JPH08340590A - Earphone/microphone set - Google Patents

Abstract

PURPOSE: To prevent an echo generated in a talking opposite party when a vibration pickup and a speaker detecting a bone conducted voice signal are contained in a shell inserted into an external auditory miatus. CONSTITUTION: A microphone 31 detecting a sound pressure signal outputted from a speaker 8 and transducing it into an electric signal (c) is provided in a shell 27. A subtractor circuit 34 subtracting the electric signal (c) outputted from the microphone 31 from a transmission signal a3 is inserted to a signal path of the transmission signal a3 outputted from a vibration pickup 7 and amplified. Furthermore, an equalizer circuit 32 correcting the frequency characteristic of the electric signal being an output of the microphone 31 into the frequency characteristic of the transmission signal a3 outputted from the vibration pickup 7 and amplified is inserted to the signal path of the subtractor circuit 34 for the electric signal (c) outputted from the microphone 31.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is an earphone that detects a bone-conducted voice signal in the external auditory meatus of a human ear, outputs it as a transmission signal to the outside, and converts a reception signal input from the outside into a sound pressure signal by a speaker. Regarding microphone device.

[0002]

2. Description of the Related Art For example, a call between a guideman of an aircraft at an airfield and a pilot on board, or a call between a worker at a quarrying site and a site supervisor at an office is performed in an environment in which a guideman or a worker exists. The noise is so loud that I cannot hear it even if I speak it directly.

In such a case, although a telephone call is made using a transceiver or the like, a guidance staff member or a worker in a noisy environment listens to the sound pressure signal of the other party's caller by using earphones. You can In addition, a microphone with high directivity should be brought close to the mouth of the other party.

However, even if the microphone has high directivity, if the ambient noise is very large, the microphone takes in ambient noise together with the sound pressure signal. As a result, it is very difficult for the other party's caller to hear the sound pressure signal from the guidance staff or workers in the noisy environment.

In order to eliminate such inconvenience, when a person produces a voice, the inner wall of the external auditory meatus of the ear vibrates in response to a sound pressure signal. A function that detects a voice signal with a vibration pickup and sends this detection signal to the other party's caller as a transmission signal, and also converts the receiving signal from the other party's party into a sound pressure signal as with normal earphones. An earphone / microphone device having the same is proposed (Japanese Patent Laid-Open No. 4-172794).

FIG. 6 is a schematic sectional view showing a schematic structure of an earpiece that constitutes a conventional earphone microphone device. An earpiece 3 is held between the tragus 1 and the fossa 2 of the human ear. The earpiece 3 has a front wall 5 facing the ear canal 4.
Is formed into a substantially circular shape, and has a shape close to a cylindrical shape whose axial distance is shorter than its diameter.

Specifically, as shown in the figure, a vibration pickup 7 and a speaker 8 are housed in a plastic shell 6. The tip 7a of the vibration pickup 7 is exposed from the front wall 5 of the shell 6 to the ear canal 4 side.
Is in contact with the inner wall 4a of the. Then, the vibration pickup 7 detects the bone conduction audio signal via the inner wall 4a of the external auditory meatus 4 and converts it into a transmission signal. The transmission signal a output from the vibration pickup 7 is led to the outside via the signal line 9 and input to a mobile phone (not shown).

On the other hand, the reception signal b from the other party's caller output from the mobile phone is applied to the speaker 8 in the shell 6 via the signal line 11. The speaker 8 converts the reception signal b into a sound pressure signal, and outputs the sound pressure signal from the window formed in the front wall 5 to the ear canal 4
Send to. The speaker 8 is positioned in the shell body 6 via the cushioning member 12.

In the earphone / microphone device having such a structure, the person who wears the earpiece 3 on his / her ear is the speaker 8
You can listen to the sound pressure signal of the other party via. Also,
When speaking normally, a bone conduction voice signal corresponding to the sound pressure signal is detected by the vibration pickup 7 and is transmitted to the other party's caller as a transmission signal a, so that the other party's talker is mixed with ambient noise. Not able to hear the sound pressure signal.

