JP3712439B2 - Audio conferencing equipment - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an audio conference apparatus, and more particularly to an improvement in a desktop audio conference apparatus in which several people surround the apparatus and connect with a conference participant at a remote location by voice.
[0002]
[Prior art]
In an audio conference apparatus in which a speaker and a microphone are unitized into a unitary structure, a reception sound transmitted from the speaker is retransmitted to the microphone, and howling or echo is generated, resulting in a deterioration in call quality.
[0003]
In the past, voice switch technology was actively used to compensate for this kind of call quality degradation, but this type of voice switch technology compares the transmission and reception levels, and only the side with the lower call level loses the loss. Insertion compensates for acoustic coupling between the speaker and the microphone, but as a result, there is a disadvantage that forced one-way communication.
[0004]
In recent years, echo cancellers are becoming popular due to advances in digital signal processing (DSP) technology. This type of echo canceller predicts and generates pseudo echoes internally, and subtracts them from actually generated echoes. In order to cancel the acoustic echo due to the acoustic coupling between the speaker and the microphone, an echo cancellation time of about 10 times is required as compared with the line echo due to impedance mismatch such as a two-wire four-wire conversion circuit. However, it is difficult to realize economically, and the ambient noise mixed in the echo cannot be eliminated.
[0005]
In addition, as measures to compensate for this kind of call quality, the invention “amplified telephone transmission / reception unit (Japanese Examined Patent Publication No. 63-22702) announced on May 12, 1988” and “a method for preventing sound and ambient noise (Japanese Patent Publication No. 29184) "Announcement on April 28, 1993" is disclosed.
[0006]
In the above-mentioned invention “expanded telephone transmission / reception unit”, a pair or a plurality of microphones are arranged at equal distances / target positions with respect to the central axis of the speaker, and each pair of microphones is arranged in order to cancel the reception sound output from the speaker. In order to reduce the influence of reflection from the desk on which the audio conferencing equipment is installed, the shape of the speaker box is flattened. In order to eliminate the dead point of transmission directivity without impairing the canceling performance, the microphones are arranged opposite to each other in the tangential direction of the center circle of the speaker.
[0007]
In the above-mentioned invention “sound and ambient noise prevention method”, a speaker is arranged at the midpoint of a line connecting two microphones, and the difference output between the two microphones is used as a 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 two lines, that is, in the direction of the same distance from the two microphones, has not been solved. However, it is effective for preventing ambient noise.
[0008]
[Problems to be solved by the invention]
The differential sound pickup method disclosed in these two inventions is that the sound from the direction of the line segment connecting two microphones has a half wavelength of the distance between the two microphones [for example, around 20 centimeters] ] (Around 850 Hz in frequency), the sound is picked up with twice the sensitivity of a single microphone.
[0009]
For high-frequency sounds with shorter wavelengths, when one wavelength is the distance between microphones (around 1700 hertz in frequency), the sensitivity becomes minimal and again the frequency at which 3/2 wavelength becomes the distance between microphones (around 2550 hertz) ], An undesired transmission sensitivity frequency characteristic is exhibited.
[0010]
As for the sound from the oblique direction, the frequency at which the peak first appears is shifted in the direction in which the distance between the microphones appears to be short.
In this way, if two microphones are always operating at the same sensitivity, 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 almost no high frequency ambient noise. The effect of canceling is lost.
[0011]
Furthermore, in a room with a large reverberation, reflection from the opposite wall surface of the speaker is added, and more complicated transmission frequency characteristics are exhibited.
That is, the simultaneous sound collection by two microphones separated by a distance of about 20 centimeters includes the S / N ratio when compared to the sound collection by one microphone, and it is said that it does not necessarily reduce the preferred call quality. There was a problem.
[0012]
An object of the present invention is to realize an audio conference apparatus that can eliminate fluctuations in frequency characteristics and can compensate for the influence of ambient noise.
[0013]
[Means for Solving the Problems]
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 principle of the present invention (Claim 2).
[0014]
In FIG. 1, 10 is an audio conference apparatus, 11 is a speaker, 12 ₁ , 12 ₂ Is a microphone, 17 is a noise detection circuit, 19 ₁ , 19 ₂ And 1G are comparison circuits, 1B ₁ 1B ₂ Is a variable loss circuit, 1D is a differential amplifier circuit, 1H is a level determination circuit, and 100 is a logic circuit.
[0015]
Speaker box (1 _A ), (1 _B ) And (1 _C ) Are shown in FIGS. 4, 5 and 6, respectively.
[0016]
[Action]
In FIG. 1 (a), the noise detection circuit (17) is connected to each microphone (12). ₁ ) And (12 ₂ ) Detects the long-term average level of ambient noise from the output signal.
