JP2006025382A - Amplitude suppressing circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve an apparent capability of an acoustic apparatus by producing an audio signal to obtain a reproduced sound of a little distortion even if an amplitude of a large-amplitude signal is strongly suppressed, and also to improve performance of an apparatus dealing with audio signals, such as a high-quality hearing-aid by converting an audio signal detected by a microphone through a similar method into a signal to obtain a reproduced sound of a sound volume feeling that human ears feel like a natural sound, and using such a sound. <P>SOLUTION: A small-amplitude signal is kept as it is, and amplitude suppression is performed on a low-frequency and great-amplitude audio signal. However, amplitude suppression is not performed so much on a signal as its frequency increases. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an audio signal amplitude suppression circuit capable of obtaining reproduced sound with very little deterioration in sound quality.

Conventionally, when an amplitude signal that greatly exceeds the capacity of an audio signal amplifier or the like is input, the reproduced sound quality of the output signal is significantly lowered. For this reason, the present inventors have devised a limiter that causes little degradation in reproduction sound quality even when a large amplitude signal is input (Japanese Patent Application No. 2000-172705). However, in this limiter too, when a too large amplitude signal is input, deterioration in sound quality is inevitable. Therefore, there has been a demand for the appearance of a circuit that can greatly suppress the amplitude without causing a decrease in reproduced sound quality.
In addition, when the natural sound collected by the microphone is played back by the speaker, the level difference between the distant sound and the nearby sound is very large, and there is a big difference from the level difference that humans feel in nature. Therefore, conventionally, when many sound sources exist at various distances, a signal captured by a microphone cannot identify a distant sound like a human ear. And the reason was that people were selecting and listening to the sounds they wanted to hear. Therefore, it has long been a dream to obtain a reproducible sound that can be identified in the same way that a human ear recognizes a natural sound.

It is an object of the present invention to obtain a reproduced sound with little deterioration in sound quality even when strong amplitude suppression is performed and to obtain a reproduced sound with a sound pressure level that makes a person feel natural. That is, if the amplitude of the audio signal is suppressed without causing the reproduced sound to be distorted, the dynamic range of the signal can be reduced, so that the practical ability of the acoustic device is improved. Further, if the amplitude difference between the large amplitude signal and the small amplitude signal can be reduced, it is possible to obtain a reproduced sound having a level difference that makes a person feel a natural sound.
(The biggest difference between a distant sound and a nearby sound is the difference in level depending on the frequency. That is, the bass sound is more attenuated by the distance than the treble sound. The bass amplitude of the sound is small, and it is thought that humans are listening to the low-level bass signal with a small correction, so that even if it is a bass signal, the small-amplitude signal remains unchanged and the amplitude of the large-amplitude signal is suppressed. And get the ideal playback sound.)

If the amplitude can be suppressed more strongly at a lower frequency while keeping the low level signal as it is, even if the low amplitude signal is strongly suppressed, the reproduced sound does not feel much distortion. In addition, if the amplitude of the signal detected by the microphone is suppressed, it is possible to reproduce a sound with a small level difference between a distant sound and a nearby sound that humans feel in nature. And confirmed by experiments).
In addition, since the natural sound usually has a small amplitude at a high frequency, the dynamic range can be sufficiently reduced by suppressing the amplitude of a low frequency signal without suppressing a high frequency signal.

