apparatus by one Example of Claim 5). The same reference numerals indicate the same objects throughout the drawings.

First, the present invention (claims 1, 3 and 6)
The embodiment will be described with reference to FIGS. 2 and 4. The audio conference device (10) shown in FIG. 2 is stored in the speaker box (1 _A ) as shown in FIG.

The speaker box (1 _A ) was shaped such that two flat cylindrical side surfaces (3 _A3 ) and (3 _A4 ) were cut to form parallel cut side surfaces (4 _A1 ) and (4 _A2 ). It is a thing.

The speaker (11) is a speaker box
(1_A) Upper surface (2_A) Attached to the outside in the center
Have been killed. Also a pair of unidirectional microphones
(12) [Individual microphones (12 ₁) And (1
2₂), The same shall apply hereinafter), respectively.
_A1) And (4_A2), The directional axis in the speaker (11)
In the tangential and opposite directions of the center circle drawn centering on the heart
It is arranged toward.

Each microphone (12 ₁ ) and (1
The directional characteristic of 2 ₂ ) is slightly deviated from the main directional axis, as shown in FIG. 4, due to the reflection effect and the shielding effect of the cut side surfaces (4 _A1 ) and (4 _A2 ), respectively.

As a result, (a), (b) and (c) in FIG.
For the audio signals input from the and (d) directions, the front or side directional sensitivity of the microphone (12 ₁ ) is higher than the back or side directional sensitivity of the microphone (12 ₂ ) separated by the speaker box (1 _A ), Microphone (12
It is clear that the output signal from ₁ ) will be at a higher level than the output signal from the microphone (12 ₂ ).

Even when compared with the third reference value such as average ambient noise, it is clear that the output signal from the microphone (12 ₁ ) becomes high level. Similarly, the sound signals input from the directions (e), (f), (g) and (h) in FIG. 4 have a front or side directivity sensitivity of the microphone (12 ₂ ) and a speaker box (1 _A ). Obviously, the output signal from the microphone (12 ₂ ) will be higher than the output signal from the microphone (12 ₁ ), which will be higher than the back or side directional sensitivity of the separated microphone (12 ₁ ).

Even when compared with the third reference value such as average ambient noise, it is clear that the output signal from the microphone (12 ₂ ) becomes high level. Next, in FIG. 2, it is assumed that no voice is transmitted from the surroundings to the voice conference device (10), and no received signal arrives from the telephone line (20), that is, there is no call.

In such a state, the microphone (12 ₁ )
Only ambient noise in the room in which the audio conference device (10) is installed is input to (12 ₂ ).
Ambient noises (N _R1 ) and (N _R2 ) input from the microphones (12 ₁ ) and (12 ₂ ) are compared with a comparison circuit (19 ₁ ) via microphone signal detection circuits (16 ₁ ) and (16 ₂ ), respectively. And (19 ₂ ) non-inverting input terminal (+) and noise detection circuit (17).

The noise detection circuit (17) receives ambient noise (N _R1 ) and (N _R1 ) from the microphones (12 ₁ ) and (12 ₂ ) via the microphone signal detection circuits (16 ₁ ) and (16 ₂ ) respectively. For N _R2 ), a long charging time constant circuit and a short discharging time constant circuit are used to extract a long-term average noise component (N _M ), and each comparison circuit (19 ₁ ) is added via an adder (18). and an inverting input terminal (19 ₂₎ (-) input to.

The noise detection circuit (17) adds some gain to the extracted long-term average noise component (N _M ) or
Alternatively, by superposing a DC bias, the microphone signal detection circuits (16 ₁ ) and (16
₂ ) from the noise detection circuit (17) to the adder (rather than ambient noise (N _R1 ) and (N _R2 ) input to the non-inverting input terminals (+) of the comparison circuits (19 ₁ ) and (19 ₂ ). 1
8) is set so that the long-term average noise component (N _M ) input to the inverting input terminals (−) of the comparison circuits (19 ₁ ) and (19 ₂ ) respectively is always at a high level (H). There is.

The comparison circuits (19 ₁ ) and (19 ₂ ) are
The long-term average noise component (N _M ) input to the inverting input terminal (−) is higher than the ambient noise (N _R1 ) and (N _R2 ) input to the non-inverting input terminal (+), respectively, at a higher level (H). ), The output comparison signals (C ₁ ) and (C ₁
Set ₂ ) to low level (L).

