JP4470413B2 - Microphone / speaker integrated configuration / communication device - Google Patents

Description

The present invention relates to a microphone / speaker integrated configuration / communication device suitable for use, for example, when a plurality of conference participants in two conference rooms conduct a conference by voice.
In particular, the present invention relates to a microphone / speaker integrated configuration / communication device, without using a special signal generator or signal measurement device, and by utilizing the functions of the microphone / speaker integrated configuration / communication device itself. The present invention relates to a technique for automatically adjusting the degree of acoustic coupling between a microphone and a plurality of microphones.

  A video conference system is used in order for conference participants in two conference rooms located at distant locations to hold a conference. The video conference system captures the appearance of the conference participants in each conference room with the imaging means, collects the sound with the microphone, and transmits the image captured with the imaging means and the sound collected with the microphone through the communication path. The transmitted image is displayed on the display unit of the television receiver in the other party's conference room, and the sound collected from the speaker is output.

In such a video conference system, in each conference room, a problem has been encountered in that it is difficult to collect the voice of a speaker who is away from the imaging means and the microphone. A microphone may be provided for each participant.
There is also a problem that the audio output from the speaker of the television receiver is difficult to hear for conference participants located at a position away from the speaker.

  In JP 2003-87887 A and JP 2003-87890 A, in addition to a normal video conference system that provides video and audio when a video conference is performed between conference rooms located at a distance from each other, The microphone and the speaker are integrated so that the voice of the conference attendee in the conference room can be heard clearly from the speaker and is not easily affected by the noise in the conference room on this side or the burden on the echo canceller is low. An audio input / output device is disclosed.

For example, a voice input / output device disclosed in Japanese Patent Laid-Open No. 2003-87887 is described with reference to FIGS. Supported from the bottom to the top by a speaker box 5 with a built-in speaker 6, a conical reflector 4 that diffuses a sound that opens radially upward, a sound shielding plate 3, and a column 8. A plurality of unidirectional microphones (four in FIGS. 6 and 7 and six in FIG. 23) are arranged radially at equal angles on a horizontal plane. The sound shielding plate 3 is for shielding the sound from the lower speaker 5 from entering a plurality of microphones.
Japanese Patent Laid-Open No. 2003-87887 JP 2003-87890 A

The audio input / output devices disclosed in Japanese Patent Laid-Open Nos. 2003-87887 and 2003-87890 are used as means for complementing a video conference system that provides video and audio.
However, as a remote conferencing system, it is often sufficient to use only audio without using a complicated device such as a video conference system. For example, when multiple meeting participants are having a meeting between the same company headquarters and a remote sales office, they are also acquaintances and understand each other's real voice, so they talk on the phone. In addition, it is possible to hold a conference sufficiently without using the video conference system.
In addition, when a video conference system is introduced, there are disadvantages in that the amount of investment for introducing the video conference system itself, the complexity of operation, and the communication burden for transmitting captured images are large.

  Assuming the case where it is applied to such an audio-only conference, the audio input / output devices disclosed in Japanese Patent Application Laid-Open Nos. 2003-87887 and 2003-87890 have performance, price, and dimensional aspects. And, there are many improvements in terms of compatibility with the usage environment and usability.

An object of the present invention is to provide a communication device that is further improved in terms of performance, price, dimensions, suitability for use environment, usability, and the like as a means used only for calls.
In particular, the present invention automatically utilizes the functions of the microphone / speaker integrated configuration / calling device itself without using a special signal generator or signal measurement device, and automatically adjusts the degree of acoustic coupling between the speaker and a plurality of microphones. It is an object of the present invention to provide a microphone / speaker integrated configuration / communication device that is adjustable.

According to the present invention, a speaker , a plurality of microphones that are arranged at the same distance from the speaker and detect audio signals , an external output terminal, an input terminal to which a sound source test noise signal is input , and the microphone detected audio signal is inputted, have adjustable features a gain of the input signal, converts the voice detection signal of the plurality of microphones into a digital signal, a gain controllable a / D converter, the a A first level detecting means for digitally detecting the levels of a plurality of digital conversion signals converted by the / D conversion means and one of the plurality of digital audio signals detected by the first level detecting means are selected. outputs Te, and signal selecting means, provided at the subsequent stage of the signal selecting means, echo cancellation processing for the selected digital audio signal The first echo canceling means and the first echo canceling means for performing the conversion, and converting the input digital voice signal after the echo cancellation processing into an analog voice signal to convert the external output terminal and the speaker. First analog / digital conversion means, level judgment / gain control means for level judgment and gain adjustment, and random power test noise signal are generated, and the power test noise signal is output to the input terminal Test signal generating means for performing, and second echo cancellation means for performing echo cancellation processing on the power supply test noise signal input to the input terminal ,
The output of the second echo cancellation means is added to the audio signal detected by each microphone and input to the A / D conversion means capable of gain adjustment.
The level judgment and gain control means, the detection signal of the above plurality of microphones detected by the first level detection means, so that acoustic coupling degree between the speaker and the plurality of microphones is equal, detected by the microphone Digitally adjusting the gain of the A / D conversion means corresponding to the voice signal
Ma Ikurofon loudspeaker integral structure type-communication device is provided.

Preferably, the microphone loudspeaker integral structure type-communication device may further include a second level detecting means for detecting the level of the digital audio signal to be output to the external output terminal, upper sharp bell judgment and gain control The means inputs and monitors the audio signal detected by the second level detection means, and the first level detection so that the level of the digital audio signal output to the external output terminal becomes a predetermined level. The level of the audio signal detected by the means and output to the external output terminal is adjusted.

Also preferably, the microphone loudspeaker integral structure type-call device further includes a digitally adjusted, variable attenuation means the amplitude of the converted signal by the adjustable gain A / D converter, the The level determination / gain control means digitally adjusts the gain of the A / D conversion means capable of gain adjustment and / or the attenuation of the variable attenuation means.

Preferably, the plurality of microphones are arranged at equal intervals along an outer periphery of a predetermined circle centered on the position where the speaker is disposed, and at least one pair of microphones disposed at positions facing each other with the speaker as a center. have, the gain controllable a / D conversion means converts every two microphones detection signals of a pair of opposed, has a common gain to the two signals,
The level determination / gain control means adjusts the attenuation amount of the variable attenuation means so that the sensitivity difference between the pair of two microphone detection signals falls within a predetermined range, and then the pair of opposing pairs. The gain of the A / D conversion means is adjusted so that the two microphone detection signals are within a predetermined range with the level of the two microphone detection signals of the other opposing pairs.

Further, according to the present invention, a speaker, a plurality of microphones that are arranged at the same distance from the speaker and detect audio signals, an external output terminal, an input terminal to which a sound source test noise signal is input, and the microphone A / D conversion means for converting the voice detection signal into a digital signal and the amplitudes of the plurality of voice signals converted by the A / D conversion means can be digitally adjusted. One of a variable attenuation means, a first level detection means for digitally detecting the levels of a plurality of audio output signals of the variable attenuation means, and a plurality of digital audio signals detected by the first level detection means. Echo cancel processing for the selected digital audio signal provided at the subsequent stage of the signal selection means and the signal selection means for selecting and outputting The first echo canceling means and the first echo canceling means for performing the conversion, and converting the input digital voice signal after the echo cancellation processing into an analog voice signal to convert the external output terminal and the speaker. First analog / digital conversion means, level judgment / gain control means for level judgment and gain adjustment, and random power test noise signal are generated, and the power test noise signal is output to the input terminal A test signal generating means for performing, and a second echo canceling means for performing echo cancellation processing on the power supply test noise signal input to the input terminal,
The output of the second echo cancellation means is added to the audio signal detected by each microphone and input to the A / D conversion means capable of gain adjustment.
The level determination / gain control means is configured such that the detection signals of the plurality of microphones indicate that the detection signals of the plurality of microphones detected by the first level detection means have an acoustic coupling degree between the speaker and the plurality of microphones. Digitally adjusting the attenuation amount of the variable attenuation means corresponding to the audio signal detected by the microphone so as to be equal;
A microphone / speaker integrated configuration / communication device is provided.

Preferably, the microphone / speaker integrated configuration / communication device further includes second level detection means for detecting a level of a digital audio signal output to the external output terminal, and the level determination / gain control means includes: The audio signal detected by the second level detection means is input and monitored, and the digital signal output to the external output terminal is set at a predetermined level by the first level detection means. The level of the audio signal that is detected and output to the external output terminal is adjusted.

Preferably, the test signal generating means generates a white noise or pink noise signal as the power supply test noise signal having no periodicity.
Preferably, both of the power test noise signal from the input terminal and the output signal of the first echo cancellation processing unit are input to the second echo cancellation unit.

  In the present invention, the microphone, the speaker integrated configuration type, the microphone / speaker integrated configuration type used as a communication device, and the function of the communication device can be used without preparing a special device, and a plurality of microphones. Can be automatically and easily equalized.

First, an application example of the microphone / speaker integrated configuration / communication device (hereinafter referred to as a communication device) of the present invention will be described.
1A to 1C are configuration diagrams showing an example to which the microphone / speaker integrated configuration type communication device of the present invention is applied.
As illustrated in FIG. 1A, communication devices 1A and 1B are installed in two remote conference rooms 901 and 902, respectively, and these communication devices 1A and 1B are connected by a telephone line 920. Yes.
As illustrated in FIG. 1B, in the two conference rooms 901 and 902, the communication devices 1A and 1B are placed on the tables 911 and 912, respectively. However, in FIG. 1B, only the communication device 1A in the conference room 901 is illustrated for simplification of illustration. The same applies to the communication device 1B in the conference room 902. FIG. 2 shows an external perspective view of the communication devices 1A and 1B.
As illustrated in FIG. 1C, a plurality (six in this embodiment) of conference participants A1 to A6 are located around the communication devices 1A and 1B, respectively. However, in FIG. 1C, only the conference participants around the communication device 1A in the conference room 901 are illustrated for simplification. The arrangement of the conference participants located around the communication device 1B in the other conference room 902 is the same.

The call device of the present invention can respond by voice between the two conference rooms 901 and 902 via the telephone line 920, for example.
Normally, a conversation via the telephone line 920 is performed by one speaker and one speaker, that is, a one-to-one call. Conference participants A1 to A6 can talk to each other. Although details will be described later, the number of speakers at the same time (same time zone) is limited to one each other in order to avoid voice congestion.
Since the call device of the present invention is intended for voice (call), it only transmits voice via the telephone line 920. In other words, a large amount of image data as in the video conference system is not transmitted. Furthermore, since the call device of the present invention compresses and transmits the call of the conference participant, the transmission burden on the telephone line 920 is light.

Configuration of Call Device The configuration of a call device as one embodiment of the present invention will be described with reference to FIGS. FIG. 2 is a perspective view of a communication device as an embodiment of the present invention.
FIG. 3 is a cross-sectional view of the communication device illustrated in FIG.
4 is a plan view of the microphone / electronic circuit housing portion of the communication apparatus illustrated in FIG.

As illustrated in FIG. 2, the communication device 1 includes an upper cover 11, a sound reflection plate 12, a connecting member 13, a speaker housing unit 14, and an operation unit 15.
As illustrated in FIG. 3, the speaker housing portion 14 includes a sound reflection surface 14a, a bottom surface 14b, and an upper sound output opening 14c. The reception / reproduction speaker 16 is accommodated in a lumen 14d which is a space surrounded by the sound reflection surface 14a and the bottom surface 14b. The sound reflecting plate 12 is positioned above the speaker housing portion 14, and the speaker housing portion 14 and the sound reflecting plate 12 are connected by a connecting member 13.

  A constraining member 17 passes through the connecting member 13, and the constraining member 17 is between the constraining member lower fixing portion 14 e on the bottom surface 14 b of the speaker housing portion 14 and the constraining member fixing portion 12 b of the sound reflecting plate 12. Restrained. However, the restraining member 17 is only penetrated by the restraining member penetration portion 14 f of the speaker housing portion 14. The reason why the restraining member 17 penetrates the restraining member through portion 14f and is not restrained here is that the speaker housing portion 14 vibrates due to the operation of the speaker 16, but the vibration is not restrained around the upper sound output opening 14c. Because.

The voice spoken by the speaker in the speaker partner conference room is removed from the upper sound output opening 14c through the reception / reproduction speaker 16, and is transmitted between the sound reflecting surface 12a of the sound reflecting plate 12 and the sound reflecting surface 14a of the speaker accommodating portion 14. It spreads in all directions of 360 degrees around the axis CC along the defined space.
As illustrated, the cross section of the sound reflecting surface 12a of the sound reflecting plate 12 depicts a gentle trumpet arc. The cross section of the sound reflecting surface 12a extends 360 degrees around the axis CC (omnidirectional) and has the illustrated cross sectional shape.
Similarly, as illustrated in the cross section of the sound reflection surface 14a of the speaker housing portion 14, a gentle convex surface is drawn. The cross section of the sound reflecting surface 14a also has the illustrated cross sectional shape over 360 degrees (omnidirectional) about the axis CC.