[0017]
Comparison circuit (19 ₁ ) And (19 ₂ ) Each microphone (12) when there is no call or during transmission. ₁ , 12 ₂ ) And the output signal from the noise detection circuit (17) are compared, and each microphone (12) is received at the time of reception. ₁ , 12 ₂ ) And the input signal to the speaker (11).
[0018]
Variable loss circuit (1B ₁ ) And (1B ₂ ) Each comparison circuit (19). ₁ , 19 ₂ ), The microphone (12 ₁ ) And (12 ₂ Only when the output signal of the noise detection circuit (17) is higher than the output signal of the noise detection circuit (17). ₁ , 12 ₂ ) Cancel the attenuation applied to the output signal.
[0019]
The differential amplifier circuit (1D) is connected to each variable loss circuit (1B). ₁ 1B ₂ ) Through each microphone (12 ₁ , 12 ₂ ) Output signal is differentially amplified.
As described above, the microphone (12 ₁ ) Or (12 ₂ ) Is selected automatically.
[0020]
In FIG. 1 (b), the comparison circuit (1G) includes both microphones (12 ₁ , 12 ₂ Compare the output signals from).
The level determination circuit (1H) includes both microphones (12 ₁ , 12 ₂ ) To determine the level difference of the output signal from.
[0021]
The logic circuit (100) identifies the call state of the audio conference device (10) based on the reception signal to the speaker (11) and the output signals from the comparison circuit (1G) and the level determination circuit (1H).
[0022]
Variable loss circuit (1B ₁ ) And (1B ₂ ) Is based on the identification result of the logic circuit (100), and at the time of transmission, the microphone (12) on the high output side is determined based on the comparison result of the comparison circuit (1G). ₁ Or 12 ₂ ) To cancel the attenuation applied to the output signal of both microphones (12 ₁ And 12 ₂ ) The cancellation of attenuation applied to the output signal is prohibited.
[0023]
The differential amplifier circuit (1D) is connected to each variable loss circuit (1B). ₁ 1B ₂ ) Through each microphone (12 ₁ , 12 ₂ ) Output signal is differentially amplified.
As described above, the microphone (12 ₁ Or 12 ₂ ) And the microphone (12) ₁ Or 12 ₂ ) Transmission level is automatically selected.
[0024]
For the audio configuration of the audio conference apparatus (10), a flat sealed speaker box (1 _A ) Top surface (2) _A ) A speaker box (1) is provided at the center with a speaker (11) facing outward. _A ) Two side faces (3 _A1 3 _A2 ), The parallel cut side faces (4) facing each other at an equal distance from the center of the speaker (11). _A1 4 _A2 ) And each parallel excision side (4 _A1 4 _A2 ) To a pair of unidirectional microphones (12 ₁ , 12 ₂ ) And each microphone (12 ₁ , 12 ₂ ) Has an acoustic configuration in which the directional axis is arranged in the direction tangential to the center circle drawn around the center of the speaker (11) and in the opposite direction.
[0025]
Note that the cut side (4 _A1 4 _A2 In the present invention (Claim 3), a flat cylindrical sealed speaker box (1) is provided. _A ) Two circular sides (3) _A1 3 _A2 In the present invention (Claim 4), the flat rhombus sealed speaker box (1) _B ) Are provided so as to cut off the two opposite corners, and in the present invention (Claim 5), a flat rhombus sealed speaker box (1) is provided. _C ) Of the two opposite corners of the cut side (4) _C1 4 _C2 ) Is provided so that the flat surface after excision is S-shaped.
[0026]
The selected microphone (12 ₁ Or 12 ₂ ) Is considered to comprise means capable of visual display.
Therefore, according to the present invention, by making the speaker box have a shape having a cut-off side surface, transmission from all directions can be identified without blind spots, and only one of the two microphones closer to the transmission direction is standard. Because the other is given appropriate attenuation, the disturbance of the transmission frequency characteristics due to the two-point sound collection method can be eliminated, and the invalid sound collection of ambient noise can be suppressed, and there is no call Appropriate attenuation is given to both microphones in the normal state, and it is possible to suppress the collection and transmission of unnecessary ambient noise. In addition, both microphones are appropriately attenuated in the reception state, and are canceled by the differential amplifier circuit. However, since the effect is also added, the acoustic coupling from the speaker to the microphone can be greatly improved as compared with a single microphone, and a high-quality call can be made.
[0027]
【Example】
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 2 is a diagram showing a circuit configuration of an audio conference apparatus according to an embodiment of the present invention (Claims 1 and 6), and FIG. 3 shows an audio conference apparatus according to an embodiment of the present invention (Claims 2 and 6). FIG. 4 is a diagram showing a circuit configuration, FIG. 4 is a diagram showing an acoustic configuration of an audio conference apparatus according to an embodiment of the present invention (Claim 3), and FIG. 5 is an embodiment of the present invention (Claim 4). FIG. 6 is a diagram showing an acoustic configuration of the audio conference apparatus, and FIG. 6 is a diagram showing an acoustic configuration of the audio conference apparatus according to an embodiment of the present invention (Claim 5). Note that the same reference numerals denote the same objects throughout the drawings.