The comparison signal (C ₁₎ and output from each comparator circuit (19 ₁₎ and (19 ₂₎ (C ₂₎ is input to respective variable loss circuits (1B ₁₎ and (1B ₂₎ , The light-emitting diode (1A ₁ ) and (1
It is also input to A ₂ ).

Variable loss circuits (1B ₁ ) and (1B ₂ )
Is set to a predetermined loss state (for example, about 15 decibels) when the comparison signals (C ₁ ) and (C ₂ ) respectively input are both set to a low level (L). .

Further, the light emitting diode (1A₁) And (1
A₂) Is the input comparison signal (C ₁) And (C₂)
Emits light when both are set to low level (L)
No microphone (12₁) And (1
2₂) Also indicates that it is not talking.

As a result, the ambient noise (N _R1 ) input from the microphone (12 ₁ ) is transmitted to the transmitter amplifier (1C ₁ ) and the variable loss circuit (1) set to a predetermined loss state.
Ambient noise (N _R2 ) input to the differential amplifier circuit (1D) via B ₁ ) and also input from the microphone (12 ₂ ) is also set to the transmission amplifier (1C ₂ ) and a predetermined loss state. Is input to the differential amplifier circuit (1D) via the variable loss circuit (1B ₂ ).

Therefore, the differential ambient noise (N _R ) output from the differential amplifier circuit (1D) is also sufficiently attenuated and input to the two-wire to four-wire conversion circuit (1E), and the differential Ambient noise (N _R ) is transmitted to the telephone line (20) via the two-wire / four-wire conversion circuit (1E) or the reception amplifier (1).
There is no fear of being transmitted to the speaker (11) via 3).

Next, referring to FIG. 2, the audio conference device (1
0) to (a), (b), (c) or (d) in FIG.
Is transmitted from the direction ( ₁ ), the transmission level input to the microphone (12 ₁ ) is higher than the transmission level input to the microphone (12 ₂ ), and higher than the ambient noise in the room. It is assumed that the received signal does not arrive from the telephone line (20) and the telephone is in the transmitting state.

In such a state, the microphone (12 ₁ )
To the microphone (12 ₂ ), a transmission of a level higher than the ambient noise is input, and to the microphone (12 ₂ ), a transmission of a level lower than the ambient noise is input together with the ambient noise.

Microphones (12 ₁ ) and (12 ₂ )
The transmission signals (V _S1 ) and (V _S2 ) respectively input from the comparators (19 ₁ ) and (19
₂ ) is input to the non-inverting input terminal (+) and also to the noise detection circuit (17).
Since it is averaged for a long time by 7), the noise detection circuit (17)
There is no output from.

The microphones (12 ₁ ) and (12
₂ ) Ambient noise (N _R1 ) and (N _R2 ) input from
Are signal detection circuits (16 ₁ ) and (1
6 ₂ ) to the non-inverting input terminals (+) of the comparison circuits (19 ₁ ) and (19 ₂ ), and also to the noise detection circuit (17). The time average noise component (N _M ) is extracted, and the adder (1
Inverting input terminal of 8) each comparator circuit (19 ₁₎ and through the (19 ₂₎ (-) is input to.

In the comparison circuit (19 ₁ ), the transmission signal (V _S1 ) input to the non-inverting input terminal (+) is input to the inverting input terminal (-) for a long time average noise component (N _M ). When it goes to a higher level (H), the output comparison signal (C ₁ ) is set to a higher level (H).

The comparator circuit (19 _2), an inverting input terminal (-) long-term average noise component is input to the (N _M) is, transmission signal inputted to the non-inverting input terminal (+) (V _S2) When it goes to a higher level (H), the output comparison signal (C ₂ ) is set to a lower level (L).

Variable loss circuit (1B₁) Is the comparison circuit (1
9₁), The comparison signal (C ₁) Is a high level
When set to (H), it is set to lossless state
Variable loss circuit (1B₂) Is a comparison circuit (19₂) Input
Comparison signal (C₂) Is set to low level (L)
And like the above, the predetermined loss state [= about 15 decibels
Degree] is set.