The sound S emitted from the reception / reproduction speaker 16 passes through the upper sound output opening 14c, passes through the sound output space having a trumpet-shaped cross section defined by the sound reflection surface 12a and the sound reflection surface 14a, and the communication device 1 is mounted. Along the surface of the placed table 911, the sound spreads in all directions 360 degrees around the axis CC, and is heard at a volume equal to all conference participants A1 to A6. In the present embodiment, the surface of the table 911 is also used as part of the sound propagation means.
The diffusion state of the sound S output from the receiving / reproducing speaker 16 is shown by arrows.

The sound reflector 12 supports the printed board 21.
On the printed circuit board 21, as illustrated in FIG. 4, the microphones MC 1 to MC 6, the light emitting diodes LED 1 to 6, the microprocessor 23, the codec (CODEC) 24, and the first digital signal Various electronic circuits such as a processor (DSP) 25, a second digital signal processor (DSP) 26, an A / D converter block 27, a D / A converter block 28, and an amplifier block 29 are mounted on the sound reflector. Reference numeral 12 also functions as a member that supports the microphone / electronic circuit housing portion 2.

  The printed circuit board 21 has a damper 18 that absorbs vibration from the reception / reproduction speaker 16 so that vibration from the reception / reproduction speaker 16 is transmitted to the sound reflector 12 and does not enter the microphones MC1 to MC6. It is attached. The damper 18 includes a screw and a cushioning material such as an anti-vibration rubber inserted between the screw and the printed board 21, and the cushioning material is screwed to the printed board 21 with a screw. That is, the vibration transmitted from the reception / reproduction speaker 16 to the printed circuit board 21 is absorbed by the buffer material. Thus, the microphones MC1 to MC6 are less affected by the sound from the speaker 16.

As shown in FIG. 4, six microphones MC <b> 1 to MC <b> 6 are located radially from the central axis C of the printed circuit board 21 at equal angles (in this embodiment, at intervals of 60 degrees). Each microphone is a unidirectional microphone. Its characteristics will be described later.
Each of the microphones MC1 to MC6 is swingably supported by a first microphone support member 22a and a second microphone support member 22b, both of which are flexible or elastic (in order to simplify the illustration, the microphones (Only the first and second microphone support members 22a and 22b of the MC1 portion are illustrated), in addition to the measures not affected by the vibration from the reception / reproduction speaker 16 by the damper 18 using the cushioning material described above Thus, the first and second microphone support members 22a and 22b having flexibility or elasticity absorb the vibration of the printed circuit board 21 that is vibrated by the vibration from the reception / reproduction speaker 16, thereby affecting the vibration of the reception / reproduction speaker 16. Thus, the noise of the receiving / reproducing speaker 16 is avoided.

As illustrated in FIG. 3, the reception / reproduction speaker 16 is oriented perpendicularly to the central axis CC of the plane on which the microphones MC1 to MC6 are located (in this embodiment, it is directed upward) With the arrangement of the reception / reproduction speaker 16 and the six microphones MC1 to MC6, the distance between the reception / reproduction speaker 16 and each of the microphones MC1 to MC6 is equal. The sound reaches the microphones MC1 to MC6 with almost the same volume and phase. However, due to the configuration of the sound reflecting surface 12a of the sound reflecting plate 12 and the sound reflecting surface 14a of the speaker housing portion 14, the sound of the receiving and reproducing speaker 16 is not directly input to the microphones MC1 to MC6. In addition, as described above, by using the damper 18 using the buffer material and the first and second microphone support members 22a and 22b having flexibility or elasticity, the influence of the vibration of the reception / reproduction speaker 16 is affected. Is reduced.
As shown in FIG. 1C, the conference participants A1 to A6 are usually arranged at substantially equal intervals in the vicinity of the microphones MC1 to MC6 arranged at intervals of 60 degrees in the direction of 360 degrees around the communication device 1. Is located at.

Light- emitting diodes Light-emitting diodes LED1 to 6 are arranged in the vicinity of microphones MC1 to MC6 as an example of means for notifying a speaker (to be described later) (microphone selection result display means 30).
The light emitting diodes LED1 to LED6 are provided so as to be visible from all the conference participants A1 to A6 even when the upper cover 11 is attached. Therefore, the upper cover 11 is provided with a transparent window so that the light emitting states of the light emitting diodes LED1 to LED6 can be visually recognized. Of course, the upper cover 11 may be provided with openings in the portions of the light emitting diodes LEDs 1 to 6, but a light-transmitting window is preferable from the viewpoint of dust prevention to the microphone / electronic circuit housing portion 2.

The printed circuit board 21 includes a first digital signal processor (DSP) 25, a second digital signal processor (DSP) 26, and various electronic circuits 27 to 29 for performing various signal processing described later. It is arranged in a space other than the part where the MC 6 is located.
In the present embodiment, the DSP 25 is used as signal processing means for performing processing such as filter processing and microphone selection processing together with various electronic circuits 27 to 29, and the DSP 26 is used as an echo canceller.

FIG. 5 is a schematic configuration diagram of a microprocessor 23, a codec (CODEC) 24, a DSP 25, a DSP 26, an A / D converter block 27, a D / A converter block 28, an amplifier block 29, and other various electronic circuits.
The microprocessor 23 performs overall control processing of the microphone / electronic circuit housing unit 2. The codec 24 compresses and encodes audio to be transmitted to the other party conference room.
The DSP 25 performs various signal processing described below, such as filter processing and microphone selection processing.
The DSP 26 functions as an echo canceller, and includes an echo cancellation transmission processing unit 261 and an echo cancellation reception unit 262.
In FIG. 5, four A / D converters 271 to 274 are illustrated as an example of the A / D converter block 27, and two D / A converters are illustrated as an example of the D / A converter block 28. As an example of the amplifier block 29, two amplifiers 291 and 292 are illustrated.
In addition, as the microphone / electronic circuit housing portion 2, various circuits such as a power supply circuit are mounted on the printed circuit board 21.

In FIG. 4, a pair of microphones MC1-MC4: MC2-MC5: MC3-M6 arranged in a straight line at symmetrical (or opposite) positions with respect to the central axis C of the printed circuit board 21 each have two channels. The analog signals are input to A / D converters 271 to 273 that convert digital signals. In this embodiment, one A / D converter converts a 2-channel analog input signal into a digital signal.
Therefore, the detection signals of two (one pair) microphones, for example, microphones MC1 and MC4, which are positioned on a straight line across the central axis C, are input to one A / D converter and converted into digital signals. Yes.
Further, in this embodiment, in order to identify the speaker of the voice to be sent to the other party's conference room, the difference between the two microphones positioned on a straight line, the volume of the voice, etc. are referred to. When the signals of two microphones located on the line are input to the same A / D converter, the conversion timing is also substantially the same, and there is little timing error when taking the difference between the audio outputs of the two microphones. There are advantages such as being easy.
The A / D converters 271 to 274 can also be configured as A / D converters 271 to 274 with a variable gain amplification function.
The collected sound signals of the microphones MC1 to MC6 converted by the A / D converters 271 to 273 are input to the DSP 25, and various signal processing described later is performed.
As one of the processing results of the DSP 25, the result of selecting one of the microphones MC <b> 1 to MC <b> 6 is output to the corresponding one of the light emitting diodes LED <b> 1 to LED <b> 6 that is an example of the microphone selection result display unit 30.

The processing result of the DSP 25 is output to the DSP 26 and an echo cancellation process is performed. The DSP 26 includes, for example, an echo cancellation transmission processing unit 261 and an echo cancellation reception unit 262.
The processing result of the DSP 26 is converted into an analog signal by the D / A converters 281 and 282. The output from the D / A converter 281 is encoded by the codec 24 as necessary, and is output to the line-out of the telephone line 920 (FIG. 1A) via the amplifier 291 to the partner conference room. It is output as sound through the reception / reproduction speaker 16 of the installed call device 1.
Voice from the communication device 1 installed in the conference room of the other party is input via the line-in of the telephone line 920 (FIG. 1A), converted into a digital signal by the A / D converter 274, and then sent to the DSP 26. It is input and used for echo cancellation processing. In addition, the voice from the communication device 1 installed in the other party's conference room is applied to the speaker 16 through a route (not shown) and output as sound.
The output from the D / A converter 282 is output as sound from the reception reproduction speaker 16 of the communication device 1 via the amplifier 292. In other words, in addition to the voice of the speaker selected in the other party's conference room from the reception / reproduction speaker 16 described above, the conference participants A1 to A6 also use the reception / reproduction speaker 16 for the voice produced by the speaker in the conference room. Can be heard through.

Microphones MC1 to MC6
FIG. 6 is a graph showing characteristics of the microphones MC1 to MC6.
Each unidirectional characteristic microphone changes its frequency characteristic and level characteristic as illustrated in FIG. 6 depending on the arrival angle of sound from the speaker to the microphone. The plurality of curves indicate directivity when the frequency of the sound collection signal is 100 Hz, 150 Hz, 200 Hz, 300 Hz, 400 Hz, 500 Hz, 700 Hz, 1000 Hz, 1500 Hz, 2000 Hz, 3000 Hz, 4000 Hz, 5000 Hz, and 7000 Hz. However, in order to simplify the illustration, FIG. 6 typically illustrates the directivity for 150 Hz, 500 Hz, 1500 Hz, 3000 Hz, and 7000 Hz.

FIGS. 7A to 7D are graphs showing the spectrum analysis results regarding the position of the sound source and the sound collection level of the microphone. As an example of the analysis, the communication device 1 and a predetermined distance, for example, 1.5 meters are shown. FIG. 5 shows the result of fast Fourier transform (FFT) on sound collected by each microphone with a speaker placed at a distance at regular time intervals. The X axis represents frequency, the Y axis represents signal level, and the Z axis represents time.
When the microphone having directivity shown in FIG. 6 is used, strong directivity is shown in front of the microphone. In the present embodiment, using such characteristics, the DSP 25 performs a microphone selection process.

When a non-directional microphone is used instead of a directional microphone as in the present invention, since all sounds around the microphone are collected, the S / N between the voice of the speaker and the ambient noise is confused. Good sound cannot be collected. In order to avoid this, in the present invention, S / N with surrounding noise is improved by collecting sound with one directional microphone.
A microphone array using a plurality of omnidirectional microphones can be used as a method for obtaining the directivity of a microphone. However, in such a method, complicated processing is performed due to matching of time axes (phases) of a plurality of signals. Therefore, it takes time, and the responsiveness is low and the apparatus configuration is complicated. That is, the DSP signal processing system also requires complicated signal processing. The present invention solves such a problem by using the directional microphone illustrated in FIG.
In order to synthesize a microphone array signal and use it as a directional sound pickup microphone, there is a disadvantage that the outer shape is restricted by the pass frequency characteristic and the outer shape becomes large. The present invention also solves this problem.

Effects of the device configuration of the communication device The communication device configured as described above exhibits the following advantages.
(1) Since the positional relationship between the even number of microphones MC1 to MC6 radially arranged at equal angles and at equal intervals and the reception / reproduction speaker 16 is constant and the distance is very close, the reception / reproduction speaker 16 The level at which the output sound returns directly to the microphones MC1 to MC6 via the conference room (room) environment is overwhelmingly dominant. Therefore, the characteristics (signal level (intensity), frequency characteristics (f characteristic), phase) that the sound reaches from the speaker 16 to the microphones MC1 to MC6 are always the same. In other words, the communication device 1 according to the embodiment of the present invention has an advantage that the transfer function is always the same.
(2) Therefore, there is no change in the transfer function when the output of the microphone sent to the other party's conference room is switched when the speakers are different, and there is no need to adjust the gain of the microphone system each time the microphone is switched. Have advantages. In other words, there is an advantage that once the adjustment is made at the time of manufacturing the telephone device, there is no need to redo the adjustment.
(3) Even if the microphones are switched when the speakers are different for the same reason as described above, only one echo canceller (DSP 26) is required. The DSP is expensive, and it is not necessary to arrange a plurality of DSPs on the printed circuit board 21 on which various members are mounted and the space is small, and the space for arranging the DSPs on the printed circuit board 21 may be small. As a result, the printed circuit board 21, and thus the communication device of the present invention can be reduced in size.
(4) Since the transfer function between the reception / reproduction speaker 16 and the microphones MC1 to MC6 is constant as described above, for example, the advantage that the sensitivity difference of the microphone itself having ± 3 dB can be adjusted by the microphone unit alone of the communication device. There is. Details of the sensitivity difference adjustment will be described later.
(5) The table on which the communication device 1 is mounted is usually a round table or a polygonal table, but the voice of equal quality is centered on the axis C by one receiving / reproducing speaker 16 in the communication device 1. As a result, a speaker system that is evenly distributed (split) in all directions of 360 degrees can be realized.
(6) The sound emitted from the receiving / reproducing speaker 16 is transmitted to the table surface of the round table (boundary effect), effectively and efficiently delivering high-quality sound to the conference participants, and facing the ceiling direction of the conference room There is an advantage that the sound and phase on the side are canceled and become a small sound, and there are few reflected sounds from the ceiling direction to the conference participants, and as a result, a clear sound is distributed to the participants.
(7) Since the sound emitted from the reception / reproduction speaker 16 reaches all the microphones MC1 to MC6 arranged radially and at equal intervals at the same angle at the same volume at the same time, it is determined whether the sound is the voice of the speaker or the received voice. It becomes easy. As a result, erroneous determination of microphone selection processing is reduced. Details thereof will be described later.
(8) Level comparison for detecting the direction of a sound source, for example, a speaker, by arranging an even number, for example, six microphones at equal angles radially and at equal intervals and a pair of opposing microphones arranged in a straight line Can be easily done.
(9) By the damper 18, the microphone support member 22, and the like, it is possible to reduce the influence of the vibration due to the sound of the reception and reproduction speaker 16 on the sound collection of the microphones MC1 to MC6.
(10) As illustrated in FIG. 3, structurally, the sound of the reception / reproduction speaker 16 is hardly transmitted directly to the microphones MC1 to MC6. Therefore, the communication device 1 is less affected by noise from the receiving / reproducing speaker 16.