There are various methods for suppressing the amplitude more strongly at a lower frequency while keeping the small level signal as it is, but “FIG. 1” and “FIG. 2” are circuit examples.
Explaining "Figure 1"
1) One end of C1 is an audio signal input circuit, and the other end is connected to the plus input terminal of OP1.
2) One end of R1 is connected to the plus input terminal of OP1, and the other end is connected to GND. Therefore, R1 makes the no-signal potential of the positive input terminal of OP1 equal to GND.
3) The output terminal and the negative input terminal of OP1 are connected, and OP1 constitutes a buffer amplifier.
4) One end of C2 is connected to the output terminal of OP1, and the other end is connected to the cathode of D1 and the anode of D2. The anode of D1 and the cathode of D2 are connected to GND. Therefore, if the OP1 output signal amplitude exceeds the forward potential of D1 and D2, the signal whose amplitude is limited by shifting the bias at the coupling point of C2, D1 and D2 (the same voltage signal as the limiter output of Japanese Patent Application No. 2000-172705). ) Appears.
5) One end of R2 is connected to the output terminal of OP1, and the other end is connected to the negative input terminal of OP2. One end of R5 is connected to the minus terminal of OP2, and the other end is connected to the output terminal. The values of R2 and R5 are the same.
6) One end of R3 is connected to the junction of C2, D1, and D2, and the other end is connected to the positive input terminal of OP2. One end of R4 is connected to the plus input terminal of OP2, and the other end is connected to GND. The values of R3 and R4 are the same.
7) Due to the connection in the items 5) and 6), a difference between the signal at the output terminal of OP1 and the signal at the connection point of C2, D1, and D2 appears at the output terminal of OP2. That is, the output signal of OP2 is equivalent to the bias shift signal for obtaining the signal at the connection point of C2, D1, and D2 from the output signal of OP1.
7) One end of R6 is connected to the output terminal of OP2, and the other end is connected to one end of C3. The other end of C3 is connected to GND. The connection point between R6 and C3 is connected to the plus input terminal of OP3. That is, R6 and C3 constitute a high cut filter, and the high cut filter output signal is applied to the plus input terminal of OP3.
8) The output terminal of OP3 is connected to the negative input terminal of OP3. That is, OP3 is a buffer amplifier.
9) One end of R8 is connected to the output terminal of OP3, and the other end is connected to the negative input terminal of OP4. One end of R7 is connected to the output terminal of OP1, and the other end is connected to the negative input terminal of OP4. The values of R7 and R8 are equal.
10) One end of R9 is connected to the output terminal of OP4, and the other end is connected to the negative input terminal of OP4. The plus input terminal of OP4 is connected to GND. Therefore, the output signal of OP3 and the output signal of OP1 are added and inverted at the output terminal of OP4. In other words, the OP4 output circuit has a signal obtained as a result of the bias shift of the output signal of OP1 being smoothed by the high-cut bias shift signal for creating the signal at the connection point between C2, D1 and D2. Appears reversed.
11) The output signal of OP4 is subjected to amplitude limitation similar to that of the limiter of Japanese Patent Application No. 2000-172705 at a relatively low frequency, but is not so limited at high frequency. However, since the amplitude of the normal audio signal is smaller as the frequency is higher, the dynamic range of the signal can be reduced only by limiting the amplitude of the lower frequency. Further, since the high frequency amplitude limit is not so much performed, even if the low frequency amplitude limit is performed, the generation of harmonics is small, and the reproduced sound does not feel much distortion.
12) Although the limiter by D1, D2, and C2 is equivalent to Japanese Patent Application No. 2000-172705, even if a general limiter is used, the object of the present invention can be satisfied to some extent (with C2 as a resistance). If replaced, it is a general limiter). However, the reproduced sound quality is inferior to that when the limiter of Japanese Patent Application No. 2000-172705 is used.

“FIG. 2” is a circuit that can obtain an amplitude suppression signal of reproduced sound with little distortion without separating bias shift signals. This circuit has the advantage of not requiring the accuracy of the circuit constants as the circuit of FIG.
Explaining the circuit operation of "Fig. 2"
1) The output terminal and the negative input terminal of OP5 are connected to each other, and OP5 constitutes a buffer amplifier.
2) An audio signal is input to the plus input terminal of OP5. The audio signal is output from the output terminal of OP5 with low impedance.
3) One end of C5 is connected to the output terminal of OP5, and the other end is connected to the plus input terminal of OP6, and the output signal of OP5 is transmitted to OP6.
4) One end of R14 is connected to the plus input terminal of OP6, and the other end is connected to GND to determine the input bias voltage of OP6 when there is no signal.
5) The output terminal and the negative input terminal of OP6 are connected to each other, and OP6 constitutes a buffer amplifier.
5) One end of R10 is connected to + Vcc and the other end is connected to the base of Q1. One end of R11 is connected to the base of Q1, and the other end is connected to GND. Therefore, R10 and R11 determine the Q1 base voltage when there is no signal. The voltage between the base of Q1 and GND is smaller than Vb-e of Q1.
6) One end of R13 is connected to -Vcc and the other end is connected to the base of Q2. One end of R12 is connected to the base of Q2, and the other end is connected to GND. Therefore, R13 and R12 determine the Q2 base voltage when there is no signal. The voltage between the base of Q2 and GND is smaller than Vb-e of Q2.
7) One end of C4 is connected to the output terminal of OP5, and the other end is connected to the base of Q1. C4, R10, and R11 constitute a high-pass filter and transmit a relatively high frequency signal ratio of the output signal of OP5 to the base of Q1.
8) One end of C6 is connected to the output terminal of OP5, and the other end is connected to the base of Q2. C6, R13, and R12 constitute a high-pass filter and transmit a relatively high frequency signal ratio of the output signal of OP5 to the base of Q2.
9) When a signal is input to INPUT, it appears at the output terminal of OP5. The output signal of OP5 is input to the plus terminal of OP6 via C5. At this time, the signal has a low frequency at which the signal cannot pass through the high-pass filter of C4, R10, R11 or C6, R13, R12, and the amplitude that the signal that has passed through C5 may cause the emitter current to flow through Q1 or Q2. In this case, the bias of the positive input terminal of OP6 is shifted by the emitter current of Q1 or Q2. As a result, the positive input terminal signal of OP6 is limited in amplitude.
10) If the signal input to INPUT is a high frequency that appears sufficiently in the output of the high-pass filter by C4, R10, R11 or C6, R13, R12, the base potential is changed along with the potential fluctuation due to the signal of the emitter of Q1 or Q2. Since it fluctuates, the signal at the positive input terminal of OP6 is not subject to much amplitude suppression.
11) The positive input terminal signal of OP6 is impedance-converted at OP6 and output from the output terminal.
12) As in FIG. 1, this circuit uses the same circuit as that of Japanese Patent Application No. 2000-172705 for amplitude suppression, but it is possible to replace C5 with a resistor to obtain a general limiter configuration.