[0010]

However, the earphone microphone device employing the earpiece shown in FIG. 6 still has the following problems to be solved. That is, originally, the vibration pickup 7 has a function of detecting the bone-conducted audio signal by contacting the distal end portion 7 a thereof with the inner wall 4 a of the ear canal 4. However, the vibration pickup 7
As shown in FIG. 7, picks up the vibration of the sound pressure signal 13 output from the speaker 8 into the ear canal 4 due to the utterance of the other party's talker. Further, the vibration 14 generated when the speaker 8 outputs the sound pressure signal 13 is transmitted to the vibration pickup 7 via the cushioning member 12 and the shell 6.

As a result, the vibration pickup 7 detects not only the bone conduction voice signal corresponding to the sound pressure signal emitted by the wearer but also the sound pressure signal emitted by the other party caller. Therefore, as shown in FIG. 8, for example, the voice transmission signal b ₁ of the voice emitted from the other party's party toward the microphone of the handset 16 of the telephone 15 is the communication network 17 and the mobile telephone 1.
8 and the signal line 11 of the earphone microphone device to be input to the speaker 8 and output as a sound pressure signal. Then, the sound pressure signal 13 and the vibration 14 from the speaker 8 are generated.
Is detected by the vibration pickup 7 and output as a sound pressure signal from the speaker of the handset 16 via the signal line 9, the mobile phone 18, the call network 17 and the phone 15.

As a result, the telephone 15 of the other party is
As shown in FIG. 8B, since the reception signal a ₁ having the same content is received after the elapse of a certain time Tg from the transmission of the transmission signal b ₁ , the other party's caller echoes the words spoken by him / herself. I will be returning as, it is very difficult to hear,
Call quality is significantly reduced.

In a normal communication line, the time interval Tg is about several tens of ms, and the deterioration of communication quality is very slight. However, a high-efficiency sound pressure signal encoding process in which the transmitting side recognizes the pattern of the electric signal, encodes it and transmits it as digital data, and the receiving side receives the encoded digital data and demodulates it to the original electric signal. In the case of performing the above, the above-mentioned time interval Tg is about several hundred ms, which is a non-negligible value, and the call quality is significantly reduced.

In order to lower the signal level of the returned received signal a ₁ , it is necessary to reduce the sound pressure signal 13 output from the speaker 8 and the vibration 14 of the speaker 8. However, if the sound pressure signal 13 is reduced, it becomes difficult for the wearer of the earpiece 3 to hear the sound pressure signal of the other party. It is also conceivable to change the cushioning member 12 to a material that easily absorbs vibrations, but this cannot completely absorb the vibrations 14 either.

The present invention has been made in view of the above circumstances, and a microphone for detecting the sound pressure of the speaker is provided in the shell so that the sound pressure signal of the speaker is output from the transmission signal output from the vibration pickup. (EN) An earphone / microphone device capable of significantly improving call quality by removing the signal component caused by the above, and thereby suppressing the received signal from the other party's caller from returning to the other party's caller as an echo signal again. The purpose is to

[0016]

In order to solve the above problems, the present invention provides a bone-conducted audio signal in a shell inserted into the ear canal by exposing the tip of the shell to the inner wall of the ear canal. An earphone microphone device that performs a two-way call with the outside by housing a vibration pickup that detects and outputs to the outside as a transmission signal and a speaker that converts a reception signal input from the outside into a sound pressure signal, A microphone that detects the sound pressure signal output from the speaker and converts it into an electric signal is provided in the body, and the electric signal output from the microphone is subtracted from the transmission signal output from the vibration pickup in the signal path of the transmission signal. The subtraction circuit is inserted.

In another invention, the frequency characteristic from the speaker input to the microphone output and the frequency characteristic from the speaker input to the vibration pickup output are provided in the signal path to the subtraction circuit to which the electric signal output from the microphone is input. An equalizer circuit approximating to is inserted.

[0018]

In the earphone / microphone device constructed as described above, the reception signal received from the other party's caller is converted into a sound pressure signal by the speaker and propagated into the ear canal. The signal can be heard in the eardrum behind the ear canal.