The communication device 1 described with reference to FIGS. 2 to 3 has the reception reproduction speaker 16 disposed in the lower portion and the microphones MC1 to MC6 (and related electronic circuits) disposed in the upper portion. The positions of 16 and microphones MC1-MC6 (and related electronic circuits) can also be turned upside down as illustrated in FIG. Even in such a case, the above-described effects are exhibited.

  The number of microphones is not limited to 6, and any number of microphones, such as four, eight, etc., may be arranged in a straight line (in the same direction) in a plurality of pairs, radially and equidistantly from the axis C as a base point. The microphones MC1 and MC4 are arranged in a straight line. The reason why the two microphones, for example, MC1 and MC4 are arranged in a straight line facing each other is to easily and accurately specify the speaker.

Signal Processing Contents Hereinafter, processing contents mainly performed by the first digital signal processor (DSP) 25 will be described.
FIG. 9 is a diagram illustrating an outline of processing performed by the DSP 25. The outline is described below.

(1) Measurement of ambient noise As an initial operation, preferably, ambient noise where the two-way communication device 1 is installed is measured.
The communication device 1 can be used in various environments (conference rooms). In order to increase the accuracy of selection of the microphone and improve the performance of the communication device 1, in the present invention, in the initial stage, noise in the surrounding environment where the communication device 1 is installed is measured, and the influence of the noise is measured by the microphone. It is possible to exclude from the collected signal.
Of course, when the communication device 1 is repeatedly used in the same conference room, noise measurement is performed in advance, and this process can be omitted when the noise state does not change. Note that noise measurement can also be performed in a normal state.
Details of the noise measurement will be described later.

(2) Selection of Chairperson For example, when the communication device 1 is used for a two-way conference, it is beneficial to have a chairperson who manages the proceedings in each conference room. Therefore, as one aspect of the present invention, the chairperson is set from the operation unit 15 of the call device 1 in the initial stage of using the call device 1. As a chairperson setting method, for example, the first microphone MC1 located in the vicinity of the operation unit 15 is used as a chairperson microphone. Of course, the chairman's microphone can be arbitrary.
Note that this process can be omitted when the chairperson who repeatedly uses the communication device 1 is the same. Or you may decide the microphone of the position where a chairperson sits beforehand. In that case, there is no need to select a chairman each time.
Of course, the selection of the chair is not limited to the initial state, and can be performed at any timing.
Details of the chairperson selection will be described later.

(3) Microphone sensitivity difference adjustment As an initial operation, preferably, the gain or attenuation unit of the amplification unit that amplifies the signals of the microphones MC1 to MC6 so that the acoustic coupling between the reception reproduction speaker 16 and the microphones MC1 to MC6 is equal. Automatically adjust the attenuation value.
The sensitivity difference adjustment will be described later.

Various processes exemplified below are performed as normal processes.
(3) Microphone selection / switching process When a plurality of conference participants make a call at the same time in one conference room, audio is mixed and difficult for the conference participants A1 to A6 in the other conference room. Therefore, in the present invention, in principle, one person is allowed to talk at a time. For this reason, the DSP 25 performs speaker identification and microphone selection / switching processing that permits a call.
As a result, only the call from the selected microphone is transmitted to the call device 1 in the other party's conference room via the telephone line 920 and output from the speaker. Of course, as described with reference to FIG. 5, the LED in the vicinity of the selected speaker's microphone is turned on, and the selected speaker's voice is also heard from the speaker of the communication device 1 in the room. And recognize who is the authorized speaker.
By this processing, a signal of a unidirectional microphone facing the speaker can be selected, and a signal having a good S / N can be sent to the other party as a transmission signal.
(4) Display of selected microphone A microphone is selected so that all the conference participants A1 to A6 can easily recognize which microphone of the conference participant is selected and allowed to speak. The selection result display means 30, for example, the corresponding one of the light emitting diodes LED1 to LED6 is turned on.
(5) As a background art of the microphone selection process described above, or in order to accurately perform the microphone selection process, various signal processes exemplified below are performed.
(A) Band separation and level conversion processing of microphone collected signal (b) Start / end determination processing of speech
To be used as a trigger to start selecting the microphone signal that faces the speaker direction.
(C) Speaker direction microphone detection processing
To analyze the collected sound signal of each microphone and determine the microphone used by the speaker.
(D) Speaker direction microphone switching timing determination processing, and microphone signal selection switching processing facing the detected speaker
An instruction to switch to the microphone selected from the above processing result is given. (E) Measurement of floor noise during normal operation

Measurement of floor (environment) noise This process is divided into an initial process and a normal process immediately after the two-way communication device is turned on. This process is performed under the following exemplary preconditions.

[Table 1]
(1) Conditions: Measurement time and threshold provisional value:
1. Test tone sound pressure: -40dB at microphone signal level
2. 2. Noise measurement unit time: 10 seconds Noise measurement under normal conditions: The average value is calculated from the measurement results for 10 seconds, and this is repeated 10 times to obtain the average value to obtain the noise level.

[Table 2]
(2) Estimated effective distance and threshold based on the difference between floor noise and speech start reference level 1.26 dB or more: 3 meters or more
Detection level threshold for starting speech: Floor noise level +9 dB
Talk level detection level threshold: floor noise level + 6 dB
2.20 to 26 dB: within 3 meters
Detection level threshold for starting speech: Floor noise level +9 dB
Talk level detection level threshold: floor noise level + 6 dB
3.14 to 20 dB: within 1.5 meters
Detection level threshold for starting speech: Floor noise level +9 dB
Talk level detection level threshold: floor noise level + 6 dB
4.9-14dB: within 1 meter
Detection level threshold for starting speech:
Difference between floor noise level and speech start reference level ÷ 2 + 2 dB
Talk end threshold: Talk start threshold-3 dB
5.9 dB or less: a little tight, tens of centimeters
Detection level threshold for starting speech:
6). Difference between floor noise level and speech start reference level ÷ 2
Talk end detection level threshold: -3 dB
7). Same or negative: Cannot be judged and cannot be selected

[Table 3]
(3) The noise measurement start threshold value of the normal process starts when the level becomes lower than the floor noise at the time of power-on + 3 dB.

Immediately after the communication device 1 is turned on, the DSP 25 performs the following noise measurement described with reference to FIGS.
The initial processing of the DSP 25 immediately after power-on of the communication device 1 is to measure the floor noise and the reference signal level, and based on the difference between them, the guideline of the effective distance between the speaker and the system and the setting of the threshold value for starting and ending the speech. To do.
The level value peak-held by the sound pressure level detection unit in the DSP 25 is read at a constant time interval, for example, 10 mSec, and an average value of unit time values is calculated and used as floor noise. Then, the DSP 25 determines a threshold value for a speech start detection level and a speech end detection level based on the measured floor noise level.

FIG. 10, Process 1: Test Level Measurement The DSP 25 outputs a test tone to the line-in terminal of the reception signal system illustrated in FIG. 5 according to the process illustrated in FIG. The sound is collected at ~ MC6, and the average value is obtained using the signal as a speech start reference level.

FIG. 11, Process 2: Noise measurement 1
In accordance with the process illustrated in FIG. 11, the DSP 25 collects the level of the collected sound signal from each of the microphones MC1 to MC6 as a floor noise level for a certain period of time, and obtains an average value.

FIG. 12, Process 3: Estimated Effective Distance The DSP 25 compares the speech start reference level with the floor noise level according to the process illustrated in FIG. 12, and estimates the noise level of a room such as a conference room in which the communication device 1 is installed. Then, the effective distance between the speaker who works well in the communication device 1 and the communication device 1 is calculated.

If the floor noise is larger (higher) than the speech start reference level as a result of the processing 3, the DSP 25 determines that there is a strong noise source in the direction of the microphone, and the microphone in that direction is automatically The selection is set to be prohibited, and is displayed on the microphone selection result display means 30 or the operation unit 15, for example.

As illustrated in FIG. 13, the threshold value determination DSP 25 compares the speech start reference level and the floor noise level, and determines the threshold values of the speech start and end levels from the difference.

  As far as noise measurement is concerned, the next process is a normal process, so the DSP 25 sets each timer (counter) and prepares for the next process.

The normal noise processing DSP 25 performs noise processing according to the processing shown in FIG. 14 in the normal operation state even after the noise measurement during the initial operation of the communication device 1, and is selected for each of the six microphones MC1 to MC6. The average sound volume level of the speaker and the noise level after detection of the end of the speech are measured, and the speech start / end determination threshold level is reset in a fixed time unit.

FIG. 14, Process 1 : The DSP 25 determines branching to Process 2 or Process 3 based on the determination of whether the speech is in progress or the end of speech.

FIG. 14, Process 2 : Speaker Level Measurement The DSP 25 averages and records the level data for a unit time, for example, 10 seconds, for a plurality of times, for example, 10 times, as a speaker level.
If the utterance ends within the unit time, the time measurement and the utterance level measurement are stopped until a new utterance starts, and the measurement process is resumed after the new utterance is detected.

FIG. 14, Process 3 : Floor noise measurement 2
The DSP 25 averages the noise level data for a unit time, for example, 10 seconds from the detection of the end of the speech to the start of the speech, and records the average as a floor noise level a plurality of times, for example, 10 times.
If there is a new message within the unit time, the DSP 25 stops the time measurement and noise measurement on the way, and restarts the measurement process after detecting the end of the new message.

FIG. 14, Process 4 : Threshold Determination 2
The DSP 25 compares the speech level and the floor noise level, and determines the threshold value for the speech start and end levels from the difference.
In addition, since the average value of the speaking level of the speaker is obtained as an application, it is also possible to set a speech start and end detection threshold level specific to the speaking party facing the microphone.

Generation of Various Frequency Component Signals by Filter Processing FIG. 15 is a configuration diagram showing filtering processing performed by the DSP 25 using sound signals collected by a microphone as preprocessing. FIG. 15 shows processing for one microphone (channel (one sound collection signal)).
The collected sound signal of each microphone is processed by an analog low cut filter 101 having a cutoff frequency of 100 Hz, for example, and a filtered audio signal from which a frequency of 100 Hz or less has been removed is output to the A / D converter 102. , Digital high-cut filters 103a to 103e (collectively referred to as “collection signals”) having cut-off frequencies of 7.5 KHz, 4 KHz, 1.5 KHz, 600 Hz, and 250 Hz, respectively. 103), high frequency components are removed (high cut processing). The results of the digital high cut filters 103a to 103e are further subtracted for each filter signal of the adjacent digital high cut filters 103a to 103e in subtractors 104a to 104d (collectively 104).
In the embodiment of the present invention, the digital high cut filters 103a to 103e and the subtractors 104a to 104d are actually processed in the DSP 25. The A / D converter 102 can be realized as one of the A / D converter blocks 27.

  FIG. 16 is a frequency characteristic diagram showing the filter processing result described with reference to FIG. Thus, a plurality of signals having various frequency components are generated from a signal collected by a microphone having one directivity.