[0028]
First, an embodiment of the present invention (claims 1, 3 and 6) will be described with reference to FIGS.
The audio conference apparatus (10) shown in FIG. 2 has a speaker box (1) as shown in FIG. _A ).
[0029]
Speaker box (1 _A ) Has two flat side surfaces (3 _A3 ) And (3 _A4 ) And parallel cut sides (4 _A1 ) And (4 _A2 ).
[0030]
The speaker (11) is connected to a speaker box (1 _A ) Top surface (2) _A ) Is attached to the outside at the center.
A pair of unidirectional microphones (12) [individual microphones (12 ₁ ) And (12 ₂ ), The same applies to the following: _A1 ) And (4 _A2 ), The directivity axis is arranged in the tangential direction and the opposite direction of the center circle drawn around the center of the speaker (11).
[0031]
Each microphone (12 ₁ ) And (12 ₂ The directivity characteristics of _A1 ) And (4 _A2 ) Is slightly deviated from the main directing axis as shown in FIG.
[0032]
As a result, the audio signal input from the directions (a), (b), (c) and (d) in FIG. ₁ ) Front or side directional sensitivity of the speaker box (1 _A ) Separated microphone (12 ₂ ) Higher than rear or side directivity, microphone (12 ₁ ) Output signal from the microphone (12 ₂ It is clear that the output signal is higher than the output signal from).
[0033]
Also, compared with the third reference value such as average ambient noise, the microphone (12 ₁ It is clear that the output signal from
Similarly, an audio signal input from the (e), (f), (g) and (h) directions in FIG. ₂ ) Front or side directional sensitivity of the speaker box (1 _A ) Separated microphone (12 ₁ ) Higher than rear or side directivity, microphone (12 ₂ ) Output signal from the microphone (12 ₁ It is clear that the output signal is higher than the output signal from).
[0034]
Also, compared with the third reference value such as average ambient noise, the microphone (12 ₂ It is clear that the output signal from
Next, in FIG. 2, it is assumed that the voice conference apparatus (10) is in a no-call state in which no voice is transmitted from the surroundings and no incoming signal arrives from the telephone line (20).
[0035]
In such a state, the microphone (12 ₁ ) And (12 ₂ ), Only ambient noise in the room where the audio conference apparatus (10) is installed is input.
Microphone (12 ₁ ) And (12 ₂ ) Ambient noise (N _R1 ) And (N _R2 ) Is a microphone signal detection circuit (16). ₁ ) And (16 ₂ ) Through the comparison circuit (19 ₁ ) And (19 ₂ ) And a noise detection circuit (17).
[0036]
The noise detection circuit (17) includes a microphone (12 ₁ ) And (12 ₂ ) From the microphone signal detection circuit (16 ₁ ) And (16 ₂ ) Ambient noise (N _R1 ) And (N _R2 ) For a long time average noise component (N) using a long charge time constant circuit and a short discharge time constant circuit. _M ) Are extracted, and each comparison circuit (19) is connected via an adder (18). ₁ ) And (19 ₂ ) Input to the inverting input terminal (-).
[0037]
The noise detection circuit (17) outputs the extracted long-time average noise component (N _M ) To the microphone signal detection circuit (16) in a no-call state by adding a slight gain or superimposing a DC bias. ₁ ) And (16 ₂ ) To the comparison circuit (19 ₁ ) And (19 ₂ ) Ambient noise (N) input to the non-inverting input terminal (+) _R1 ) And (N _R2 ) From the noise detection circuit (17) via the adder (18). ₁ ) And (19 ₂ ) Long-time average noise component (N) respectively input to the inverting input terminal (−) of _M ) Is always set to a high level (H).
[0038]
Comparison circuit (19 ₁ ) And (19 ₂ ) Are long-time average noise components (N _M ) Are ambient noise (N) input to the non-inverting input terminal (+). _R1 ) And (N _R2 ) At a higher level (H), the comparison signal (C ₁ ) And (C ₂ ) Are set to a low level (L).
[0039]
Each comparison circuit (19 ₁ ) And (19 ₂ ) Output from the comparison signal (C ₁ ) And (C ₂ ) Is a variable loss circuit (1B) ₁ ) And (1B ₂ ) And a light emitting diode (1A) ₁ ) And (1A ₂ ).
[0040]
Variable loss circuit (1B ₁ ) And (1B ₂ ) Is a comparison signal (C ₁ ) And (C ₂ ) Are set to a low level (L), all are set to a predetermined loss state (for example, about 15 dB).
[0041]
The light emitting diode (1A ₁ ) And (1A ₂ ) Is an input comparison signal (C ₁ ) And (C ₂ ) Are set to a low level (L), no light is emitted, and any microphone (12 ₁ ) And (12 ₂ ) Also indicates that you are not transmitting.