Further, the vibration pickup, which is in contact with the inner wall of the ear canal and detects the bone-conducted sound signal, detects a part of the sound pressure signal propagating in the ear canal as a vibration. The transmission signal resulting from the sound pressure signal detected by the vibration pickup is input to the subtractor. The sound pressure signal output from the speaker is detected by a microphone, converted into an electric signal, and then input to the subtractor.

The subtraction circuit subtracts the electric signal detected by the microphone from the transmission signal of the sound pressure signal detected by the vibration pickup. The output signal of the subtraction circuit becomes a signal from which the electric signal component caused by the wraparound from the speaker has been removed. Therefore, it is possible to prevent the received signal from returning to the other party as an echo. As a result, the call quality with the other party's caller is improved.

Further, in another invention, the frequency characteristic of the electric signal detected by the microphone is corrected to the frequency characteristic of the transmission signal of the vibration pickup by the equalizer circuit.

That is, the frequency characteristic when the sound pressure signal propagating in the ear canal is detected as vibration by the vibration pickup is different from the frequency characteristic when the sound pressure signal is detected by the microphone because the transmission path is different.

Therefore, by correcting the frequency characteristic of the electric signal detected by the microphone in the equalizer circuit, the subtraction circuit more reliably removes the signal component resulting from the sound pressure signal of the speaker from the transmission signal of the vibration pickup. it can.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic cross-sectional view showing the earpiece 21 worn on the ear, and FIG. 2 is a schematic view showing a schematic configuration of the earphone microphone device of the embodiment.

The same parts as those of the conventional earphone microphone device shown in FIG. 6 are designated by the same reference numerals. Therefore, detailed description of the overlapping portions is omitted. As shown in FIG. 2, the earphone microphone device of this embodiment is roughly divided into
An earpiece 21 worn by a worker who works in a poor noise environment on the ear, an adapter 23 connected to the earpiece 21 via a signal cable 22, and a signal cable 24 connected to the adapter 23. It is composed of the connected connector 25. Furthermore, the connector 25
The mobile phone 26 or transceiver is connected via the.

The shell 27 of the earpiece 21 is made of a plastic material. A window 29 through which the sound pressure signal of the speaker 8 is output is formed at a substantially central portion of a front wall 28 having a substantially circular shape of the shell 27. Also, the front wall 28
The tip portion 7a of the vibration pick-up 7 is exposed at a position below.

Similar to the conventional earpiece 3 of FIG. 6, the earpiece 21 of this embodiment has a tragus 1 and a fossa 2 of the human ear.
Held between and. And the plastic shell 2
A vibration pickup 7 and a speaker 8 are housed inside 7. The front end 7a of the vibration pickup 7 is exposed from the front wall 28 of the shell 27 to the ear canal 4 side and is in contact with the inner wall 4a of the ear canal 4.

Next, the signal flow will be described with reference to FIGS. The vibration pickup 7 detects a bone conduction voice signal via the inner wall 4a of the ear canal 4 and outputs it as a transmission signal a ₂ . Transmission signal a ₂ output from the vibration pickup 7
Is guided to the outside via the signal cable 22 and input to the adapter 23.

On the other hand, the reception signal b ₂ from the other party's caller output from the adapter 23 is applied to the speaker 8 in the shell 27 via the signal cable 22. The speaker 8 converts the received signal b ₂ into a sound pressure signal and sends it to the ear canal 4 through the window 29 formed in the front wall 28. The speaker 8 is positioned in the shell 27 via a cushioning member (not shown).

In the shell 27, in addition to the vibration pickup 7 and the speaker 8 described above, a microphone 31 is housed at a position adjacent to the speaker 8. The microphone 31 detects the sound pressure signal output from the speaker 8 and outputs it as an electric signal c. The electric signal c output from the microphone 31 is guided to the outside via the signal cable 22 together with the transmission signal a ₂ from the vibration pickup 7, and is input to the adapter 23.

The equalizer circuit 32 is provided in the adapter 23 connected to the earpiece 21 via the signal cable 22.
The amplifier 33 and the subtraction circuit 34 are housed therein. The adapter 23 is stored in, for example, a pocket of the chest of the wearer of the earpiece 21.