The start / end of speech is determined as one of the triggers for starting the band-pass filter processing and microphone signal level conversion processing microphone selection processing. A signal used for this purpose is obtained by the bandpass filter processing and level conversion processing illustrated in FIG. FIG. 17 shows only 1CH during processing of 6-channel (CH) input signals collected by microphones MC1 to MC6.
The band-pass filter processing and level conversion processing unit in the DSP 25 respectively collects the collected sound signals of the microphones of each channel at 100 to 600 Hz, 200 to 250 Hz, 250 to 600 Hz, 600 to 1500 Hz, 1500 to 4000 Hz, 4000 to 7500 Hz. Band-pass filters 201a to 201a having band-pass characteristics (collectively, band-pass filter block 201), original microphone sound collection signals, and level converters 202a to 202g for level-converting the band-pass sound collection signals ( Collectively, it has a level conversion block 202).

  Each level conversion unit 202 a to 202 g includes a signal absolute value processing unit 203 and a peak hold processing unit 204. Therefore, as illustrated in the waveform, the signal absolute value processing unit 203 inverts the sign and converts it to a positive signal when a negative signal indicated by a broken line is input. The peak hold processing unit 204 holds the maximum value of the output signal of the signal absolute value processing unit 203. However, in the present embodiment, the held maximum value is somewhat lowered with the passage of time. Of course, the peak hold processing unit 204 can be improved so that the maximum value can be held for a long time by reducing the decrease.

A bandpass filter will be described. The band-pass filter used for the communication device 1 is composed of, for example, a secondary IIR high-cut filter and a microphone signal input stage low-cut filter only.
In the present embodiment, it is utilized that if the signal that has passed through the high-cut filter is subtracted from the signal having a flat frequency characteristic, the rest is substantially equivalent to the signal that has passed through the low-cut filter.
In order to match the frequency-level characteristics, an extra band-pass bandpass filter is required for one band, but the band required by the number of filter stages equal to the number of bands of the required bandpass filter + 1 and the filter coefficient A pass is obtained. The band frequency of the hand pass filter required this time is the following 6 band pass filter per channel (CH) of the microphone signal.

[Table 4]
BP characteristic band pass filter
BPF1 = [100Hz-250Hz] ・ ・ 201b
BPF2 = [250Hz-600Hz] ・ ・ 201c
BPF3 = [600Hz-1.5KHz] ・ ・ 201d
BPF4 = [1.5KHz-4KHz] ・ ・ 201e
BPF5 = [4KHz-7.5KHz] ・ ・ 201f
BPF6 = [100Hz-600Hz] ・ ・ 201a

In this method, the calculation program of the above IIR filter in the DSP 25 is only 6CH (channel) × 5 (IIR filter) = 30.
Contrast with the conventional bandpass filter configuration. Assuming that the band-pass filter uses a second-order IIR filter and a 6-band band-pass filter is prepared for each of six microphone signals as in the present invention, in the conventional method, 6 × 6 × 2 = 72. Circuit IIR / filtering is required. This processing requires considerable program processing even with the latest excellent DSP, and affects other processing.
In the embodiment of the present invention, the 100 Hz low cut filter is processed by an analog filter in the input stage. There are five types of cutoff frequencies of the prepared second-order IIR high cut filters: 250 Hz, 600 Hz, 1.5 KHz, 4 KHz, and 7.5 KHz. Of these, a high-cut filter with a cutoff frequency of 7.5 KHz is not necessary because the sampling frequency is actually 16 KHz. In order to reduce the phenomenon, the phase of the reduced number is intentionally rotated.

  FIG. 18 is a flowchart when processing by the DSP 25 is performed according to the configuration illustrated in FIG.

  In the DSP 25 illustrated in FIG. 18, a high-pass filter process is performed as the first stage process, and a subtraction process from the result of the first-stage high-pass filter process is performed as the second stage process. FIG. 16 is an image frequency characteristic diagram of the signal processing result. [X] below shows each processing case in FIG.

First stage [1] The input signal is passed through a 7.5 kHz high cut filter for the whole band pass filter. This filter output signal becomes a bandpass filter output of [100Hz-7.5KHz] by matching the analog low cut of the input.

  [2] Pass the input signal through a 4KHz high cut filter. This filter output signal becomes a [100Hz-4KHz] depass filter output in combination with the input analog low cut filter.

  [3] Pass the input signal through a 1.5 kHz high cut filter. This filter output signal is combined with the input analog low cut filter [100Hz-1.5KHz] is combined with the input analog low cut filter [100Hz-1.5KHz] When combined with the input analog low cut filter [100Hz -1.5KHz] bandpass filter output.

  [4] Pass the input signal through a 600 kHz high cut filter. This filter output signal becomes a bandpass filter output of [100Hz-600Hz] by combining with the input analog low cut filter.

  [5] The input signal is passed through a 250 kHz high cut filter. This filter output signal becomes a bandpass filter output of [100Hz-250Hz] by combining with the input analog low cut filter.

The second stage [1] band pass filter (BPF5 = [4KHz ~ 7.5KHz]) executes the process of filter output [1]-[2] ([100Hz ~ 7.5KHz]-[100Hz ~ 4KHz]) The signal output is [4KHz to 7.5KHz].
[2] The bandpass filter (BPF4 = [1.5KHz to 4KHz]) will perform the above processing when the filter output [2]-[3] ([100Hz to 4KHz]-[100Hz to 1.5KHz]) is executed. Output [1.5KHz ~ 4KHz].
[3] The bandpass filter (BPF3 = [600Hz to 1.5KHz]) performs the above processing when the filter output [3]-[4] ([100Hz to 1.5KHz]-[100Hz to 600Hz]) is executed. Output [600Hz ~ 1.5KHz].
[4] The bandpass filter (BPF2 = [250Hz to 600Hz]) performs the process of filter output [4]-[5] ([100Hz to 600Hz]-[100Hz to 250Hz]). ~ 600Hz]. [5] The bandpass filter (BPF1 = [100 Hz to 250 Hz]) uses the signal [5] as it is as the output signal [5].
[6] The bandpass filter (BPF6 = [100 Hz to 600 Hz]) uses the signal [4] as it is and outputs it as the output signal (4).
The bandpass filter output required by the above processing in the DSP 25 is obtained.

  The input microphone sound collection signals MIC1 to MIC6 are constantly updated in the DSP 25 as the sound pressure level of the entire band and the sound pressure level of the six bands that have passed through the bandpass filter as shown in Table 5.

In Table 5, for example, L1-1 indicates a peak level when the collected sound signal of the microphone MC1 passes through the first bandpass filter 201a.
The start and end of speech is determined by using a microphone sound collection signal that has passed through the 100 Hz to 600 Hz bandpass filter 201a shown in FIG.

  The conventional band-pass filter is configured by combining a high-pass filter and a low-pass filter for each stage of the band-pass filter. Therefore, a 36-band band-pass filter based on the specifications used in this embodiment is used. Constructing 72 requires filtering processing of 72 circuits. In contrast, the filter configuration of the embodiment of the present invention is simplified as described above.

Start and end determination process first digital signal processor (DSP 1) 25 remarks, based on the value output from the sound pressure level detector, as illustrated in FIG. 19, the microphone sound pickup signal level than the floor noise If it rises and exceeds the threshold of the speech start level, it is determined that the speech starts.If the level continues to be higher than the threshold of the start level, the floor noise is determined if the level is lower than the threshold of speech end during speech. The speech end determination time is determined, for example, when it is continued for 0.5 seconds, the speech end is determined.
The start and end of speech is determined by sound pressure level data (microphone signal level (1)) that has passed through a band pass filter of 100 Hz to 600 Hz that has been subjected to sound pressure level conversion by the microphone signal conversion processor 202b illustrated in FIG. It is determined that the utterance has started when the threshold level illustrated in FIG. 19 is reached.
In order to avoid malfunction due to frequent microphone switching, the DSP 25 does not detect the start of the next speech after the speech start determination time, for example, 0.5 seconds, after detecting the speech start.

The microphone selection DSP 25 performs speaker direction detection and automatic selection of a microphone signal facing the speaker in the mutual communication system based on a so-called “star chart method”.
FIG. 20 is a graph illustrating the operation mode of the communication device 1.
FIG. 21 is a flowchart showing normal processing of the communication device 1.

As illustrated in FIG. 20, the communication device 1 performs voice signal monitoring processing in accordance with the collected sound signals from the microphones MC1 to MC6, performs speech start / end determination, performs speech direction determination, performs microphone selection, The result is displayed on the microphone selection result display means 30, for example, the light emitting diodes LED1 to LED6.
The operation will be described below with the DSP 25 in the call device 1 as a main component with reference to the flowchart of FIG. The overall control of the microphone / electronic circuit housing unit 2 is performed by the microprocessor 23, and the processing of the DSP 25 will be mainly described.

Step 1: Level conversion signal monitoring The signals collected by the microphones MC1 to MC6 are respectively obtained in the band-pass filter block 201 and the level conversion block 202 described with reference to FIGS. Therefore, the DSP 25 constantly monitors seven types of signals for each microphone sound collection signal.
Based on the monitoring result, the DSP 25 proceeds to any one of the speaker direction detection processing 1, the speaker direction detection processing 2, and the speech start / end determination processing.

Step 2: Speech Start / End Determination Processing The DSP 25 determines the start and end of speech according to the method described in detail below with reference to FIG. When the DSP 25 detects the start of speech, the DSP 25 informs the speaker direction determination processing in step 4 of the start of speech.
When the speech start / end determination process in step 2 is performed, when the speech level becomes lower than the speech end level, a speech end determination time (for example, 0.5 second) timer is activated and the speech end determination time and the speech level are When it is less than the end level, it is determined that the speech has ended.
If it becomes larger than the speech end level within the speech end determination time, it waits until it becomes smaller than the speech end level again.

Step 3: Speaker Direction Detection Processing The speaker direction detection processing in the DSP 25 is continuously performed by continuously searching for the speaker direction. Thereafter, the data is supplied to the speaker direction determination processing in step 4.

Step 4: Speaker direction microphone switching processing The timing determination processing in the speaker direction microphone switching processing in the DSP 25 has been selected from the results of Step 2 and Step 3 and the current speaker detection direction. If the speaker direction is different, the microphone selection in step 4 is instructed to select a microphone in a new speaker direction.
However, if the chairman's microphone is set from the operation unit 15 and the chairman's microphone and another conference participant speak at the same time, the chairman's comment is given priority.
At this time, the selected microphone information is displayed on the microphone selection result display means 30, for example, the light emitting diodes LED1 to LED6.

Step 5: Transmission of microphone sound collecting signal In the microphone signal switching process, only the microphone signal selected by the process of Step 4 from the six microphone signals is used as the transmission signal, and the other party side from the communication device 1 through the telephone line 920. Is transmitted to the line-out of the telephone line 920 illustrated in FIG.

Setting the speech start level threshold and speech end threshold
Process 1 : Immediately after turning on the power, the floor noise for a predetermined time, for example, 1 second of each microphone is measured.
The DSP 25 reads the peak-held level value of the sound pressure level detection unit at regular time intervals, for example, 10 mSec intervals in the present embodiment, and calculates an average value of values for a predetermined time, for example, 1 minute, to calculate floor noise. And
The DSP 25 determines a speech start detection level (floor noise +9 dB) and a speech end detection level threshold (floor noise +6 dB) based on the measured floor noise level. After that, the DSP 25 reads the peak-held level value of the sound pressure level detector at regular time intervals.
When it is determined that the speech has ended, the DSP 25 functions as a floor noise measurement, detects the start of speech, and updates the threshold for the detection level of speech end.

  According to this method, since the floor noise level at the position where the microphone is placed is different in this threshold setting, a threshold can be set for each microphone, and erroneous determination in selection of the microphone by the noise source can be prevented.

Process 2 : Response to ambient noise (large floor noise) room Process 2 performs the following as a countermeasure when it is difficult to detect the start and end of speech when the floor level is high in Process 1 and the threshold level is automatically updated. .
The DSP 25 determines a threshold for the detection level of the speech start and the detection level of the speech end based on the predicted floor noise level.
The DSP 25 sets the speech start threshold level to be greater than the speech end threshold level (for example, a difference of 3 dB or more).
The DSP 25 reads the level value peak-held by the sound pressure level detector at regular time intervals.

  According to this method, since the threshold value is the same value for all microphones, the person who is behind the noise source and the person who is not so have the same voice volume and can recognize the start of speech.

Talk start judgment
Process 1 The output level of the sound pressure level detector corresponding to the six microphones is compared with the threshold value of the speech start level.
When the output level of the sound pressure level detector corresponding to all the microphones exceeds the threshold of the speech start level, the DSP 25 determines that the signal is from the reception / reproduction speaker 16 and does not determine that the speech is started. This is because the distance between the reception / reproduction speaker 16 and all the microphones MC1 to MC6 is the same, so that the sound from the reception / reproduction speaker 16 reaches almost all the microphones MC1 to MC6.