[0051] As a result, transmission signal (V _S1) inputted from the microphone (12 ₁₎ is a transmission amplifier (1C ₁₎ and a lossless state variable loss circuit (1B ₁₎ via the differential amplifier circuit (1D), and the microphone (12
_The transmission signal (V _S2 ) input from ₂ ) is input to the differential amplifier circuit (1D) via the transmission amplifier (1C ₂ ) and the variable loss circuit (1B ₂ ) set to a predetermined loss state. To be done.

Therefore, the differential amplifier circuit (1D) inputs only the transmission signal (V _S1 ) input from the microphone (12 ₁ ) to the two-wire / four-wire conversion circuit (1E). It is sent to the telephone line (20) via the line conversion circuit (1E). However, although it is transmitted to the speaker (11) through the receiving amplifier (13), since it is sufficiently attenuated by the two-wire / four-wire conversion circuit (1E), there is no fear of being output from the speaker (11).

Further, only the light emitting diode (1A ₁ ) emits light when the input comparison signal (C ₁ ) is set to the high level (H), indicating that the microphone (12 ₁ ) is in the transmitting state. .

Next, in FIG. 2, when the reception signal (V _R ) arrives from the telephone line (20) to the audio conference device (10), the arrival reception signal (V _R ) is converted into a two-wire four-line conversion. The signal is input to the speaker (11) via the circuit (1E) and the reception amplifier (13), is transmitted to the room as reception voice, and is also input to the reception signal detection circuit (14).

[0055] the received signal detection circuit (14) detects the input receiving signal (V _R), and outputs to the adder (15). On the other hand, the microphones (12 ₁ ) and (12 ₂ ) receive the ambient noise (N
Only _R1 ) and (N _R2 ) are input, and the non-inverting input terminals (+) of the comparison circuits (19 ₁ ) and (19 ₂ ) are input via the microphone signal detection circuits (16 ₁ ) and (16 ₂ ), respectively.
It is also input to the noise detection circuit (17).

The noise detection circuit (17) has the same noise level as described above.
The long-term average noise component (N _M) Is extracted and added
To the container (18). Adders (15) and (18)
Is the reception signal output from the reception signal detection circuit (14)
(V_R) And the long time output from the noise detection circuit (17)
Inter-average noise component (N_M) And are added to each comparison circuit (19
₁) And (19₂) Inversion input terminal (-)
It

As a result, the inverting input terminal (-) of each of the comparison circuits (19 ₁ ) and (19 ₂ ) has a higher level than the case of only the long-time average noise component (N _M ) in the non-talking state. The addition result of the reception signal (V _R ) and the long-term average noise component (N _M ) is input.

Therefore, it is output from the speaker (11).
The received voice is a microphone (12) for acoustic coupling.₁)
Or (12₂), Even if it is fed back to
Received signal (V) input to (-)_R) And long-term average
Noise component (N_M) To reach a higher level
Is not possible, each comparison circuit (19₁) And (19₂) From
Output comparison signal (C₁) And (C₂) Are all
Set to low level, each variable loss circuit (1B₁)
And (1B₂) Is input to each
Iodo (1A₁) And (1A₂) Is also input and is possible
Variable loss circuit (1B ₁) And (1B₂), The given loss
Set to the state [= about 15 decibels].

As a result, the acoustically coupled reception output and ambient noise (N _R1 ) and (N _R2 ) input from the microphones (12 ₁ ) and (12 ₂ ) are also transmitted by the transmission amplifier (1
C ₁ ) and (1C ₂ ) and the variable loss circuits (1B ₁ ) and (1B ₂ ) set to a predetermined amount of attenuation provide sufficient attenuation.

Further, the light emitting diode (1A₁) And (1
A₂) Is the input comparison signal (C ₁) And (C₂)
Emits light when both are set to low level (L)
No microphone (12₁) And (1
2₂) Also indicates that it is not talking.

Next, an embodiment of the present invention (claims 2, 3 and 6) will be described with reference to FIGS. The audio conference device (10) shown in FIG. 3 is stored in the speaker box (1 _A ) as shown in FIG. 4 as described above, and the speaker (11) and the pair of microphones (12) are included.
_1), (arrangement of 12 ₂₎ are the same as described above, as a result, in FIG. 4 (a), (b) , (c), (d), (e), (f)
, (G) and (h), the microphone (12 ₁ ) or (12 ₂ ) outputs a higher level output signal with respect to the audio signal input.