The reception signal b ₂ from the other party's caller input from the mobile phone 26 into the adapter 23 via the connector 25 and the signal cable 24 passes through the adapter 23 as it is and the earpiece via the signal cable 22. Two
Introduced into 1.

On the other hand, the transmission signal a ₂ output from the vibration pickup 7 of the earpiece 21 becomes a transmission signal a ₃ after being amplified to a predetermined signal level by the amplifier 33. Thereafter, the transmission signal a ₃ is input to the (+) side terminal of the subtraction circuit 34.

Further, the electric signal c output from the microphone 31 of the earpiece 21 is input to the equalizer circuit 32. The equalizer circuit 32 corrects the frequency characteristic of the input electric signal c so that it becomes the same as the frequency characteristic of the transmission signal a ₃ output from the vibration pickup 7 and amplified. The corrected electric signal c ₂ is output to the next subtraction circuit 3
4 is input to the (-) side terminal.

When the transmitted signal a ₃ amplified and outputted from the vibration pickup 7 due to the sound pressure signal of the speaker 8 and the electric signal c of the microphone 31 are canceled, a delay characteristic and an amplitude characteristic are provided in the signal transmission path. It is common to insert an equalizer circuit 32 having Therefore, the equalizer circuit 32 finely divides the required frequency band so that the delay characteristic and the amplitude characteristic can be adjusted at arbitrary frequencies, performs delay compensation and amplitude compensation in each frequency band, and expects the entire required frequency band. It has the function of adjusting the frequency characteristics.

FIG. 3 is a detailed circuit diagram of the equalizer circuit 32. The input electric signal c is input to the phase matching circuit 35. The phase matching circuit 35 adjusts the phase of the electric signal c to match the phase of the transmission signal a ₃ . Even if there is no amplitude difference between the electric signal c derived from the sound pressure signal of the speaker 8 detected by the microphone 31 and the detection signal derived from the same sound pressure signal from the speaker 8 detected by the vibration pickup 7. Also in the above, if there is a phase difference between the two signals, it is not possible to completely cancel them by the next subtraction circuit 34. Therefore, the phase matching circuit 35 matches the phases of both.

The electric signal c ₁ whose phase has been adjusted by the phase matching circuit 35 is input to the next three BPFs (bandpass filters) 36a, 36b and 36c connected in parallel. The pass center frequencies F _C1 , F _C2 , and F _C3 of the three BPFs 36a, 36b, and 36c are, for example, 400 Hz and 1 KH.
z and 2.5 KHz are set to different values.

Then, each of the BPFs 36a to 36c individually limits the band of the inputted electric signal c ₁ and sends it to each (+) terminal of the adder circuit 37. The adder circuit 37 adds the output signals of the band-limited BPFs 36a to 36c and outputs the result as a new electric signal c ₂ . Therefore,
The electric signal c ₂ is obtained by converting the electric signal c ₁ into three BPFs 36 a to
The signal has a frequency characteristic corrected by a filter that synthesizes the frequency characteristic of 36c.

In the equalizer circuit 32 of the embodiment apparatus, after the phase characteristic is compensated by the phase matching circuit 35,
Although the amplitude characteristics are compensated by the BPFs 36a to 36c, the order of compensation may be reversed. It is also possible to insert the equalizer circuit 32 in the path of the vibration pickup 7 depending on the characteristics of the transmission path.

The reason why the frequency characteristic correction is performed on the electric signal c will be described with reference to the frequency characteristic diagram shown in FIG.
Each symbol of the electric signal and the transmission signal is as shown in FIG.

FIG. 4A is a frequency characteristic diagram before the frequency characteristic correction, and FIG. 4B is a frequency characteristic diagram after the frequency characteristic correction. Further, A in the figure shows the frequency characteristic of the signal path from the input of the speaker 8 to the output of the vibration pickup 7, and B in the figure shows the frequency characteristic of the input of the speaker 8 to the microphone 31.
3 shows the frequency characteristic of the signal path up to the output of.

The detection frequency characteristic A for detecting the bone-conducted audio signal of the vibration pickup 7 by contacting the inner wall 4a of the external auditory meatus 4 has a mountain-shaped characteristic having many peaks and valleys in the vicinity of 2 KHz as shown in the figure. Therefore, when the vibration pickup 7 detects and amplifies the sound pressure signal output from the speaker 8, the transmitted signal a ₃ is as shown in FIG.
The signal has a frequency characteristic indicated by A.