Process 2 Two unidirectional microphones (with microphones MC1 and MC1) with the directional axes shifted by 180 degrees in the opposite direction at an equal angle of 60 degrees with respect to the six microphones illustrated in FIG. Three sets of MC4, microphones MC2 and MC5, and microphones MC3 and MC6) are used, and the level difference between the two microphone signals is used. That is, the following calculation is performed.

[Table 6]
Absolute value of (the signal level of microphone 1−the signal level of microphone 4) [1]
Absolute value of (signal level of microphone 2−signal level of microphone 5) [2]
Absolute value of (signal level of microphone 3−signal level of microphone 6) [3]

The DSP 25 compares the absolute values [1], [2], and [3] with the threshold value of the speech start level, and determines that the speech is started when the threshold value of the speech start level is exceeded.
In the case of this process, since all the absolute values do not become larger than the threshold value of the speech start level as in process 1 (because the sound from the reception / reproduction speaker 16 reaches all the microphones equally), the reception / reproduction speaker 16 It is not necessary to determine whether the sound is from the speaker or from the speaker.

Speaker Direction Detection Processing For detecting the speaker direction, the characteristics of the unidirectional microphone illustrated in FIG. 6 are used. As illustrated in FIG. 6, the frequency characteristics and level characteristics of the unidirectional microphone change depending on the sound arrival angle from the speaker to the microphone. The results are illustrated in FIGS. 7 (A) to (C). 7A to 7C show a case where a speaker is placed at a predetermined distance from the communication device 1, for example, a distance of 1.5 meters, and the sound collected by each microphone is subjected to fast Fourier transform (FFT) at regular time intervals. Results are shown. The X axis represents frequency, the Y axis represents signal level, and the Z axis represents time. The horizontal line represents the cut-off frequency of the band-pass filter, and the level of the frequency band sandwiched between the lines is the 5-band band pass from the microphone signal level conversion processing described with reference to FIGS. -It becomes the data converted into the sound pressure level that passed through the filter.

A determination method applied as an actual process for detecting a speaker direction in the communication device 1 as an embodiment of the present invention will be described.
Appropriate weighting processing is performed on the output level of each band-pass filter (0 for 1 dB full span (1 dBFs) step, 0 for 0 dBFs, 3 for -3 dBFs, or vice versa). This weighting step determines the processing resolution.
The above weighting process is executed for each sample clock, and the weighted score of each microphone is added and averaged with a fixed number of samples, and the microphone signal having a small (large) total score is determined as a microphone facing the speaker. To do. Table 7 below is an image of this result.

In this example illustrated in Table 7, since the smallest total point is the first microphone MC1, the DSP 25 determines that there is a sound source in the direction of the first microphone MC1 (there is a speaker). The DSP 25 holds the result in the form of a sound source direction microphone number.
As described above, the DSP 25 performs weighting on the output level of the bandpass filter in the frequency band for each microphone, and ranks the microphone signals in the order of smaller (or larger) scores of the output of each bandbandpass filter. The microphone signal having the first rank in three or more bands is determined as the microphone facing the speaker. Then, the DSP 25 creates a score table as shown in Table 8 below, assuming that a sound source is present in the direction of the first microphone MC1 (there is a speaker).

  Actually, the performance of the first microphone MC1 is not necessarily the best in the output of all bandpass filters due to the reflection of sound and the influence of standing waves depending on the characteristics of the room, but the majority in the 5 bands If it is first, it can be determined that a sound source is present in the direction of the first microphone MC1 (there is a speaker). The DSP 25 holds the result in the form of a sound source direction microphone number.

  The DSP 25 sums the output level data of each band band pass filter of each microphone in the form shown in Table 9 below, determines that the microphone signal having a high level is the microphone facing the speaker, and determines the result as the sound source direction microphone number. Hold in the form of.

[Table 9]
MIC1 Level = L1-1 + L1-2 + L1-3 + L1-4 + L1-5
MIC2 Level = L2-1 + L2-2 + L2-3 + L2-4 + L2-5
MIC3 Level = L3-1 + L3-2 + L3-3 + L3-4 + L3-5
MIC4 Level = L4-1 + L4-2 + L4-3 + L4-4 + L4-5
MIC5 Level = L5-1 + L5-2 + L5-3 + L5-4 + L5-5
MIC6 Level = L6-1 + L6-2 + L6-3 + L6-4 + L6-5

Talker direction microphone switching timing determination processing When activated by the speech start determination result of step 2 in FIG. 21 and when a new speaker microphone is detected from the speaker direction detection processing result of step 3 and past selection information, The DSP 25 issues a microphone signal switching command to the microphone signal selection switching process in step 5, and notifies the microphone selection result display means 30 (light emitting diodes LED1 to 6) that the speaker microphone has been switched. Informs the telephone device 1 that it has responded to its remarks.

In order to eliminate the influence of reflected sound and standing waves in a room with high reverberation, the DSP 25 prohibits the activation of a new microphone selection command unless the speech end determination time (for example, 0.5 seconds) elapses after the microphone is switched.
In the present embodiment, two microphone selection switching timings are prepared from the result of the microphone signal level conversion process in step 1 in FIG. 21 and the detection process result in the speaker direction in step 3.

First method : When it is possible to clearly determine the start of speech When speech from the direction of the selected microphone has ended and there is a new speech from another direction.
In this case, the DSP 25 starts speaking after all the microphone signal level (1) and the microphone signal level (2) are equal to or lower than the speech end threshold level and more than the speech end determination time (for example, 0.5 seconds). When any microphone signal level (1) is equal to or higher than the speech start threshold level, it is determined that speech has started, and a microphone facing the speaker direction is properly collected based on the information of the microphone number in the sound source direction. The microphone is determined, and the microphone signal selection switching process in step 5 is started.

Second method : When a new louder voice is spoken from another direction while speaking is in progress In this case, the DSP 25 stops speaking from the start of speaking (when the microphone signal level (1) exceeds the threshold level). The determination process starts after the determination time (for example, 0.5 seconds) has elapsed. If it is determined that the sound source direction microphone number from the process 3 is changed and is stable before the end of the speech is detected, the DSP 25 is more than the speaker currently selected for the microphone corresponding to the sound source direction microphone number. It is determined that there is a speaker who is speaking loudly, the sound source direction microphone is determined as a valid sound collecting microphone, and the microphone signal selection switching process in step 5 is started.

The microphone signal selection switching processing DSP 25 facing the detected speaker is activated by the command selected and determined by the command from the speaker direction microphone switching timing determination processing in step 4 of FIG.
The microphone signal selection switching process of the DSP 25 is composed of a 6-circuit multiplier and a 6-input adder as illustrated in FIG. In order to select the microphone signal, the DSP 25 sets the channel gain (channel gain: CH Gain) of the multiplier to which the microphone signal to be selected is connected to [1] and the CH gains of the other multipliers to [0]. By doing so, the selected signal of (microphone signal × [1]) and the processing result of (microphone signal × [0]) are added to the adder, and a desired microphone selection signal is obtained at the output.

  When the channel gain is switched between [1] and [0] as described above, there is a possibility that a click sound is generated due to the level difference of the microphone signal to be switched. Therefore, in the two-way communication device 1, as illustrated in FIG. 23, in order to change the change in CH Gain from [1] to [0] and from [0] to [1], for example, By continuously changing and crossing in a time of 10 milliseconds, the generation of a click sound due to the difference in the level of the microphone signal is avoided.

  Further, by setting the maximum channel gain to other than [1], for example, [0.5], the echo cancellation processing operation in the DSP 25 at the subsequent stage can be adjusted.

As described above, the communication device according to the first embodiment of the present invention is not affected by noise and can be effectively applied to a two-way conference such as a conference.
Of course, the communication device of the present invention is not limited to the conference, but can be applied to various other uses. That is, the communication device according to the first embodiment of the present invention is also suitable for measuring the voltage level of the passband when the group delay characteristics of each passband need not be emphasized. Therefore, for example, a simple spectrum analyzer, a level meter that performs Fast Fourier Transform (FFT) processing (FFT-like), a level detection processing device for checking an equalizer processing result such as a graphic equalizer, a level meter such as a car stereo or a radio cassette It can also be applied to.

The communication device according to the first embodiment of the present invention has the following advantages in terms of structure.
(1) The positional relationship between a plurality of microphones having a single directivity and a reception / reproduction speaker is constant, and furthermore, since the distance is very close, the sound emitted from the reception / reproduction speaker passes through the conference room (room) environment. The level that returns directly to the multiple microphones is overwhelmingly dominant. Therefore, the characteristics (signal level (intensity), frequency characteristics (f characteristic), phase) for sound to reach a plurality of microphones from the receiving / reproducing speaker are always the same. That is, the communication device of the present invention has an advantage that the transfer function is always the same.

  (2) Therefore, there is no change in the transfer function when the microphone is switched, and there is an advantage that it is not necessary to adjust the gain of the microphone system every time the microphone is switched. In other words, there is an advantage that it is not necessary to redo once the adjustment is made at the time of manufacturing the communication device.

  (3) Even if the microphone is switched for the same reason as described above, only one echo canceller configured by a digital signal processor (DSP) may be used. The DSP is expensive, and the space for placing the DSP on a printed circuit board on which various members are mounted and there is little space may be small.

  (4) Since the transfer function between the receiving / reproducing speaker and the plurality of microphones is constant, there is an advantage that the sensitivity difference of the microphone itself having ± 3 dB can be adjusted by the unit alone.

  (4) The table on which the communication device is mounted normally uses a round table, but it is used as a speaker system that uniformly distributes sound of equal quality in all directions with a single reception / reproduction speaker in the communication device. Became possible.

  (5) The sound emitted from the receiving / reproducing speaker is transmitted to the table surface (boundary effect), and the sound is effectively and evenly delivered to the conference participants, and the sound on the opposite side to the ceiling direction of the conference room. The phase is canceled to produce a small sound, and there is an advantage that the conference participant has less reflected sound from the ceiling direction, and as a result, a clear sound is distributed to the participant.

  (6) Since the sound emitted from the reception / reproduction speaker reaches all of the plurality of microphones at the same volume at the same time, it is easy to determine whether the sound is the speaker's voice or the reception voice. As a result, erroneous determination of microphone selection processing is reduced.

  (7) Even number of microphones are arranged at equal angles radially and at equal intervals, so that level comparison for direction detection can be easily performed.

  (8) Microphones are collected by vibration due to the sound of a receiving / reproducing speaker that can be transmitted through a printed circuit board on which the microphone is mounted by means of a damper using a cushioning material, a microphone support member having flexibility or elasticity, and the like. The influence can be reduced.

  (9) The sound of the receiving / reproducing speaker does not directly enter the microphone. Therefore, this call device is less affected by noise from the reception / reproduction speaker.

The communication device according to the first embodiment of the present invention has the following advantages from the viewpoint of signal processing.
(A) A plurality of unidirectional microphones are arranged radially at equal intervals so that the direction of the sound source can be detected, and the microphone signal is switched to collect (collect) sound with good S / N and clear sound. Can be sent to the other party.
(B) Sound from surrounding speakers can be collected with good S / N, and a microphone facing the speaker can be automatically selected.
(C) In the present invention, the signal analysis is simplified by dividing the passing voice frequency band as a microphone selection processing method and comparing the levels of the divided frequency bands.
(D) The microphone signal switching process according to the present invention is realized as a DSP signal process, and a plurality of signals are all cross-fade processed so as not to generate a clicking sound at the time of switching.
(E) A microphone selection result display means such as a light emitting diode or a notification process to the outside can be performed on the microphone selection result. Therefore, for example, it can be used as speaker position information for a television camera.

Second Embodiment A technique for automatically adjusting a sensitivity difference of a microphone will be described as a second embodiment of the microphone / speaker integrated configuration type communication device (call device) of the present invention.

As a method of adjusting the gain of the microphone amplifier, generally, a method of adjusting the gain of the analog amplifier for the microphone to absorb the sensitivity difference between the microphones is assumed. There is a tendency for the coordinator to influence. That is, the adjustment level tends to vary between when the adjuster is near the microphone during adjustment and when the adjuster is away from the microphone. In addition, such a method requires troublesome work such as connection and disconnection between the output signal of the microphone amplifier and the measuring device.
In the second embodiment of the present invention, in order to overcome the above-described problems, the microphone sensitivity difference is automatically adjusted by the method described below.

The adjustment of the sensitivity difference of the microphone according to the second embodiment of the present invention is based on the following concept.
1. The telephone conversation device 1 according to the embodiment of the present invention includes a reception reproduction speaker 16 as illustrated in FIG. Therefore, if the reference signal is lined in, it can be input to the DSP 26 and the DSP 25 via the A / D converter 274. Therefore, the advantage that the sensitivity difference of the microphone can be adjusted without providing a special measuring device is used.
2. The error range of the sensitivity difference can be freely set by the DSP 25 program.
3. Automatic adjustment makes it possible to identify nonstandard microphones and detect poor connections. Similarly, a failure of an amplification unit that amplifies a microphone signal is also detected.