Next, referring to FIG. 3, the audio conference device (1
0) to the telephone line (20)
It is assumed that there is no incoming call signal from, and there is no call. In such a state, only ambient noise in the room in which the audio conference device (10) is installed is input to the microphones (12 ₁ ) and (12 ₂ ).

Microphones (12 ₁ ) and (12 ₂ )
Ambient noise (N _R1 ) and (N _R2 ) input from the microphone signal detection circuits (16 ₁ ) and (16 ₂ ) respectively
Through the comparison circuit (1G) and the level determination circuit (1
H).

The reception signal detection circuit (1K) arrives from the telephone line (20) and is input to the speaker (11) through the two-wire / four-wire conversion circuit (1E) and the reception amplifier (13). When (V _R ) is detected, the output signal (R)
Setting to a low level (L), but in no call state for not detecting the reception signal (V _R), sets the output signal (R) to a high level (H).

The comparison circuit (1G) includes a microphone (12
₁) To the microphone signal detection circuit (16 ₁) Through inversion
Ambient noise (N_R1) And Mike
Rohon (12₂) To the microphone signal detection circuit (16₂)
Ambient noise (N) input to the non-inverting input terminal (+) via
_R2) With the condition (N_R1)> (N_R2) Holds
Set the comparison signal (C) to low level (L), and
(N_R1) <(N_R2) Is satisfied, the comparison signal (C) is set to high level.
Set to Bell (H).

Further, the level determination circuit (1H) receives the ambient noise (N _R1 ) and the ambient noise (N _R1 ) inputted from the microphones (12 ₁ ) and (12 ₂ ) via the microphone signal detection circuits (16 ₁ ) and (16 ₂ ), respectively. It is determined whether or not the absolute value of the level difference of (N _R2 ) is greater than or equal to a preset reference value. If the absolute value of the level difference is less than or equal to the reference value, a determination signal (D) to be output Is set to a low level (L), and when the absolute value of the level difference exceeds the reference value, the output decision signal (D) is set to a high level (H).

In the idle state, the condition (N _R1 ) =
Since ( _NR2 ) is established, the determination signal (D) output from the level determination circuit (1H) becomes indefinite, but the determination signal (D) output from the level determination circuit (1H) is at a low level (L). ), The AND gate (1F) is cut off and the output signal (G ₀ ) is set to a low level (L) regardless of the output signal (R) from the reception signal detection circuit (1K). , As a result, AND gates (1J ₁ ) and (1
J ₂ ) is also cut off, regardless of the comparison signal (C) from the comparison circuit (1G), the output signals (G ₁ ) and (G _1
2 ) Set to low level (L).

Each AND gate (1J ₁ ) and (1
Output signals (G ₁ ) and (G ₂ ) output from J ₂ ).
Are variable loss circuits (1B ₁ ) and (1B ₂ ) respectively.
The light emitting diode (1
It is also input to A ₁ ) and (1A ₂ ).

Variable loss circuits (1B ₁ ) and (1B ₂ )
When the input output signals (G ₁ ) and (G ₂ ) are both set to a low level (L), each has a predetermined attenuation amount [= attenuation amount of about 15 decibels]. Is set.

As a result, the ambient noise (N _R1 ) input from the microphone (12 ₁ ) is the transmission amplifier (1C ₁ ) and the variable loss circuit (1B ₁ ) set to a predetermined attenuation amount.
The ambient noise (N _R2 ) input to the differential amplifier circuit (1D) via the microphone (12 ₂ ) is also
A differential amplifier circuit (1D) via a transmission amplifier (1C ₂ ) and a variable loss circuit (1B ₂ ) set to a predetermined amount of attenuation.
Is input to

Therefore, the differential ambient noise (N _R ) output from the differential amplifier circuit (1D) is also sufficiently attenuated and input to the two-wire to four-wire conversion circuit (1E), and the differential Ambient noise (N _R ) is transmitted to the telephone line (20) via the two-wire / four-wire conversion circuit (1E) or the reception amplifier (1).
There is no fear of being transmitted to the speaker (11) via 3).

Next, referring to FIG. 3, the audio conference device (1
0) to (a), (b), (c) or (d) in FIG.
Is transmitted from the direction ( ₁ ), the transmission level input to the microphone (12 ₁ ) is higher than the transmission level input to the microphone (12 ₂ ), and higher than the ambient noise in the room. It is assumed that the received signal does not arrive from the telephone line (20) and the telephone is in the transmitting state.