[0042]
As a result, the microphone (12 ₁ ) Ambient noise (N _R1 ) Is a transmitter amplifier (1C ₁ ) And a variable loss circuit (1B) set to a predetermined loss state ₁ ) Through the differential amplifier circuit (1D) and the microphone (12 ₂ ) Ambient noise (N _R2 ) Transmitter amplifier (1C ₂ ) And a variable loss circuit (1B) set to a predetermined loss state ₂ ) To the differential amplifier circuit (1D).
[0043]
Therefore, the differential ambient noise (N _R ) Is also sufficiently attenuated and is input to the two-wire 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 transmitted to the speaker (11) via the receiver amplifier (13).
[0044]
Next, in FIG. 2, the voice conference device (10) is sent from the direction (a), (b), (c) or (d) in FIG. ₁ ) Is set to the microphone (12). ₂ ) And higher than the ambient noise in the room, and it is assumed that there is no incoming signal from the telephone line (20), and that there is a transmission state.
[0045]
In such a state, the microphone (12 ₁ ) Is input to the microphone (12) together with the ambient noise and a speech having a higher level than the ambient noise. ₂ ) Is transmitted together with the ambient noise, a transmission level lower than the ambient noise.
[0046]
Microphone (12 ₁ ) And (12 ₂ ) Input speech signals (V) _S1 ) And (V _S2 ) Is a comparison circuit (19). ₁ ) And (19 ₂ ) Is input to the non-inverting input terminal (+) and to the noise detection circuit (17), but is averaged for a long time by the noise detection circuit (17). There is no output.
[0047]
The microphone (12 ₁ ) And (12 ₂ ) Ambient noise (N _R1 ) And (N _R2 ) Is the signal detection circuit (16) as described above. ₁ ) And (16 ₂ ) Through the comparison circuit (19 ₁ ) And (19 ₂ ) Input to the non-inverting input terminal (+) and also to the noise detection circuit (17). The noise detection circuit (17) causes the long-term average noise component (N _M ) Are extracted, and each comparison circuit (19) is added via an adder (18). ₁ ) And (19 ₂ ) Input terminal (-).
[0048]
Comparison circuit (19 ₁ ) Is a transmission signal (V) input to the non-inverting input terminal (+). _S1 ) Is the long-term average noise component (N _M ) At a higher level (H), the comparison signal (C ₁ ) Is set to a high level (H).
[0049]
Comparison circuit (19 ₂ ) Is a long-term average noise component (N) input to the inverting input terminal (−). _M ) Is transmitted to the non-inverting input terminal (+) (V) _S2 ) At a higher level (H), the comparison signal (C ₂ ) Is set to a low level (L).
[0050]
Variable loss circuit (1B ₁ ) Is a comparison circuit (19). ₁ ) Input from the comparison signal (C ₁ ) Is set to a high level (H), the lossless state is set, and the variable loss circuit (1B) is set. ₂ ) Is a comparison circuit (19). ₂ ) Input from the comparison signal (C ₂ ) Is set to a low level (L), it is set to a predetermined loss state (= about 15 dB) as described above.
[0051]
As a result, the microphone (12 ₁ ) Input speech signal (V _S1 ) Is a transmitter amplifier (1C ₁ ) And lossless variable loss circuit (1B) ₁ ) Through the differential amplifier circuit (1D) and the microphone (12 ₂ ) Input speech signal (V _S2 ) Is a transmitter amplifier (1C ₂ ) And a variable loss circuit (1B) set to a predetermined loss state ₂ ) To the differential amplifier circuit (1D).
[0052]
Therefore, the differential amplifier circuit (1D) is connected to the microphone (12 ₁ ) Input speech signal (V _S1 ) Is input to the two-wire four-wire conversion circuit (1E) and sent to the telephone line (20) via the two-wire four-wire conversion circuit (1E). However, it is transmitted to the speaker (11) via the receiver amplifier (13), but since it is sufficiently attenuated by the two-wire four-wire conversion circuit (1E), there is no possibility of being output from the speaker (11).
[0053]
The light emitting diode (1A ₁ Only the comparison signal (C ₁ ) Is set to a high level (H), light is emitted and the microphone (12 ₁ ) Indicates a transmission state.
[0054]
Next, in FIG. 2, the received signal (V) from the telephone line (20) to the voice conference device (10). _R ) Arrives, the incoming call signal (V _R ) Is input to the speaker (11) through the two-wire four-wire conversion circuit (1E) and the reception amplifier (13), and is transmitted to the room as reception voice, and is also input to the reception signal detection circuit (14). The
[0055]
The received signal detection circuit (14) receives the received received signal (V _R ) And output to the adder (15).