As a precondition , in the second embodiment, as illustrated in FIG. 4, the microphones are even-numbered, for example, six, radially and equally spaced at equal angles, and further equidistant from the reception / reproduction speaker 16. It is arranged.
The positional relationship between the microphones MC1 to MC6 and the reception / reproduction speaker 16 is such that the reception / reproduction speaker 16 is disposed below the microphones MC1 to MC6 as illustrated in FIG. The reception / reproduction speaker 16 may be disposed above the MC1 to MC6.

Apparatus Configuration The apparatus configuration for carrying out the second embodiment is basically the one illustrated in FIG. 5, and the details are as illustrated in FIG.
24, variable gain amplifiers 301 to 306 that perform gain adjustment are actually arranged between the microphones MC1 to MC6 and the A / D converters 271 to 273 in FIG. Alternatively, the A / D converters 271 to 274 in FIG. 5 may be A / D converters 271 to 274 with variable gain amplifiers 301 to 306.
The DSP 25 performs the above-described various processes, but the first to sixth variable attenuation units (ATTs) 2511 to 2516 and the first to sixth level detection units 2521 to 2526 are parts for adjusting the sensitivity difference between the amplifiers 301 to 306. , A level determination / gain control unit 253, and a test signal generation unit 254.
The DSP 26 includes an echo cancellation transmission processing unit 261 and an echo cancellation reception unit 262.

  The variable gain amplifiers 301 to 306 are amplifiers that can change the gain, and the gain adjustment is performed by the level determination / gain control unit 253. However, when the variable gain amplifiers 301 to 306 are built in the A / D converters 271 to 273, the gain cannot be freely adjusted. That is, there is a case where the gain adjustment can be performed freely, and there is a restriction on the control width of the variable gain amplifiers 301 to 306. In the present embodiment, the situation of the variable gain amplifiers 301 to 306 is determined. Process according to.

  The variable attenuation units 2511 to 2516 are also attenuation units that can change the attenuation amount, and the level determination / gain control unit 253 outputs the attenuation coefficient 0.0 to 1.0 by controlling the attenuation amount. Since the variable attenuation units 2511 to 2516 are processed in the DSP 25, the level determination / gain control unit 253 in the same DSP 25 actually controls (adjusts) the attenuation values of the variable attenuation units 2511 to 2516. become.

  Each of the level detection units 2521 to 2526 includes a bandpass filter 252a, an absolute value calculation unit 252b, and a peak level detection / holding unit 252c, which are basically the same as the configuration illustrated in FIG. It is. The operation of the circuit configuration illustrated in FIG. 17 has been described above.

When a test sound is output from the sound level meter or the reception / reproduction speaker 16 in a room (meeting room) of a certain size, it is arranged at an equal interval d from the sound level meter or the reception / reproduction speaker 16 unless there is a reflector or sound absorption object. A substantially equivalent signal arrives at each of the installed microphones MC1 to MC6.
The test sound from the sound level meter or the reception / reproduction speaker 16 collected by the microphones MC1 to MC6 is amplified by the variable gain amplifiers 301 to 306, converted into digital signals by the A / D converters 271 to 273, and stored in the DSP 25. Attenuation is performed in the variable attenuation units 2511 to 2516. The frequency components of a predetermined band pass through the bandpass filter 252a in the level detection units 2521 to 2526, the calculation shown in Table 6 is performed in the absolute value calculation unit 252b, and the maximum value is detected in the peak level detection / holding unit 252c. Being held.
The level determination / gain control unit 253 adjusts the attenuation amount (attenuation coefficient) of the variable attenuation units 2511 to 2516 to adjust the sensitivity difference between the microphones MC1 to MC6.

Design Value of Sensitivity Difference Adjustment Error In the second embodiment, a microphone of ± 3 dB is assumed as a nominal error of microphone sensitivity, for example.
In the second embodiment, the design value of the sensitivity difference adjustment error is targeted within 0.5 dB, for example. In addition, since it changes with the environment where a two-way communication apparatus is installed, about 0.5-1.0 dB is appropriate as an actual sensitivity difference adjustment error, for example.

  The test signal generation unit 254 inputs pink noise of a reference input level (a sufficiently large sound pressure is generated with respect to ambient noise), for example, 20 dB pink noise, to the line input terminal, and outputs the sound from the reception reproduction speaker 16. put out. Alternatively, as indicated by a broken line in FIG. 24, the test signal output from the test signal generation unit 254 can be re-input to the DSP 25 via the echo cancellation transmission processing unit 261.

  The microphone sensitivity difference adjustment method is classified into 1 to 5 in the following cases depending on circuit configuration conditions such as the variable gain amplifiers 301 to 306. In the present embodiment, the process is performed separately.

Case 1 : Since the variable gain amplifiers 301 to 306 are not incorporated in the A / D converters 271 to 273 but are provided as independent amplifiers 301 to 306, the gain of the amplifiers 301 to 306 is determined by the DSP 25 as a level determination When digital control by the gain controller 253 is not possible:
In this case, the level determination / gain control unit 253 adjusts the attenuation values of the variable attenuation units 2511 to 2516. In other words, the variable gain amplifiers 301 to 306 are designed so that the minimum necessary line output level can be obtained when the microphone having the lowest sensitivity is used, and the level determination / gain control unit 253 performs variable attenuation. The attenuation values of the units 2511 to 2516 are adjusted.

The processing of the level determination / gain control unit 253 will be described below with reference to FIG.
Step S201 : The attenuation value of the variable attenuation units 2511 to 2516 is set to 0 dB (1). Further, it waits until the level detection operation of the level detection unit 252 is stabilized.
Step S202 : The average level of each microphone signal whose level has been converted by the level detectors 2521 to 2526 is measured.
Steps S203 to S207 : The attenuation values of the variable attenuation units 2511 to 2516 are changed so that each channel is at the design value level of the sensitivity difference adjustment error with reference to the measured average value. In addition, each channel is repeatedly subjected to a sensitivity difference using the average level of each microphone signal level-converted by the first to sixth level detection units 2521 to 2526 after changing the attenuation value of the variable attenuation units 2511 to 2516. The attenuation values of the variable attenuation units 2511 to 2516 are changed so as to be the design value level of the adjustment error. The accuracy of adjusting the sensitivity difference is determined by the accuracy of tracking the level difference at this time.
As described above, by determining the adjustment range of the attenuation value in advance, it is possible to detect a defective microphone.

Case 2 : When the gains of the variable gain amplifiers 301 to 306 can be digitally controlled for each channel and the control width is a sensitivity difference adjustment error, for example, 0.5 dB or less:
As illustrated in FIG. 26, the level determination / gain control unit 253 performs the following processing for adjusting the gains of the variable gain amplifiers 301 to 306.

Step S211 : The gains of the variable gain amplifiers 301 to 306 are set to initial values. Further, the attenuation value of the variable attenuation units 2511 to 2516 is set to 0 dB (1), and it waits until the level detection in the level detection units 2521 to 2526 is stabilized.
Step S212 : The average value of each microphone whose level is converted by the level detectors 2521 to 2526 is measured.
Steps S213 to 219 : If there is a microphone of the channel whose measurement result falls within the range of ± 0.5 dB, which is the design value of the sensitivity difference adjustment error, the channel adjustment is terminated. Otherwise, the gains of the variable gain amplifiers 301 to 306 of each microphone are changed (adjusted) so as to fall within the design value range of the sensitivity difference adjustment error. In addition, using the average level of each microphone signal level-converted by the level detectors 2521 to 2526 after changing the gains of the variable gain amplifiers 301 to 306, each channel is repeatedly designed for the sensitivity difference adjustment error. The gains of the variable gain amplifiers 301 to 306 are changed so as to reach the level.
In this manner, by determining the gain adjustment range of the variable gain amplifiers 301 to 306 in advance, the variable gain amplifiers 301 to 306 or the microphone failure can be detected.

Case 3 : When the gains of the variable gain amplifiers 301 to 306 can be digitally controlled for each channel and the control width is, for example, 2 dB or more:
As illustrated in FIG. 27, the level determination / gain control unit 253 first performs gain adjustment of the variable gain amplifiers 301 to 306 (steps S231 to S237), and then the attenuation amount of the variable attenuation units 2511 to 2516. Adjustment is performed (steps S238 to S241).

Steps S231 to S238 : Basically, the processing is the same as that in the case 2 described with reference to FIG. 26, and the gains of the variable gain amplifiers 301 to 306 are adjusted.
That is, in step S231, the gains of the variable gain amplifiers 301 to 306 are set to initial values, the attenuation values of the variable attenuation units 2511 to 2516 are set to 0 dB (1), and the level is converted by the level detection units 2521 to 2526. Measure the average value of each microphone. If there is a microphone of a channel whose measurement result falls within a value of ± 0.5 dB, which is the design value of the sensitivity difference adjustment error, the channel adjustment is terminated. Otherwise, the gains of the variable gain amplifiers 301 to 306 are set, and the gains of the remaining variable gain amplifiers 301 to 306 are set so that the average level is a value that is more positive than the design value of the sensitivity difference adjustment error. .

  In the case 3, the control width of the gain adjustment of the variable gain amplifiers 301 to 306 is 2 dB, and the control width as in the case 2 is not 0.5 dB. Therefore, thereafter, the attenuation amount is adjusted by the variable attenuation units 2511 to 2516 by the following processing.

Steps S240 to S243 : Change the attenuation amount of the variable attenuation units 2511 to 2516 of the microphone signal of the channel that does not fall within the design value of the sensitivity difference adjustment error, and wait until the level in the level detection units 2521 to 2526 becomes stable. Capture the level of my signal with a stable level, perform average processing, and iterate until the value falls within the design range of the sensitivity difference adjustment error. The attenuation values of the variable attenuation units 2511 to 2516 are set so as to be within ± 0.5 dB of the design value of the adjustment error.
As described above, by determining the adjustment range of the attenuation value and the gain of the variable gain amplifiers 301 to 306 in advance, it is possible to detect a failure of the variable gain amplifiers 301 to 306 or the microphone.

Case 4 : The variable gain amplifiers 301 to 306 are incorporated in the A / D converters 271 to 273, and the gains of the amplifiers 301 to 306 can actually be digitally controlled only at the same time for two channels, and the control width is adjusted for the sensitivity difference. For errors, for example 0.5 dB or less:
As illustrated in FIGS. 28 and 29, the level determination / gain control unit 253 performs the following processing.

Steps S251 and S271 : The gains of the variable gain amplifiers 301 to 306 are set to initial values, the attenuation values of the variable attenuation units 2511 to 2516 are set to 0 dB (1), and the level detection of the level detection units 2521 to 2526 is stable. Wait until
Steps S252 and S272 : The average value processing of level detection detected by the level detection units 2521 to 2526 is performed.

Hereinafter, as illustrated in FIGS. 28 and 29, the following two adjustment methods are used.
FIG. 28 shows a method in which the gain adjustment of the variable gain amplifiers 301 to 306 is performed first and the attenuation amount of the variable attenuation units 2511 to 2516 is adjusted later (case 4-1). FIG. 29 is illustrated in FIG. Contrary to the above method, the attenuation of the variable attenuators 2511 to 2516 is adjusted first, and the gain of the variable gain amplifiers 301 to 306 is adjusted later (case 4-2).

Case 4-1 : As illustrated in steps S253 to S259 of FIG. 28, the signal levels of the other channels are set to the signal levels of the channels having the low signal levels within the group in which the gains of the variable gain amplifiers 301 to 306 can be set. The gains of the variable gain amplifiers 301 to 306 are adjusted so as to fall within the low channel signal level ± 0.5 dB. Next, as illustrated in steps S261 to S264, the attenuation value of the variable attenuation units 2511 to 2516 is adjusted so that the higher signal level falls within ± 0.5 dB of the design value of the sensitivity difference adjustment error.

Case 4-2 : As illustrated in steps S273 to S277 of FIG. 29, the gains of the variable gain amplifiers 301 to 306 are adjusted so that the average level value of the microphone signal channel falls within ± 0.5 dB of the design value. Next, as illustrated in steps S278 to S282, the signal levels of the channels having a low signal level within the group in which the gains of the variable gain amplifiers 301 to 306 can be set are changed to the signal levels of the low channels, and the signal levels of the low channels are set to ± 0. The gains of the variable gain amplifiers 301 to 306 are adjusted so as to be within 5 dB.

  As described above, it is possible to detect defects of the variable gain amplifiers 301 to 306 or the microphone by previously determining the adjustment ranges of the attenuation values of the variable attenuating units 2511 to 2516 and the gains of the variable gain amplifiers 301 to 306.

