JPH06338746A - Agc circuit for audio apparatus - Google Patents

Abstract

PURPOSE:To provide an AGC circuit for audio apparatus which realizes quick AGC response without the silent state or the occurrence of cracking sounds at the time of the amplitude change of an input signal. CONSTITUTION:This AGC circuit consists of a first AGC circuit 1, which is provided with a first audio signal level control means 5 to which first AGC feedback loops 6 to 12 are connected and has a slow AGC control response characteristic, and a second AGC circuit 2 which is provided with a second audio signal level control means 13 to which second AGC feedback loops 14 to 20 are connected and has a quick AGC control response characteristic, and first and second AGC circuits 1 and 2 are cascaded to an audio signal line. When the input signal whose amplitude is quickly increased is supplied to an input terminal 3, the first AGC circuit 1 converts it to a signal whose amplitude is temporarily increased and is fixed after a long time, and the second AGC circuit 2 converts it to a signal whose amplitude is temporarily slightly increased and is fixed after a short time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to an audio equipment AG.
In connection with a C (automatic gain control) circuit, in particular, when performing AGC of an audio signal, an adverse effect caused by an inadequate control response of the AGC circuit due to a large instantaneous variation of the audio signal is eliminated. It relates to an AGC circuit.

[0002]

2. Description of the Related Art Conventionally, an AGC circuit for audio equipment has a circuit configuration as shown in FIG.

In FIG. 5, 50 is an electronic volume IC as an audio signal level control means, 51 is an audio signal input terminal, 52 is an audio signal output terminal, 5
3 is a double-wave rectifier circuit, 54 is a voltage regulator, 55 is an operational amplifier, 56 is a diode, 57 is a resistor, 58 is a capacitor for discharging electric charge, and the diode 56, the resistor 57, and the capacitor 58 are fast attack and slow recovery circuits. Are configured.

In the above configuration, the audio signal supplied to the audio signal input terminal 51 is amplified as a required gain in the electronic voltage regulator IC 50 and then taken out from the audio signal output terminal 52 as an audio output signal. At this time, a part of the audio output signal is rectified by the double-wave rectification circuit 53 and converted into a pulsating current voltage, and then the level thereof is adjusted by the voltage regulator 54, and the operational amplifier 55.
It is supplied to the inverting input terminal of. Next, the pulsating current voltage is inverted and amplified by the operational amplifier 55, and further smoothed by the fast attack and slow recovery circuits 56 to 58 to obtain A.
It is converted into a GC voltage and supplied to the gain control terminal of the electronic volume IC 50.

Here, FIG. 6 shows an electronic volume IC 50.
FIG. 6 is a characteristic diagram showing an example of a relationship between the AGC voltage supplied to the device and the attenuation amount of the audio signal in the electronic volume IC 50.

When the level of the audio signal input to the electronic volume IC 50 is high, the operational amplifier 55
Due to the inverting and amplifying action of, the AGC voltage supplied to the electronic volume IC 50 is reduced, and as a result, the attenuation amount of the electronic volume IC 50 is increased as shown in FIG.
Conversely, when the level of the audio signal input to the electronic volume IC 50 is low, the electronic volume IC 5
The AGC voltage supplied to 0 increases, and as a result, the amount of attenuation of the electronic volume IC 50 decreases.

Therefore, even if the level of the audio signal input to the audio signal input terminal 51 changes considerably, the level change of the audio signal output from the audio signal output terminal 52 can be suppressed within a required range. It is a thing.

By the way, in the known AGC circuit, when the audio output signal obtained at the audio signal output terminal 52 is heard as a reproduced sound, the reproduced sound is usually unnatural so as not to be unnatural. In the attack / slow recovery circuits 56 to 58, when the amplitude of the input audio signal sharply increases, the time (attack time) ta until the amplitude of the output audio signal becomes constant is small, and the input The characteristic is set so that the time (decay time) td until the amplitude of the output audio signal becomes constant when the amplitude of the output audio signal sharply decreases becomes large.

[0009]

FIG. 7 shows this known A
1A shows an example of changes in signal waveforms and voltage states of various parts in a GC circuit, where (a) is an electronic volume IC
50 is an audio signal input to 50, (b) is an AGC voltage supplied to the gain control terminal of the electronic volume IC 50,
(C) and (d) are audio signals output from the electronic volume IC 50, respectively.

Now, referring to FIG.
When an audio signal as shown in (a) is input and its amplitude sharply increases at time t ₁ , the attack time ta becomes a relatively small attack time t.
If a ₁ is set, the change in AGC voltage is
Overshoot occurs as shown by the solid line in FIG. Therefore, as shown in FIG. 7C, the audio signal output from the electronic volume IC 50 has a problem that the amplitude temporarily becomes zero and a so-called silent state occurs. On the other hand, if a slightly larger attack time ta ₂ is set as the attack time ta,
The change in the GC voltage becomes gentle as shown by the broken line in FIG. Therefore, although it is possible to avoid the occurrence of the silent state, this time, as shown in FIG. 7D, the followability of the AGC voltage with respect to the increase of the amplitude of the audio signal becomes poor, and the output is made from the electronic volume IC 50. It takes a relatively long time until the amplitude of the audio signal becomes constant, and there is a new problem that an increase in the amplitude of the audio signal causes pop noise.