In this state, the microphone (12 ₁ )
A high-level transmission is input together with the ambient noise, and a low-level transmission is input together with the ambient noise into the microphone (12 ₂ ).

Microphones (12 ₁ ) and (12 ₂ )
The transmission signals (V _S1 ) and (V _S2 ) respectively input from are input to the comparison circuit (1G) and the level determination circuit (1H), as described above.

Similarly to the above, the comparison circuit (1G) compares the transmission signals (V _S1 ) and (V _S2 ) input to the inverting input terminal (−) and the non-inverting input terminal (+), and determines the condition. (N
_R1 )> (N _R2 ) holds, so the comparison signal (C) to be output
Is set to low level (L).

In the level determination circuit (1H), the absolute value of the level difference between the input transmission signals (V _S1 ) and (V _S2 ) is equal to or greater than the preset reference value, as described above. If it is determined that the absolute value of the level difference exceeds the reference value, the output determination signal (D) is set to the high level (H), and the AND gate (1F) is set to the conductive state. To do.

[0077] Note that the received signal detection circuit (1K), since it does not detect the reception signal (V _R) in the listen state, sets the output signal (R) to a high level (H). As a result, the AND gate (1F) changes the output signal (G ₀ ) to the high level (H).
, And AND gates (1J ₁ ) and (1
J ₂ ) is also set to the conductive state.

The comparison signal (C) [= low level (L)] output from the comparison circuit (1G) is input to the AND gate (1J ₁ ) via the inverting circuit (1I) and at the same time the direct logic is applied. Since it is input to the product gate (1J ₂ ), the output signal (G ₁ ) of the logical product gate (1J ₁ ) is set to the high level (H) and the variable loss circuit (1B ₁ ) and the light emitting diode (1A ₁ ) The output signal (G ₂ ) of the AND gate (1J ₂ ) is set to the low level (L) and is input to the variable loss circuit (1B ₂ ) and the light emitting diode (1A ₂ ).

The variable loss circuit (1B ₁ ) is set to a lossless state when the output signal (G ₁ ) input from the AND gate (1J ₁ ) is set to a high level (H), and is also variable. When the output signal (G ₂ ) input from the AND gate (1J ₂ ) is set to the low level (L), the loss circuit (1B ₂ ) has a predetermined attenuation [= 15
Attenuation of about decibel] is set.

As a result, the transmission signal (V _S1 ) input from the microphone (12 ₁ ) is transmitted through the transmission amplifier (1C ₁ ) and the variable loss circuit (1B ₁ ) in the lossless state to the differential amplifier circuit. (1D), and the microphone (12
_The transmission signal (V _S2 ) input from ₂ ) is input to the differential amplifier circuit (1D) via the transmission amplifier (1C ₂ ) and the variable loss circuit (1B ₂ ) set to a predetermined attenuation amount. To be done.

Therefore, the differential amplifier circuit (1D) inputs only the transmission signal (V _S1 ) input from the microphone (12 ₁ ) to the two-wire to four-wire conversion circuit (1E),
It is sent to the telephone line (20) through the two-wire / four-wire conversion circuit (1E). However, although it is transmitted to the speaker (11) through the receiving amplifier (13), since it is sufficiently attenuated by the two-wire / four-wire conversion circuit (1E), there is no fear of being output from the speaker (11). Next, in the transmitting state,
As described above, the transmission is input to the microphone (12 ₁ ),
The comparison signal (C) output from the comparison circuit (1G) is set to a low level, the determination signal (D) output from the level determination circuit (1H) is set to a high level (H), and the AND gate (1F) and an output signal from the (1J ₁₎ (G ₀₎ and (G ₁₎ is high (H), and the output signal from the aND gate (1J ₂₎ (G ₂₎ is a low level (L)
, The variable loss circuit (1B ₁ ) is in a lossless state, the variable loss circuit (1B ₂ ) is set to a predetermined attenuation amount, and the transmission signal (V _S1 ) input from the microphone (12 ₁ ) is a telephone line. It is assumed that the data has been sent to (20).

[0082] In this state, when the received signal (V _R) arrives to the telephone line (20) conference telephone from (10), the received signal (V _R), the double-wire four-wire conversion circuit (1E) and It is input to the speaker (11) via the reception amplifier (13), is transmitted to the room as reception voice, and is also input to the reception signal detection circuit (14).