On the other hand, the microphone (12 ₁ ) And (12 ₂ ) Includes room ambient noise (N _R1 ) And (N _R2 ) Only, and the microphone signal detection circuit (16 ₁ ) And (16 ₂ ) Through the comparison circuit (19 ₁ ) And (19 ₂ ) And a noise detection circuit (17).
[0056]
The noise detection circuit (17) performs a long-time average noise component (N _M ) Are extracted and output to the adder (18).
Adders (15) and (18) receive the reception signal (V) output from the reception signal detection circuit (14). _R ) And the long-time average noise component (N) output from the noise detection circuit (17) _M ) And each comparison circuit (19 ₁ ) And (19 ₂ ) Input to the inverting input terminal (-).
[0057]
As a result, each comparison circuit (19 ₁ ) And (19 ₂ ) To the inverting input terminal (−), the long-time average noise component (N _M ) With a higher level of reception signal (V _R ) And long-term average noise component (N _M ) Is added.
[0058]
Therefore, the received voice output from the speaker (11) is converted into a microphone (12) for acoustic coupling. ₁ ) Or (12 ₂ ), The received signal (V) input to the inverting input terminal (−). _R ) And long-term average noise component (N _M ) Cannot reach a level higher than the addition result, and each comparison circuit (19 ₁ ) And (19 ₂ ) Output from the comparison signal (C ₁ ) And (C ₂ ) Are set to low levels, and variable loss circuits (1B) ₁ ) And (1B ₂ ) And a light emitting diode (1A) ₁ ) And (1A ₂ ) And variable loss circuit (1B) ₁ ) And (1B ₂ ) Is set to a predetermined loss state [= about 15 dB].
[0059]
As a result, the microphone (12 ₁ ) And (12 ₂ ) Input from acoustically coupled and ambient noise (N _R1 ) And (N _R2 ) Transmitter amplifier (1C ₁ ) And (1C ₂ ) And a variable loss circuit (1B) set to a predetermined attenuation amount ₁ ) And (1B ₂ ) Is sufficiently attenuated.
[0060]
The light emitting diode (1A ₁ ) And (1A ₂ ) Is an input comparison signal (C ₁ ) And (C ₂ ) Are set to a low level (L), no light is emitted, and any microphone (12 ₁ ) And (12 ₂ ) Also indicates that you are not transmitting.
[0061]
Next, examples of the present invention (claims 2, 3 and 6) will be described with reference to FIGS.
The audio conference apparatus (10) shown in FIG. 3 has a speaker box (1) as shown in FIG. _A ), And a speaker (11) and a pair of microphones (12 ₁ ), (12 ₂ ) Is the same as described above, and as a result, from the (a), (b), (c), (d), (e), (f), (g) and (h) directions in FIG. A microphone (12 ₁ ) And (12 ₂ ) Outputs a higher level output signal.
[0062]
Next, in FIG. 3, it is assumed that the voice conference apparatus (10) is in a no-call state in which there is no transmission from the surroundings and no incoming signal from the telephone line (20) arrives.
In such a state, the microphone (12 ₁ ) And (12 ₂ ), Only ambient noise in the room where the audio conference apparatus (10) is installed is input.
[0063]
Microphone (12 ₁ ) And (12 ₂ ) Ambient noise (N _R1 ) And (N _R2 ) Is a microphone signal detection circuit (16). ₁ ) And (16 ₂ ) To the comparison circuit (1G) and the level determination circuit (1H).
[0064]
The reception signal detection circuit (1K) arrives from the telephone line (20) and is input to the speaker (11) via the two-wire four-wire conversion circuit (1E) and the reception amplifier (13). _R ) Is detected, the output signal (R) is set to a low level (L). _R ) Is not detected, the output signal (R) is set to a high level (H).
[0065]
The comparison circuit (1G) includes a microphone (12 ₁ ) To microphone signal detection circuit (16 ₁ ) Ambient noise (N) input to the inverting input terminal (−) via _R1 ) And microphone (12 ₂ ) To microphone signal detection circuit (16 ₂ ) Ambient noise (N) input to the non-inverting input terminal (+) via _R2 ) And the condition (N _R1 )> (N _R2 ) Is established, the comparison signal (C) is set to a low level (L), and the condition (N _R1 ) <(N _R2 ) Is established, the comparison signal (C) is set to a high level (H).
[0066]
Further, the level determination circuit (1H) includes a microphone (12 ₁ ) And (12 ₂ ) From the microphone signal detection circuit (16 ₁ ) And (16 ₂ ) Ambient noise (N _R1 ) And (N _R2 ) Level difference absolute value is greater than or equal to a preset reference value. If the level difference absolute value is less than or equal to the reference value, the output judgment signal (D) is low level. If the absolute value of the level difference exceeds the reference value, the determination signal (D) to be output is set to the high level (H).