On the other hand, when the microphone 31 detects the sound pressure signal output from the speaker 8, its electric signal c
Is a signal having a relatively straight mountain-shaped frequency characteristic shown by B in FIG.

Therefore, in order to use the electric signal c of the microphone 31 to cancel the signal component due to the sound pressure signal included in the transmission signal a ₃ by using the subtraction circuit 34, the electric signal detected by the microphone 31 is used. It is necessary to compensate c to a frequency characteristic close to the detected frequency characteristic A.

In the apparatus of this embodiment, three BPFs 3 are used.
6a-36c, 400Hz, 1KH, respectively
The frequency characteristic was compensated at z and 2.5 KHz. as a result,
As shown in FIG. 4B, the frequency characteristic B of the electric signal c ₂ compensated by the equalizer circuit 32 is similar to the frequency characteristic A of the transmission signal a ₃ .

The subtraction circuit 34 subtracts the electric signal c ₂ whose frequency characteristic is corrected by the equalizer circuit 32 from the transmission signal a ₃ amplified by the amplifier 33, and outputs it as a new transmission signal a ₄ .

In the actual adapter 23, the equalizer circuit 32, the subtraction circuit 34 and the amplifier 3 described above are used.
3 can also be configured by one integrated circuit (LSI). The transmission signal a ₄ output from the adapter 23 is as shown in FIG.
As shown in, the signal is input to the mobile phone 26 via the signal cable 24 and the connector 25.

In the earphone / microphone device having the above structure, the person wearing the earpiece 21 in his / her ear
When speaking to the other party's caller, when speaking normally, a bone conduction voice signal corresponding to the sound pressure signal is detected by the vibration pickup 7 and transmitted to the adapter 23 via the signal cable 22 as a transmission signal a _2. It is amplified by the amplifier 33 and input to the subtraction circuit 34.

In the subtraction circuit 34, the transmission signal a ₃ is subtracted from the electric signal c ₂ output from the microphone 31 and the frequency characteristic of which is corrected in the equalizer circuit 32, and a new transmission signal a ₄ is obtained. It is sent to the mobile phone 26 via the cable 24.

In this case, since the signal level of the electric signal c output from the microphone 31 is almost zero when the sound pressure signal is not output from the speaker 8, the transmission signal input to the mobile phone 26. a ₄ is substantially equal to the transmission signal a ₃ of the bone conduction voice detected and amplified by the vibration pickup 7.

The mobile phone 26 receives the transmitted transmission signal a ₄
To the other party's telephone set via the call network. The other party's caller can hear the voice of the wearer of the earpiece 21 through the speaker of the handset of the telephone.

On the other hand, when the other party talker talks to the wearer of the earpiece 21 through the microphone of the handset, the sound pressure signal is converted into an electric signal, and the telephone, the communication network, the mobile telephone 26, and the signal cable 24 are connected. And is introduced into the earpiece 21 via the adapter 23. The received signal b ₂ is converted into a sound pressure signal by the speaker 8. The sound pressure signal output from the speaker 8 is the front wall 2
It is delivered to the external auditory meatus 4 through a window 29 formed in 8. As a result, the wearer of the earpiece 21 can hear the sound pressure signal through the eardrum.

In this case, the sound pressure signal of the other party's caller output from the speaker 8 is also detected by the vibration pickup 7. The detected transmission signal a ₂ is input to the subtraction circuit 34 of the adapter 23. The sound pressure signal of the other party's caller is detected by the microphone 31 and sent to the adapter 23 as an electric signal c. The electric signal c is frequency-corrected by the equalizer circuit 32 and input to the subtraction circuit 34.

The subtraction circuit 34 cancels the transmission signal a ₃ generated by the sound pressure signal and the electric signal c ₂ . Therefore, the transmission signal resulting from the sound pressure signal of the other party's caller output from the speaker 8 is not output from the adapter 23.