Case 5 : The variable gain amplifiers 301 to 306 are incorporated in the A / D converters 271 to 273, and the gains of the amplifiers 301 to 306 can actually be digitally controlled only at the same time for two channels, and the control width is, for example, For 2 dB or less:
As illustrated in FIG. 30, the level determination / gain control unit 253 first adjusts the attenuation amount of the variable attenuation units 2511 to 2516 (S293 to S297), and then adjusts the gain of the variable gain amplifiers 301 to 306. (S298 to S303), and further, the attenuation amount of the variable attenuation units 2511 to 2516 is adjusted (S304 to S308). This will be described in detail below.

Step S291 : The gains of the variable gain amplifiers 301 to 306 are set to the initial values, the attenuation values of the variable attenuation units 2511 to 2516 are set to 0 dB (1), and the standby is performed until the level detection of the level detection units 2521 to 2526 is stabilized. To do.
Step S292 : The average value processing of each microphone signal level-converted by the level detectors 2521 to 2526 is performed.
Steps S293 to S297 : Adjust the attenuation values of the variable attenuators 2511 to 2516 so that the other signal levels are matched with the lowest channel signal level of the microphone channels in the group in which the gains of the variable gain amplifiers 301 to 306 can be set. To do.
Steps S298 to S303 : The gains of the variable gain amplifiers 301 to 306 are adjusted so that the average level value of the microphone signal channel falls within ± 1 dB of the design value of the sensitivity difference adjustment error.
Steps S304 to S308 : The attenuation values of the variable attenuation units 2511 to 2516 are adjusted again so that the microphone signal level becomes ± 0.5 dB of the design value of the sensitivity difference adjustment error.
In this manner, by determining the attenuation value and the gain adjustment range of the variable gain amplifiers 301 to 306 in advance, it is possible to detect a circuit or microphone failure.

  According to the second embodiment, the sensitivity difference between a pair of opposed microphones fixedly connected to a microphone amplifier is automatically adjusted, and a plurality of microphones arranged at equal distances from the reception / reproduction speaker 16 Thus, the gain of the amplifier of the transmitting microphone can be automatically adjusted so that the acoustic coupling between the receiving / reproducing speaker 16 and each of the sound collecting microphones MC1 to MC6 becomes equal.

  In carrying out the present embodiment, no special device is required, and the microphone / speaker integrated configuration type communication device itself may be used. Therefore, the adjustment can be performed in a state where the microphone / speaker integrated configuration type / communication device is provided.

With reference to the third embodiment Figure 31 to 41, it describes a third embodiment of the present invention.
The third embodiment of the present invention automatically corrects the sensitivity difference between a plurality of transmission microphones that are equidistant from the reception speaker in a two-way call system, and transmits the sound so that the acoustic coupling between the speaker and the sound collection microphone becomes equal. A method and apparatus for automatically adjusting the amplifier gain of a microphone digitally.

  In a device that selects and switches between a plurality of microphones MC1 to MC6, such as the communication device 1 according to the embodiment of the present invention, signal level variations due to sensitivity differences among the microphones MC1 to MC6 may be a problem. is there. In such a case, the output volume or gain of the amplifiers of the analog microphones MC1 to MC6 is adjusted to align the output levels of the microphone signals, and the output level is adjusted by adjusting the output level or gain of the analog line amplifier. Is normal.

As such a method, a method of adjusting a gain of an analog microphone amplifier to absorb a microphone sensitivity difference is known. This method is the most common method, but has the disadvantage of being easily influenced by the adjuster, such as reflection and absorption of sound. For example, the level tends to vary between when the adjuster is close during adjustment and when the adjuster is away. Also, complicated operations such as switching the connection between the microphone amplifier output and the measuring instrument are required.
The third embodiment of the present invention improves such a problem.

Conceptual diagram 31 of the third embodiment is a block diagram of a communication device of the third embodiment of the present invention.
As illustrated in FIG. 3 and FIG. 31, a speaker 16 is provided in the communication device according to the embodiment of the present invention. Therefore, if a sound source test signal from a second test signal generator 258 (to be described later) is input to the input terminal LINE-IN of the communication device 1 and processed in the DSP 25 having various signal processing functions, the speaker 16 and each The degree of acoustic coupling with the microphones MC1 to MC6 can be specified, and the degree of acoustic coupling can be adjusted. In particular, the DSP 25 can be used as a test signal generator. By doing so, the acoustic coupling degree between the speaker 16 and the microphones MC1 to MC6 is automatically measured without using a special measuring device such as a test signal generator, a sound measuring instrument, and an analyzer, and a variable gain amplifier. By adjusting 301 to 306, the variable attenuation units 2511 to 2516, etc., there is an advantage that the acoustic coupling degree can be adjusted.
Further, the total gain of the transmission system can be automatically adjusted by the circuit configuration.
Furthermore, the adjustment error can be freely set by a program.

As shown in FIG. 4, six unidirectional microphones are arranged radially at intervals of 60 degrees, and the speaker 16 is located above or below the microphone as illustrated in FIG. 3 or FIG. It is assumed that the distances between the microphones MC1 to MC6 and the speaker 16 are equal.

DSP
The communication device 1 illustrated in FIG. 31 is similar to the communication device 1 illustrated in FIG. 24 in the second embodiment, but the configuration and processing contents of the first digital signal processor (DSP) DSP 25 are different. 31 includes a second level determination / gain control unit 257 and a second test signal generation unit instead of the level determination / gain control unit 253 and the test signal generation unit 254 in the DSP 25 illustrated in FIG. 258. That is, the second level determination / gain control unit 257 performs processing described with reference to FIGS. 33 to 40, and the second test signal generation unit 258 generates a test signal different from the test signal generation unit 254.
As in the embodiment described above, the DSP 25 is provided with switch means for outputting the signals of the selected microphones MC1 to MC6 to LINE OUT. In other words, the second level determination / gain control unit 257 has a function of selecting a microphone signal by the method described above.
Further, the second level determination / gain control unit 257 of the DSP 25 has amplification means for digitally amplifying the signal selected by the switch means, and within the second level determination / gain control unit 257, the D / A The gain of the signal output to LINEOUT via the converter 281 can be adjusted. As such a gain adjustment method, the second level determination / gain control unit 257 performs multiplication.
The level of the signal that is gain-adjusted and output to LINE OUT via the D / A converter 281 is detected by a level detector 391 described later.
Other configurations of the DSP 25, for example, the digital variable attenuation unit 251 and the digital level detection unit 252 are the same as those described with reference to FIG.

A level detector 391 for detecting the output of the level detector output amplifier 291 is added.
The level detector 391 is a peak level detector for signal level measurement, and serves as an automatic adjustment measuring instrument in the present embodiment.
The level detection unit 391 can have, for example, a circuit configuration similar to the circuit configuration of the level detection unit 252 in the DSP 25, such as an absolute value calculation unit and a peak level detector. However, although the level detection unit 252 in the DSP 25 is realized by digital signal processing, the level detection unit 391 is configured by a hardware circuit, but the function is the same as that of the level detection unit 252.
In the level detection unit 391, a band pass filter corresponding to the band pass filter unit 252a may be added before the absolute value calculation unit 252b of the level detection unit 252.

A / D Converter Each of the A / D converters 271 to 274 has a function of inputting a two-microphone signal and converting it into a digital signal, as in the above example.
Further, from the viewpoint of digitally adjusting the gain of the input microphone signal, A / D converters 271 to 274 with digital variable gain are used.

Microphone signal selection method (combination)
Each A / D converter 271 to 274 can receive two microphone signals. Further, since the microphones MC1 to MC6 are equidistant from the speaker 16 and are in the same condition, the two microphone signals input to the A / D converters 271 to 274 can be arbitrarily selected.
From the viewpoints of the first and second embodiments, it is necessary to input microphone pairs that are opposed and arranged in a straight line across the center C of the printed circuit board 21 to the same A / D converter. Also in the present embodiment, such an input method may be used, and this is convenient because it is unnecessary to change the wiring when other uses are considered.
However, if this embodiment is taken into consideration, any combination can be input to each A / D converter without such a restriction. As an example, in the arrangement of the microphones MC1 to MC6 illustrated in FIG. 4, the signals of two adjacent microphones can be input to each A / D converter. Such an example is described below.

[Table 10]
MIC1, MIC2-ADC1
MIC3, MIC4-ADC2
MIC5, MIC6-ADC3

  When a 1-input 1-output type A / D converter is used, the above-described signal combinations are not discussed.

  In FIG. 31, the microphones MC1 to MC6 to A / D converter block 27 are used as the transmission signal input unit B1, the D / A converter 281 to the amplifier 291 are used as the transmission output unit B2, and the D / A converter 282 to the speaker. 16 is the reception output unit B3, and the LINEIN to A / D converter 274 is the reception input unit B4.

The variable attenuation unit 251 is configured such that the attenuation amount can be changed by the second level determination / gain control unit 257.
The gains of the variable gain amplifiers 301 to 306 can also be adjusted by the second level determination / gain control unit 257. In the present embodiment, the case where the gain is automatically adjusted digitally will be described. The digitally adjustable portion of the D converters 271 to 274 is adjusted. Therefore, the variable gain amplifiers 301 to 306 are irrelevant in the present embodiment.

FIG. 32 shows the required signal level diagram.
The gain setting of the receiving system is not subject to automatic adjustment because a measuring instrument is required, and is kept at the design value.
The gain of the design value is set so that the sound pressure level at a point 2 m away from the receiving speaker 16 becomes 70 dB when pink noise of 20 dB is input to the reception input terminal.
What is particularly important in the transmission system gain setting is that the microphone output level of the echo cancellation processing block is -25 dB through the microphone from the speaker 16 under the above conditions with respect to the reception output level of -20 dB of the echo cancellation processing block in the DSP 26. This is to determine the signal level of the transmission system including the microphone selection processing in the DSP 25.

Second test signal generation unit The second test signal generation unit 258 may output a pink noise signal, a white noise signal, or other noise, for example, like the test signal generation unit 254. A signal can also be output.
The sound source test signal generated by the second test signal generator 258 is input to the input terminal LINE IN of the call device 1.

Processing of Second Level Determination / Gain Control Unit The processing performed by the second level determination / gain control unit 257 can be broadly divided into the following three processes as illustrated in FIG.

1. The difference in microphone sensitivity is corrected by the variable attenuation unit 251, S411 to S413.
1.1 S411: Microphone pair sensitivity difference adjustment 1
The sensitivity difference between the microphones connected to the ADC 1 is adjusted.
The size is compared with the masked value of the lower 8 bits of the 16-bit data obtained from the level detector. The attenuation value (ATT value) of the variable attenuation unit 251 is increased in units of 1 step 0x100 (HEX).
Details of the processing are shown in the flowchart of FIG.

1.2 S412: Microphone pair sensitivity difference adjustment 2
The sensitivity difference between the microphones connected to the ADC 2 is adjusted.
The size is compared with a value that masks the lower 8 bits of the 16-bit data obtained from the level detector. The ATT value is increased by 1 step 0x100 (HEX).
Details of the processing are shown in the flowchart of FIG.

1.3 S413: Microphone pair sensitivity difference adjustment 3
The sensitivity difference between the microphones connected to the ADC 3 is adjusted.
The size is compared with a value that masks the lower 8 bits of the 16-bit data obtained from the level detector. The ATT value is increased by 1 step 0x100 (HEX).
Details of the processing are shown in the flowchart of FIG.

The processing illustrated in FIG. 34 to FIG. 36 is performed by the variable attenuators 2511 to 2516 for the higher level signals of the two signals input to the A / D converters 271 to 274 and converted. And lower the level to bring both into a predetermined range.
The reason is that since the A / D converters 271 to 274 adjust the common gain with two inputs and cannot be individually adjusted by the A / D converters 271 to 274, first, the variable attenuators 2511 to 2516 are used. This is to adjust the level of the two inputs to a predetermined range.
If the A / D converters 271 to 274 are 1-input 1-conversion A / D converters 271 to 274, such processing is not necessary.

2. Microphone amplifier gain adjustment, S421 to S412
This is a part for correcting the attenuation amount in the variable attenuation unit 251 in units of two microphones, and adjusts the gain of the microphone amplifier in the A / D converters 271 to 274. The microphone amplifier gain adjustment can be achieved by increasing other microphone amplifier gains so as to match the maximum microphone pair output level of the microphone pair output.
Details of the processing are shown in the flowchart of FIG.

3. Microphone selection unit output level adjustment: S431 to S438
The signal output to the external output terminal LINE OUT where one microphone signal is selected is adjusted.
The second level determination / gain control unit 257 receives the signal obtained by detecting the level of the D / A converter 281 by the level detection unit 391, and adjusts the gain of the output amplifier 291 so as to be equivalent to -25 dB. In order to adjust the gain of the D / A converter 281 or to adjust the gain of the signal after selecting the microphone signal in the DSP 25, a predetermined coefficient is added to the signal output to the selected D / A converter 281. Take a ride.
In order to adjust the gain of the signal after selection of the microphone signal in the DSP 25, a method of multiplying a signal output to the selected D / A converter 281 by a predetermined coefficient can be easily realized digitally.