[0067]
In no-call state, the condition (N _R1 ) = (N _R2 ) Is established, the determination signal (D) output from the level determination circuit (1H) is indefinite, but the determination signal (D) output from the level determination circuit (1H) is at a low level (L). Therefore, the AND gate (1F) is cut off, and the output signal (G) regardless of the output signal (R) from the reception signal detection circuit (1K). ₀ ) Is set to a low level (L), so that the AND gate (1J ₁ ) And (1J ₂ ) Is also cut off, and the output signal (G) regardless of the comparison signal (C) from the comparison circuit (1G). ₁ ) And (G ₂ ) Is set to a low level (L).
[0068]
Each AND gate (1J ₁ ) And (1J ₂ ) Output signal (G ₁ ) And (G ₂ ) Is a variable loss circuit (1B) ₁ ) And (1B ₂ ) And a light emitting diode (1A) ₁ ) And (1A ₂ ).
[0069]
Variable loss circuit (1B ₁ ) And (1B ₂ ) Is an output signal (G ₁ ) And (G ₂ ) Are set at a low level (L), all are set to a predetermined attenuation amount (= attenuation amount of about 15 dB).
[0070]
As a result, the microphone (12 ₁ ) Ambient noise (N _R1 ) Is a transmitter amplifier (1C ₁ ) And a variable loss circuit (1B) set to a predetermined attenuation ₁ ) Through the differential amplifier circuit (1D) and the microphone (12 ₂ ) Ambient noise (N _R2 ) Transmitter amplifier (1C ₂ ) And a variable loss circuit (1B) set to a predetermined attenuation ₂ ) To the differential amplifier circuit (1D).
[0071]
Therefore, the differential ambient noise (N _R ) Is also sufficiently attenuated and is input to the two-wire 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 transmitted to the speaker (11) via the receiver amplifier (13).
[0072]
Next, in FIG. 3, the voice conference device (10) is transmitted from the direction (a), (b), (c) or (d) in FIG. ₁ ) Is set to the microphone (12). ₂ It is assumed that the transmission level is higher than the transmission level input in (1) and higher than the ambient noise in the room, and no incoming signal arrives from the telephone line (20).
[0073]
In such a state, the microphone (12 ₁ ) Is input with high-level speech along with ambient noise, and a microphone (12). ₂ ) Is input with low-level transmission along with ambient noise.
[0074]
Microphone (12 ₁ ) And (12 ₂ ) Input speech signals (V) _S1 ) And (V _S2 ) Is input to the comparison circuit (1G) and the level determination circuit (1H) as described above.
[0075]
The comparison circuit (1G), as described above, transmits the transmission signal (V _S1 ) And (V _S2 ) And the condition (N _R1 )> (N _R2 ) Is established, the output comparison signal (C) is set to a low level (L).
[0076]
Also, the level determination circuit (1H) receives the input transmission signal (V _S1 ) And (V _S2 ) Level difference absolute value is greater than or equal to a preset reference value. If the level difference absolute value exceeds the reference value, the output judgment signal (D) is increased. The level (H) is set, and the logical product gate (1F) is set to the conductive state.
[0077]
The reception signal detection circuit (1K) is configured to receive the reception signal (V _R ) Is not detected, the output signal (R) is set to a high level (H).
As a result, the AND gate (1F) outputs the output signal (G ₀ ) Is set to a high level (H), and the AND gate (1J ₁ ) And (1J ₂ ) Is also set to the conductive state.
[0078]
The comparison signal (C) [= low level (L)] output from the comparison circuit (1G) is supplied to the AND gate (1J) via the inverting circuit (1I). ₁ ) And a direct AND gate (1J ₂ AND gate (1J) ₁ ) Output signal (G ₁ ) Is set to the high level (H) and the variable loss circuit (1B) ₁ ) And light emitting diode (1A) ₁ ) And AND gate (1J ₂ ) Output signal (G ₂ ) Is set to a low level (L) and a variable loss circuit (1B) ₂ ) And light emitting diode (1A) ₂ ).
[0079]
Variable loss circuit (1B ₁ ) Is an AND gate (1J ₁ ) Output signal (G ₁ ) Is set to a high level (H), the lossless state is set, and the variable loss circuit (1B) is set. ₂ ) Is an AND gate (1J ₂ ) Output signal (G ₂ ) Is set to a low level (L), it is set to a predetermined attenuation amount [= attenuation amount of about 15 decibels] as described above.
[0080]
As a result, the microphone (12 ₁ ) Input speech signal (V _S1 ) Is a transmitter amplifier (1C ₁ ) And lossless variable loss circuit (1B) ₁ ) Through the differential amplifier circuit (1D) and the microphone (12 ₂ ) Input speech signal (V _S2 ) Is a transmitter amplifier (1C ₂ ) And a variable loss circuit (1B) set to a predetermined attenuation ₂ ) To the differential amplifier circuit (1D).