The reception signal detecting circuit (14), when detecting the input reception signal (V _R ), is the logical product gate (1F).
The output signal (R) input to is set to a low level (L). As a result, the logical product gate (1F) is set to the cutoff state, and the logical product gates (1J ₁ ) and (1J ₂ ) are turned on regardless of the judgment signal (D) output from the level judgment circuit (1H). The input output signal (G ₀ ) is set to a low level (L), and as a result, the AND gates (1J ₁ ) and (1J ₂ ) are also cut off, and the comparison signal (C) from the comparison circuit (1G). Regardless of the above, the output signals (G ₁ ) and (G ₂ ) are set to the low level (L).

In the variable loss circuit (1B ₁ ), when the input output signal (G ₁ ) is changed from the high level (H) to the low level (L), the lossless state is changed to a predetermined attenuation amount []. = Attenuation amount of about 15 decibels], and since the output signal (G ₂ ) being input is held at a low level (L), the variable loss circuit (1B ₂ ) continues to be at a predetermined level. The attenuation amount is set to [= attenuation amount of about 15 decibels].

As a result, when the reception signal (V _R ) arrives from the telephone line (20), the microphone (1
The transmission signal (V _S1 ) input from 2 ₁ ) is input to the differential amplifier circuit (1D) via the variable loss circuit (1B ₁ ) set to a predetermined attenuation amount, and therefore, Even if the received voice output from the speaker (11) is returned to the microphone (12 ₁ ) or (12 ₂ ) for acoustic coupling, it is sufficiently attenuated.

The light emitting diode (1A₁) And (1
A₂) Is the output signal (G ₁) And (G₂)
Light is emitted only when is set to a high level (H).
Similarly to the microphone (12₁) And
(12₂) Is displayed.

As is clear from the above description, according to the embodiment of the present invention (claims 1, 2 and 6), the speaker box (1 _A ) is shaped as shown in FIG.
Speech from all directions can be identified without dead points, and only one of the two microphones (12 ₁ ) and (12 ₂ ) closer to the speech direction operates with standard sensitivity, and the other one is appropriate. Since the attenuation is given, it is possible to eliminate the disturbance of the transmission frequency characteristic due to the two-point sound collection method, and it is also possible to suppress the invalid sound collection of ambient noise, which enables high quality calls and also in the non-call state. Provides appropriate attenuation to both microphones (12 ₁ ) and (12 ₂ ), and can suppress the collection and transmission of unnecessary ambient noise. Furthermore, even in the receiving state, both microphones (12 ₁₎ and the proper attenuation with given (12 _2), since also applied effect cancellation by a differential amplifier circuit (1D) from the speaker (11) to the microphone (12 ₁₎ and (12 ₂₎ Hibiki binding than the single microphone, enabling improved longitudinal approximately 20 decibels.

It should be noted that FIGS.
This is only an example, for example, a speaker box (1_A) Is Figure 4
It is not limited to those shown in FIG.
Flat rhomboid closed speaker box (1_B)of
Cut away two opposite corners to cut side
(4_B1) And (4_B2) Is formed and the cut side (4_B1)
And (4_B2) To the microphone (12₁) And (1
2₂) To the speaker box (1_A) Same as in
Wear, or as shown in Figure 6, flat rhombic closed form
Speaker box (1_C) Two opposite corners
Including the cutting side (4_A1Four_A2) Is a S-shaped plane after excision
Cut off the sides (4_B1) And (4_B2) Formed
And cut side (4_B1) And (4_B2) To microphone
(12₁) And (12 ₂) The speaker box
(1_A) And many other variations, such as mounting in
However, the effect of the present invention is different in any case.
Absent.

The circuit configuration of the audio conference device (10) is as follows.
The present invention is not limited to what is shown in the drawings, and various modifications may be considered within the scope of the claims, but the effect of the present invention does not change in any case.