Adjustable Parts The adjustable parts according to the third embodiment are shown below.
1. Transmission system 1.1 Digital gain of A / D converters 271 to 274
The gain changes simultaneously for two inputs.
1.2 Attenuation of digital variable attenuator 251 1.3 Digital gain of microphone selection signal performed by second level determination / gain controller 257 1.4 Gain of D / A converter 281 Receiving system 2.1 A / D converter 274 connected to echo canceling receiver 262
Gain

That is, the embodiment of the present invention is not limited to the above-described embodiment, and the following adjustment can be appropriately selected and performed. For example, only the variable attenuation sections 2511 to 2516 may be adjusted.
If the A / D converters 271 to 274 are one-input and one-conversion type A / D converters, the level of the two signals in S411 (FIGS. 34 to 36) is not adjusted, The A / D converter or the variable attenuators 2511 to 2516 can be individually adjusted without adjusting the gain every two. Whether to adjust the gain of the A / D converter first or to adjust the attenuation amount of the variable attenuation units 2511 to 2516 first is determined by a predetermined rule. For example, when the level is above a certain level, the attenuation of the variable attenuators 2511 to 2516 is adjusted first, and then the gain of the A / D converter is adjusted. In the opposite case, the gain is increased by the A / D converter. After that, the attenuation amount of the variable attenuation units 2511 to 2516 is adjusted.

  As described above, according to the third embodiment, the digitally adjustable portion of the communication device 1 can be automatically adjusted without using a special measurement device or test signal generator.

Modified Embodiment of Third Embodiment FIG. 41 shows a modified embodiment of the third embodiment illustrated in FIG.
The difference between the configuration of FIG. 41 and the configuration of FIG. 31 is that, in FIG. 31, the echo canceling receiver 262 has one input terminal, whereas in FIG. That is, the number of connections to the input terminal of the unit 262 is increased to two. 41, the output signal from the echo cancellation transmission processing unit 261 is input to the echo cancellation reception unit 262, and echo cancellation is completely performed on the transmission signal, and the influence can be removed. More accurate sensitivity adjustment is possible.

FIG. 1A is a diagram showing an outline of a conference system as an example to which the microphone / speaker integrated configuration type communication device (communication device) of the present invention is applied, and FIG. FIG. 1C is a diagram showing a state where the call device in A) is placed, and FIG. 1C is a diagram showing an arrangement of the call device placed on the table and conference participants. FIG. 2 is a perspective view of the communication device according to the embodiment of the present invention. FIG. 3 is an internal cross-sectional view of the communication device illustrated in FIG. FIG. 4 is a plan view of the microphone / electronic circuit housing portion from which the upper cover of the communication device illustrated in FIG. 1 is removed. FIG. 5 is a diagram showing a connection state of main circuits of the microphone / electronic circuit housing unit, and shows a connection state of connection between the first DSP and the second DSP. FIG. 6 is a characteristic diagram of the microphone illustrated in FIG. 7A to 7D are graphs showing the results of analyzing the directivity of a microphone having the characteristics illustrated in FIG. FIG. 8 is a partial configuration diagram of a modification of the communication device according to the present invention. FIG. 9 is a graph showing an outline of the entire processing contents in the first DSP. FIG. 10 is a flowchart showing a first embodiment of the noise measuring method in the present invention. FIG. 11 is a flowchart showing a second embodiment of the noise measuring method according to the present invention. FIG. 12 is a flowchart showing a third embodiment of the noise measuring method in the present invention. FIG. 13 is a flowchart showing a fourth embodiment of the noise measuring method according to the present invention. FIG. 14 is a flowchart showing a fifth embodiment of the noise measuring method according to the present invention. FIG. 15 is a diagram showing a filtering process in the communication device of the present invention. FIG. 16 is a frequency characteristic diagram showing the processing result of FIG. FIG. 17 is a block diagram showing bandpass filtering processing and level conversion processing according to the present invention. FIG. 18 is a flowchart showing the processing of FIG. FIG. 19 is a graph showing a process for determining the start and end of speech in the communication device of the present invention. FIG. 20 is a graph showing the flow of normal processing in the communication device of the present invention. FIG. 21 is a flowchart showing the flow of normal processing in the communication device of the present invention. FIG. 22 is a block diagram illustrating a microphone switching process in the communication device of the present invention. FIG. 23 is a block diagram illustrating a method of microphone switching processing in the communication device of the present invention. FIG. 24 is a block diagram illustrating a partial configuration of the communication device according to the second embodiment of the present invention. FIG. 25 is a flowchart showing a first processing method according to the second embodiment of the present invention. FIG. 26 is a flowchart showing a second processing method according to the second embodiment of the present invention. FIG. 27 is a flowchart showing a third processing method according to the second embodiment of the present invention. FIG. 28 is a flowchart showing a fourth processing method according to the second embodiment of this invention. FIG. 29 is a flowchart showing a fourth processing method according to the second embodiment of this invention. FIG. 30 is a flowchart showing a fifth processing method according to the second embodiment of the present invention. FIG. 31 is a block diagram illustrating a partial configuration of a communication device according to a third embodiment of the present invention. FIG. 32 is a diagram illustrating conditions in the third embodiment of the present invention. FIG. 33 is a flowchart showing a processing method according to the third embodiment of the present invention. FIG. 34 is a flowchart showing the first details of part of FIG. FIG. 35 is a flowchart showing a second detail of part of FIG. FIG. 36 is a flowchart showing a third detail of part of FIG. FIG. 37 is a flowchart showing a fourth detail of part of FIG. FIG. 38 is a flowchart showing a first detail of part of FIG. FIG. 39 is a flowchart showing a second detail of part of FIG. FIG. 40 is a flowchart showing a third detail of part of FIG. FIG. 41 is a block diagram illustrating a partial configuration of a modification of the communication device according to the third embodiment of the present invention.

Explanation of symbols

1. ・ Microphone / speaker integrated configuration type ・ Communication device (communication device)
11. Top cover
12 .. Sound reflector
12a ... Sound reflecting surface, 12b ... Restriction member fixing part
13. Connection member
14 .. Speaker housing
14a ... Sound reflecting surface, 14b ... Bottom
14c .. upper surface 14b, 14d .. lumen
14e ・ ・ Restraining member lower fixed part
14f..Restraining member penetration
15. Operation part
16. ・ Receiving speaker
17 .. Restraint member
18. ・ Damper 2 ・ ・ Microphone ・ Electronic circuit housing
21 .. Printed circuit board
MC1 ~ MC ・ ・ Microphone
22. Microphone support member
22a .. First microphone support member
22b .. Second microphone support member
23. Microprocessor, 24. Codec
25..First digital signal processor (DSP 1)
301-306 .. Variable gain amplifier
251 .. Variable attenuation part
252 .. Level detector
253 ・ ・ Level judgment ・ Gain controller
254 .. Test signal generator
257 ... Second level judgment / gain control unit
258 .. Second test signal generator
391..Level detector
26 .. Second digital signal processor (DSP2)
261 ・ ・ Echo cancellation transmission processing part
262 ・ ・ Echo cancellation receiver
27..A / D converter block
28 ・ ・ D / A converter block
29 .. Amplifier block
30 .. Microphone selection result display means
LED1 ~ 6 ・ ・ Light emitting diode

Claims (8)

Speakers,
A plurality of microphones arranged at the same distance from the speaker and respectively detecting audio signals ;
An external output terminal;
An input terminal to which a sound source test noise signal is input ;
A gain-adjustable A / D conversion means for inputting a voice signal detected by the microphone and having a function capable of adjusting the gain of the inputted signal, and converting the voice detection signals of the plurality of microphones into digital signals; ,
First level detection means for digitally detecting levels of a plurality of digital conversion signals converted by the A / D conversion means;
Signal selecting means for selecting and outputting one of the plurality of digital audio signals detected by the first level detecting means;
A first echo canceling means provided at a subsequent stage of the signal selecting means for performing an echo canceling process on the selected digital audio signal;
A first analog / digital signal provided at the subsequent stage of the first echo canceling means, which converts the input digital audio signal after the echo cancellation processing into an analog audio signal and outputs the analog audio signal to the external output terminal and the speaker. Conversion means;
Level determination / gain control means for performing level determination and gain adjustment;
A test signal generating means for generating a random power test noise signal and outputting the power test noise signal to the input terminal;
Second echo cancellation means for performing echo cancellation processing on the power supply test noise signal input to the input terminal;
Have
The output of the second echo cancellation means is added to the audio signal detected by each microphone and input to the A / D conversion means capable of gain adjustment.
The level judgment and gain control means, the detection signal of the above plurality of microphones detected by the first level detection means, so that acoustic coupling degree between the speaker and the plurality of microphones is equal, detected by the microphone Digitally adjusting the gain of the A / D conversion means corresponding to the voice signal
Ma Ikurofon speaker unitary construction type, communication apparatus. The microphone / speaker integrated configuration type / communication device further includes second level detection means for detecting the level of the digital audio signal output to the external output terminal,
Upper sharp Bell judgment and gain control means, so that monitoring by entering the audio signal detected by said second level detection means, the level of the digital audio signal outputted to the external output terminal reaches a predetermined level And adjusting the level of the audio signal detected by the first level detection means and output to the external output terminal,
The call device according to claim 1. The microphone loudspeaker integral structure type-call device further includes a digitally adjusted, variable attenuation means the amplitude of the converted signal by the adjustable gain A / D conversion means,
The level determination / gain control means digitally adjusts the gain of the A / D conversion means capable of gain adjustment and / or the attenuation of the variable attenuation means.
The call device according to claim 1 or 2. The plurality of microphones have at least one pair of microphones arranged at equal intervals along an outer periphery of a predetermined circle centered on the speaker placement position, and arranged at positions facing each other with the speaker as a center. ,
The gain-adjustable A / D conversion means converts each pair of opposing two microphone detection signals, and has a gain common to the two signals.
The level determination / gain control means is
Adjusting the attenuation amount of the variable attenuation means so that the sensitivity difference between the pair of two microphone detection signals is within a predetermined range;
Thereafter, two microphones detection signals of a pair of the opposing, so that within a level and a predetermined range of the two microphone detection signal of the pair of other opposite to adjust the gain of the A / D conversion means,
4. A microphone / speaker integrated configuration / communication device according to claim 3. Speakers,
A plurality of microphones arranged at the same distance from the speaker and respectively detecting audio signals ;
An external output terminal;
An input terminal to which a sound source test noise signal is input ;
A / D conversion means for inputting a sound signal detected by the microphone and converting the sound detection signal into a digital signal;
A plurality of digitally adjusted, variable attenuation means the amplitude of the audio signal converted by the A / D conversion means,
First level detection means for digitally detecting levels of a plurality of audio output signals of the variable attenuation means;
Signal selecting means for selecting and outputting one of the plurality of digital audio signals detected by the first level detecting means;
A first echo canceling means provided at a subsequent stage of the signal selecting means for performing an echo canceling process on the selected digital audio signal;
A first analog / digital signal provided at the subsequent stage of the first echo canceling means, which converts the input digital audio signal after the echo cancellation processing into an analog audio signal and outputs the analog audio signal to the external output terminal and the speaker. Conversion means;
Level determination / gain control means for performing level determination and gain adjustment;
A test signal generating means for generating a random power test noise signal and outputting the power test noise signal to the input terminal;
Second echo cancellation means for performing echo cancellation processing on the power supply test noise signal input to the input terminal;
Have
The output of the second echo cancellation means is added to the audio signal detected by each microphone and input to the A / D conversion means capable of gain adjustment.
The level determination / gain control means is
Detection signals of the plurality of microphones, the detection signals of the plurality of microphones detected by the first level detection means, so that acoustic coupling degree between the speaker and the plurality of microphones is equal, detected by the microphone Digitally adjusting the attenuation amount of the variable attenuation means corresponding to the voice signal
Ma Ikurofon speaker unitary construction type, communication apparatus. The microphone / speaker integrated configuration type / communication device further includes second level detection means for detecting the level of the digital audio signal output to the external output terminal,
Upper sharp Bell judgment and gain control means, so that monitoring by entering the audio signal detected by said second level detection means, the level of the digital audio signal outputted to the external output terminal reaches a predetermined level And adjusting the level of the audio signal detected by the first level detection means and output to the external output terminal,
The communication device according to claim 5 . The test signal generating means generates a white noise or pink noise signal as a power test noise signal having no periodicity.
The microphone / speaker integrated configuration type communication device according to any one of claims 1 to 6. The second echo cancellation means receives the power test noise signal from the input terminal and the output signal of the first echo cancellation processing means.
The microphone / speaker integrated configuration type / communication device according to claim 1.

Images