[0081]
Therefore, the differential amplifier circuit (1D) is connected to the microphone (12 ₁ ) Input speech signal (V _S1 ) Is input to the two-wire four-wire conversion circuit (1E) and sent to the telephone line (20) via the two-wire four-wire conversion circuit (1E). However, it is transmitted to the speaker (11) via the receiver amplifier (13), but since it is sufficiently attenuated by the two-wire four-wire conversion circuit (1E), there is no possibility of being output from the speaker (11).
Next, in the transmission state, the microphone (12 ₁ ) Is input, the comparison signal (C) output from the comparison circuit (1G) is set to a low level, and the determination signal (D) output from the level determination circuit (1H) is set to a high level (H ) And AND gates (1F) and (1J ₁ ) Output signal (G ₀ ) And (G ₁ ) Is high level (H), AND gate (1J ₂ ) Output signal (G ₂ ) Is set to a low level (L), and the variable loss circuit (1B) ₁ ) Is lossless, variable loss circuit (1B) ₂ ) Is set to a predetermined attenuation, and the microphone (12 ₁ ) Input speech signal (V _S1 ) Is sent to the telephone line (20).
[0082]
In this state, an incoming signal (V) is sent from the telephone line (20) to the voice conference device (10). _R ) Arrives, the received signal (V _R ) Is input to the speaker (11) through the two-wire four-wire conversion circuit (1E) and the reception amplifier (13), and is transmitted to the room as reception voice, and is also input to the reception signal detection circuit (14). The
[0083]
The received signal detection circuit (14) receives the received received signal (V _R ) Is detected, the output signal (R) input to the logical product gate (1F) is set to a low level (L).
As a result, the logical product gate (1F) is set to the cut-off state, and the logical product gate (1J) regardless of the judgment signal (D) output from the level judgment circuit (1H). ₁ ) And (1J ₂ ) Output signal (G ₀ ) Is set to a low level (L), so that the AND gate (1J ₁ ) And (1J ₂ ) Is also cut off, and the output signal (G) regardless of the comparison signal (C) from the comparison circuit (1G). ₁ ) And (G ₂ ) Is set to a low level (L).
[0084]
Variable loss circuit (1B ₁ ) Is the output signal (G ₁ ) Is changed from a high level (H) to a low level (L), the setting is changed from a lossless state to a predetermined attenuation [attenuation of about 15 dB], and the variable loss circuit (1B) is changed. ₂ ) Is the output signal (G ₂ ) Is held at a low level (L), the predetermined attenuation amount [= attenuation amount of about 15 dB] is continuously set.
[0085]
As a result, the received signal (V _R ) Arrives, the microphone (12 ₁ ) Input speech signal (V _S1 ) Is a variable loss circuit (1B) set to a predetermined attenuation. ₁ ) Is input to the differential amplifier circuit (1D), and thus the received voice output from the speaker (11) is converted into the microphone (12) for acoustic coupling. ₁ ) Or (12 ₂ ) Will be sufficiently attenuated.
[0086]
Light emitting diode (1A ₁ ) And (1A ₂ ) Is the input output signal (G ₁ ) And (G ₂ ) Is set to a high level (H), and the microphone (12) is in the transmitting state as described above. ₁ ) And (12 ₂ ) Is displayed.
[0087]
As is apparent from the above description, according to the embodiments of the present invention (claims 1, 2 and 6), the speaker box (1 _A ) In the shape as shown in FIG. 4, transmission from all directions can be identified without a dead point, and two microphones (12 ₁ ) And (12 ₂ ), Only one closer to the transmission direction operates at the standard sensitivity, and the other is given appropriate attenuation, so it is possible to eliminate the disturbance in the transmission frequency characteristics due to the two-point sound collection method, and the surroundings Ineffective noise pickup can be suppressed, high-quality calls can be made, and both microphones (12 ₁ ) And (12 ₂ ) Is appropriately attenuated, so that the collection and transmission of unnecessary ambient noise can be suppressed, and both microphones (12) are also used in the reception state in the same manner as described above. ₁ ) And (12 ₂ ) Is appropriately attenuated, and a canceling effect by the differential amplifier circuit (1D) is also added, so that the speaker (11) to the microphone (12 ₁ ) And (12 ₂ ) Can be improved by about 20 decibels compared to a single microphone.
[0088]
FIGS. 2 to 4 are merely examples of the present invention. For example, a speaker box (1 _A ) Is not limited to that shown in FIG. 4, and a flat rhombus sealed speaker box (1) as shown in FIG. _B ) And cut off the two opposite corners of each other (4) _B1 ) And (4 _B2 ), And the resected side (4 _B1 ) And (4 _B2 ) With microphone (12 ₁ ) And (12 ₂ ) To the speaker box (1 _A ), Or as shown in FIG. 6, a flat rhombus sealed speaker box (1) _C ) Of the two opposite corners of the cut-out side (4 _A1 4 _A2 ) To the side of the cut (4 _B1 ) And (4 _B2 ), And the resected side (4 _B1 ) And (4 _B2 ) With microphone (12 ₁ ) And (12 ₂ ) To the speaker box (1 _A A number of other modifications are considered, such as mounting in the same manner as in (1), but the effect of the present invention does not change in any case.