[0090]

As described above, according to the present invention, by forming the speaker box with the cut-off side surface, it is possible to distinguish the transmission from all directions without a blind spot, and the transmission direction among the two microphones can be changed. Only the near one operates with standard sensitivity, and the other one is given proper attenuation, so it is possible to eliminate the disturbance of the transmission frequency characteristic due to the two-point sound collection method, and it is also possible to suppress the invalid sound collection of ambient noise. Also, both microphones are given proper attenuation in the idle state,
Unnecessary ambient noise pickup can be suppressed, and even in the receiving state, proper attenuation is given to both microphones, and the canceling effect by the differential amplifier circuit is added, so acoustic coupling from the speaker to the microphone is achieved. Can be significantly improved compared to a single microphone, enabling high quality calls.

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a circuit configuration of a voice conference device according to an embodiment of the present invention (claims 1 and 6).

FIG. 3 is a circuit configuration of a voice conference device according to an embodiment of the present invention (claims 2 and 6).

FIG. 4 is an acoustic configuration of a voice conference device according to an embodiment of the present invention (claim 3).

FIG. 5 is an audio configuration of a voice conference device according to an embodiment of the present invention (claim 4).

FIG. 6 is an acoustic configuration of a voice conference device according to an embodiment of the present invention (claim 5).

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 speaker box 2 upper surface 3 side surface 4 excision side surface 10 audio conference apparatus 11 speaker 12 microphone 13 receiving amplifier 14, 1K receiving signal detecting circuit 15, 18 adder 16 microphone signal detecting circuit 17 noise detecting circuit 19, 1G comparing circuit 1A light emitting diode 1B Variable loss circuit 1C Transmitter amplifier 1D Differential amplifier circuit 1E Two-wire / four-wire conversion circuit 1F, 1J AND gate 1H Level determination circuit 1I Inversion circuit 20 Telephone line 100 Logic circuit

Claims (6)

[Claims] 1. A flat closed type speaker box is provided with a speaker toward the outside at the center of the upper surface thereof, and two side surfaces of the speaker box are provided with parallel cut side surfaces facing each other at an equal distance from the center of the speaker box. A pair of unidirectional microphones is provided on each parallel cut side surface, and each microphone has an acoustic configuration in which the directional axis is arranged in a tangential direction and a reciprocal direction of a center circle drawn around the center of the speaker. Comprising a noise detection circuit for detecting a long-term average level of ambient noise from the output signal from each microphone, and an output signal from each microphone when no call or during transmission, and from the noise detection circuit A pair of comparison circuits for comparing the output signal of each microphone and the input signal to the speaker when receiving a voice, According to the comparison result of each comparison circuit, a pair of variable loss circuits that cancel the attenuation applied to the output signal of each microphone only when the output signal of the microphone is higher than the output signal of the noise detection circuit, A voice conference device comprising: a differential amplifier circuit that differentially amplifies an output signal of each of the microphones output via a variable loss circuit, and automatically selects a microphone that operates during transmission. 2. A flat closed type speaker box is provided with a speaker at the center of the upper surface toward the outside, and two side surfaces of the speaker box are provided with parallel cut side surfaces facing each other at an equal distance from the center of the speaker box. A pair of unidirectional microphones is provided on each parallel cut side surface, and each microphone has an acoustic configuration in which the directional axis is arranged in a tangential direction and a reciprocal direction of a center circle drawn around the center of the speaker. A comparison circuit for comparing the output signals from the both microphones, a level determination circuit for determining the level difference of the output signals from the both microphones, a reception signal to the speaker, the comparison circuit and the level A logic circuit that identifies the call state of the audio conference device based on the output signal from the determination circuit; Te is,
Based on the comparison result of the comparison circuit, a pair of variable outputs that cancels the attenuation applied to the output signal of the high-output microphone and prohibits the cancellation of the attenuation applied to the output signals of both microphones during a silent or receiving call. A loss circuit and a differential amplifier circuit that differentially amplifies the output signal of each microphone output via each variable loss circuit, and a microphone that operates during transmission and a transmission level of the microphone. A voice conferencing device that is automatically selected. 3. The audio conference apparatus according to claim 1, wherein the cut side surface is provided on two circular side surfaces of a flat cylindrical closed speaker box. 4. The audio conference apparatus according to claim 1, wherein the cut side surface is provided so as to cut off two opposite corners of the flat rhomboid closed speaker box. 5. The cutting side surface includes two opposite corners of a flat rhomboid closed speaker box, and the cutting side surface is provided so that a flat surface after cutting is S-shaped. The audio conference device according to claim 1. 6. The audio conference apparatus according to claim 1, wherein the selected microphone includes a unit capable of being displayed visually.