As a result, the other party's caller is greatly suppressed from returning the sound pressure signal, which he or she has emitted to the microphone of the handset, to the speaker of the handset as an echo, so that the discomfort is eliminated. , The call quality is greatly improved.

As described above, since the microphone 31 and the subtraction circuit 34 for canceling the signal due to the sound pressure signal from the speaker 8 detected by the vibration pickup 7 are provided,
Even in a call system that performs communication processing that performs high-efficiency sound pressure signal encoding processing with a large transmission delay, call quality does not deteriorate.

FIG. 5 is a schematic diagram showing a schematic structure of an earphone microphone device according to another embodiment of the present invention. The same parts as those of the embodiment shown in FIG. 1 are designated by the same reference numerals. Therefore, detailed description of the overlapping portions is omitted.

In this embodiment, the adapter 23
Only the subtraction circuit 32 is stored in a. That is, the equalizer circuit 32 and the amplifier 32 in the embodiment apparatus of FIG. 1 are removed.

In the earphone microphone device having such a configuration, the electric signal c obtained by detecting the sound pressure signal output from the speaker 8 by the microphone 31 is directly input to the subtraction circuit 32 without frequency correction. However, in general, the detection frequency characteristic of the microphone 3 and the vibration pickup 7
Since it has a characteristic similar to the detection frequency characteristic of, even if the frequency characteristic is not completely matched by the equalizer circuit 32, the echo can be reduced only by the subtraction circuit 32, and the speech quality that is sufficiently practical can be obtained. Can be secured.

[0060]

As described above, in the earphone microphone device of the present invention, the microphone and the subtraction circuit are provided. Therefore, the signal resulting from the sound pressure signal output from the speaker detected by the vibration pickup can be canceled by the electric signal detected by the microphone. Therefore,
It is possible to prevent the sound pressure signal from the other party's caller from returning to the other party's party as an echo again, and it is possible to significantly improve the quality of the call with the other party's party.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a schematic configuration of an earphone microphone device according to an embodiment of the present invention.

FIG. 2 is an external view showing the entire earphone / microphone device of the same embodiment.

FIG. 3 is a detailed circuit diagram of an equalizer circuit incorporated in the apparatus of the embodiment.

FIG. 4 is a diagram showing an example of frequency characteristics of the equalizer circuit.

FIG. 5 is a schematic diagram showing a schematic configuration of an earphone microphone device according to another embodiment of the present invention.

FIG. 6 is a schematic sectional view showing a schematic configuration of an earpiece in a conventional earphone microphone device.

FIG. 7 is a diagram for explaining a problem of the conventional device.

FIG. 8 is a diagram for explaining the cause of echo generation in the conventional device.

[Explanation of symbols]

1 ... Tragus, 2 ... Fovea, 4 ... External auditory meatus, 4a ... Inner wall, 7 ...
Vibration pickup, 8 ... speaker, 21 ... earpiece,
22, 24 ... Signal cable, 23 ... Adapter, 26 ... Mobile phone, 27 ... Shell, 28 ... Front wall, 29 ... Window, 31 ...
Microphone, 32 ... Equalizer circuit, 33 ... Amplifier, 34 ... Subtraction circuit, 35 ... Phase matching circuit, 36a, 3
6b, 36c ... BPF, 37 ... Adder

Claims (2)

[Claims] 1. A vibration pickup that detects a bone-conducted voice signal and outputs it as a transmission signal to the outside by detecting a bone-conducted audio signal in the shell inserted into the ear canal by exposing the tip from the shell and contacting the inner wall of the ear canal. In an earphone microphone device that performs a two-way call with the outside by accommodating a speaker that converts a reception signal input from the outside into a sound pressure signal, a sound pressure signal output from the speaker is provided in the shell. And a subtraction circuit that is inserted in the signal path of the transmission signal and subtracts the electric signal output by the microphone from the transmission signal output by the vibration pickup. Earphone microphone device. 2. A frequency characteristic from a speaker input to a microphone output, which is inserted in a signal path to the subtraction circuit to which an electric signal output from the microphone is input,
The earphone microphone device according to claim 1, further comprising an equalizer circuit that approximates a frequency characteristic from a speaker input to a vibration pickup output.