[0089]
Further, the circuit configuration of the audio conference apparatus (10) is not limited to that shown in the figure, and various other modifications are considered within the scope described in the claims. However, the effect of the present invention is not changed.
[0090]
【The invention's effect】
As described above, according to the present invention, the speaker box has a shape having a cut side surface, so that transmission from all directions can be identified without blind spots, and only one of the two microphones closer to the transmission direction is standard. Because the other is given appropriate attenuation, the disturbance of the transmission frequency characteristics due to the two-point sound collection method can be eliminated, and the invalid sound collection of ambient noise can be suppressed, and there is no call Appropriate attenuation is given to both microphones in the normal state, and it is possible to suppress the collection and transmission of unnecessary ambient noise. In addition, both microphones are appropriately attenuated in the reception state, and are canceled by the differential amplifier circuit However, since the effect is also added, the acoustic coupling from the speaker to the microphone can be greatly improved as compared with a single microphone, and a high-quality call can be made.
[Brief description of the drawings]
FIG. 1 is a principle diagram of the present invention.
FIG. 2 is a circuit configuration of an audio conference apparatus according to an embodiment of the present invention (claims 1 and 6);
FIG. 3 is a circuit configuration of an audio conference apparatus according to an embodiment of the present invention (claims 2 and 6);
FIG. 4 is an audio configuration of an audio conference apparatus according to an embodiment of the present invention (Claim 3);
FIG. 5 shows the acoustic configuration of the audio conference apparatus according to an embodiment of the present invention (claim 4).
FIG. 6 shows an audio configuration of an audio conference apparatus according to an embodiment of the present invention (Claim 5).
[Explanation of symbols]
1 Speaker box
2 Top surface
3 side
4 Resection side
10 Audio conferencing equipment
11 Speaker
12 Microphone
13 Receiver amplifier
14, 1K incoming signal detection circuit
15, 18 Adder
16 Microphone signal detection circuit
17 Noise detection circuit
19, 1G comparison 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 judgment circuit
1I Inversion circuit
20 Telephone line
100 logic circuits

Claims (6)

In the center of the upper surface of the flat sealed speaker box, a speaker is provided to the outside,
On the two side surfaces of the speaker box, there are opposed parallel cut side surfaces that are equidistant from the center of the speaker,
Each parallel cut side has a pair of unidirectional microphones,
Each of the microphones includes an acoustic configuration in which a directional axis is arranged in a tangential direction and a direction opposite to a center circle drawn with the center of the speaker as a center,
A noise detection circuit for detecting a long-term average level of ambient noise from an output signal from each microphone;
During no call or during transmission, the output signal from each microphone is compared with the output signal 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 at the time of receiving a call;
According to the comparison result of each comparison circuit, a pair of variable loss circuits that cancels 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 differential amplifier circuit that differentially amplifies the output signal of each microphone output via each variable loss circuit;
An audio conference apparatus that automatically selects a microphone that operates during transmission. In the center of the upper surface of the flat sealed speaker box, a speaker is provided to the outside,
On the two side surfaces of the speaker box, there are opposed parallel cut side surfaces that are equidistant from the center of the speaker,
Each parallel cut side has a pair of unidirectional microphones,
Each of the microphones includes an acoustic configuration in which a directional axis is arranged in a tangential direction and a direction opposite to a center circle drawn with the center of the speaker as a center,
A comparison circuit for comparing output signals from both microphones;
A level determination circuit for determining the level difference between the output signals from both microphones;
A logic circuit for identifying a call state of the audio conference device based on a reception signal to the speaker and an output signal from the comparison circuit and the level determination circuit;
Based on the identification result of the logic circuit, during transmission, the comparison result of the comparison circuit cancels the attenuation added to the output signal of the microphone on the high output side,
A pair of variable loss circuits for prohibiting the cancellation of attenuation applied to the output signals of both microphones during no-call or during reception;
A differential amplifier circuit that differentially amplifies the output signal of each microphone output via each variable loss circuit;
An audio conference apparatus that automatically selects a microphone that operates during transmission and a transmission level of the microphone. 3. The audio conference apparatus according to claim 1, wherein the cut side faces are provided at two circular side faces of a flat cylindrical sealed speaker box. 3. The audio conference apparatus according to claim 1, wherein the cut side surface is provided so as to cut off two opposite corners of a flat rhombus sealed speaker box. 3. The cut side surface includes two opposite corners of a flat rhombus-shaped sealed speaker box, and the cut side surface is provided so that a flat surface after the cut has an S shape. The audio conference apparatus described. The audio conference apparatus according to claim 1 or 2, wherein the selected microphone includes means capable of visual display.

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