Even if a signal exceeding the dynamic range is input to the audio equipment, it is possible to obtain a reproduced sound with little distortion, so that the apparent performance of the audio equipment can be enhanced.
In addition, since a sound with a level feeling close to the sound that humans feel in nature can be reproduced, the sound quality of a hearing aid, a recorder, etc. can be dramatically improved.
In addition, the difference in volume and sound quality due to the distance between the microphone and the sound source can be reduced, making it easier to capture far away sounds.

  FIG. 3A is an example block diagram of a power amplifier circuit in which the present invention is used. When the present invention is used for a power amplifier, it is possible to improve the audible amplifier capability. In other words, even if an amplitude signal exceeding the capability is input, the amplitude can be suppressed so that the reproduced sound is not distorted. As a result, a volume like an amplifier having a large output can be produced.

  FIG. 3B is an example of a circuit block diagram when the present invention is used in a hearing aid. Conventional hearing aids (including hearing aids and sound collectors) have made it almost impossible to distinguish between distant sounds and nearby sounds at the same time. However, hearing aids using the present invention seem to sound like a normal hearing person. Can be heard. The reason is that it is possible to suppress a nearby excessive bass without distortion, while keeping a far bass (that is, the amplitude is small) as it is.

  FIG. 3C is an example of a circuit block diagram in which the present invention is used in a telephone. Conventionally, in a hands-free telephone, when a speaker talks away from a microphone, there is a drawback that the transmitted sound sounds like a voice far away for the receiver. However, in a hands-free telephone in which the present invention is used for a transmission circuit, the transmission sound quality does not change much even if the speaker is slightly away from the microphone. Therefore, the listener can have a conversation with no sense of incongruity.

FIG. 3D is an example of a circuit block diagram when the present invention is used in a loudspeaker. A loudspeaker can produce a relatively large volume with a small amount of power, similar to a power amplifier.
Therefore, it is very useful in applications where small size and light weight are required.

  FIG. 3E is an example of a circuit block diagram when the present invention is used in a tape recorder. When recording at a conference or the like with a conventional recording machine, the level of the reproduced sound was so large that the sound between the nearby sound and the distant sound was so large that the intelligibility could not be increased. However, a recorder using the present invention can clearly record distant sounds and nearby sounds. This is for the same reason as in the case of hearing aids.

  FIG. 3F is an example of a circuit block diagram when the present invention is used for a telephoto microphone. In video cameras, etc., a sharp directional microphone called a telephoto microphone is sometimes used to better record the sound near the subject, but it is only sensitive to sound in a certain direction. The volume difference due to the difference was the same as that of a normal microphone. However, if this sharp directional microphone is combined with the present invention, it is possible to capture far away sounds in a certain direction more clearly.

  FIG. 3 (G) is an example of a circuit block diagram when the present invention is used in a speech recognition apparatus. Conventionally, in a speech recognition apparatus, a speaker usually speaks close to a microphone because of a problem of recognition rate. However, if the present invention is used, the speaker can obtain a high recognition rate even if the speaker is not so close to the microphone.

  In addition to the examples shown in FIG. 3, the present invention has high utility value in all devices for audio signals.

Amplitude suppression circuit example 1 of the present invention Amplitude suppression circuit example 2 of the present invention Example of block diagram of audio equipment circuit in which the present invention is used

Explanation of symbols

R1 to R14 are resistors C1 to C6 are capacitors D1, D2 is a diode OP1 to OP6 are operational amplifiers Q1, Q2 is a transistor VR is an attenuator IN PUT is an input circuit OUT PUT is an output circuit + Vcc is a positive power supply −Vcc is a negative power supply GND is a ground Circuit AF AMP is a low frequency amplifier SUPPRESS is an amplitude suppressor of the present invention PW AMP is a power amplifier MIC is a microphone PHONE is an earphone S.P. N. C is a speech network circuit. F. C is a hands-free circuit DIALER is a dial circuit. S is handset SP is speaker R.S. P. H is a recording / reproducing head REC AMP is a recording amplifier PB AMP is a reproducing amplifier

Claims (3)

When an amplitude signal exceeding the preset level is input, the amplitude part below the preset level is almost unchanged, and the amplitude part exceeding the preset level is more strongly suppressed by the low frequency signal than the high frequency signal. Signal amplitude suppression circuit. An audio signal amplitude suppression circuit in which the amplitude of a signal is suppressed by changing a bias or subtracting or adding another signal. A power amplifier, a hearing aid, a hearing aid, a telephone, a communication device, a loudspeaker, a recording device, a telephoto microphone, in which the audio signal amplitude suppression circuit according to claim 1 or claim 2 or both of claim 1 and claim 2 is used, All devices that handle voice signals, such as voice recognition devices.

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