The present invention eliminates the above-mentioned problems, and an object of the present invention is to quickly respond to various changes in the amplitude of an input signal without producing a silent state or a rattling noise and quickly responding to AGC. AGC of audio equipment that can
To provide a circuit.

[0012]

To achieve the above object, the present invention comprises a first audio signal level control means having a first AGC feedback loop coupled to the slow AGC.
The first AGC circuit having the control response characteristic and the second AGC circuit having the second audio signal level control means to which the second AGC feedback loop is coupled are provided, and the second AGC circuit having the fast AGC control response characteristic is provided. AGC circuit and the second AGC
The circuit comprises means cascaded to the audio signal path.

Further, in order to achieve the above-mentioned object, the means according to the present invention comprises: a first operational amplifier in which the first AGC feedback loop has first and second input terminals and an output terminal; A first input resistor connected in series to the first input terminal, a first capacitor connected between the first input terminal and the output terminal, and a first capacitor connected between the second input terminal and the ground. A first bias power supply, and
The AGC feedback loop includes a second operational amplifier having first and second input terminals and an output terminal, a second input resistor connected in series to the first input terminal, and the first input terminal. It includes a second capacitor and a diode connected in parallel with the output terminal, and a second bias power supply connected between the second input terminal and ground.

[0014]

According to the above means, in the first AGC circuit having the slow AGC control response characteristic, the first AGC circuit has the large attack time, and the second AGC circuit having the fast AGC control response characteristic has the large attack time.
The second AGC feedback loop has a small attack time. Therefore, the first AGC circuit gently absorbs a change in the amplitude of the audio signal when an audio signal whose amplitude suddenly increases is input, and its output gradually attenuates after the amplitude temporarily increases. An intermediate audio output signal is obtained. Then the second AG
When the audio intermediate output signal is input, the C circuit rapidly absorbs only the increased amplitude portion of the audio intermediate output signal, and its output is temporarily increased in amplitude and then within a short time. A substantially constant audio output signal is obtained.

As described above, according to the above-mentioned means, since the AGC of the audio signal is performed by sequentially using the two AGC circuits having different AGC control response characteristics, the amplitude suddenly increases. Even if an audio signal is input, an audio signal whose amplitude is substantially constant can be obtained within a relatively short time without generating a silent state due to overshoot of the AGC voltage or a clicking sound accompanying a delay in AGC followability. Moreover, the dynamic range of the AGC can be greatly expanded as compared with the conventional AGC circuit of this type.

According to the above-mentioned means, when an audio signal whose amplitude sharply increases or decreases, an audio signal of slightly large or slightly small amplitude is initially output, and then an audio signal of a predetermined amplitude is output. Since the signal is output, the portion where the amplitude of the input audio signal changes abruptly can be clearly identified when listening to the reproduced sound.

[0017]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a circuit configuration diagram showing an embodiment of an AGC circuit of an audio device according to the present invention.

In FIG. 1, 1 is an AGC circuit having a slow AGC control response characteristic (hereinafter referred to as a low speed response AGC circuit), 2 is an AGC circuit having a fast AGC control response characteristic (hereinafter referred to as a high speed response AGC circuit) 3 is an audio signal input terminal and 4 is an audio signal output terminal.

The low-speed response AGC circuit 1 has its input connected to the audio signal input terminal 3 and its output connected to the input of the high-speed response AGC circuit 2, respectively.
Has an output connected to the audio signal output terminal 4. The low-speed response AGC circuit 1 includes the first electronic volume I
C (first audio signal level control means) 5, voltage regulator 6, first rectifier circuit 7, first amplifier 8, first input resistor 9, first bias power supply 10, first operational amplifier. 11 and a first AGC feedback loop including the first capacitor 12. In addition, the fast response AGC circuit 2
Is a second electronic volume IC (second audio signal level control means) 13, a second rectifier circuit 14, a first amplifier 15, a second input resistor 16, a second bias power supply 17, a second A second AGC feedback loop including an operational amplifier 18, a diode 19, and a second capacitor 20. In the first AGC feedback loop, the first operational amplifier 11 has an inverting (first) input terminal, a non-inverting (second) input terminal, and an output terminal, and the first operational amplifier 11 is connected in series to the inverting input terminal. In the input resistor 9, the first capacitor 12 is connected between the inverting input terminal and the output terminal, and the first bias power supply 10 is connected between the non-inverting input terminal and the ground. The voltage regulator 6 is the first electronic volume IC 5
Of the first input resistor 9 connected via the first rectifier circuit 7 and the first amplifier 8.
Is connected to the other end of. The output terminal of the first operational amplifier 11 is connected to the gain control terminal of the first electronic volume IC 5. In this case, the first input resistor 9 and the first capacitor 12 form an integrating circuit, and the decay time td is set by the time constant.

In the second AGC feedback loop, the second operational amplifier 18 has an inverting (first) input terminal, a non-inverting (second) input terminal, and an output terminal, and is serially connected to the inverting input terminal. The second input resistor 16 has the diode 19 and the second capacitor 20 connected in parallel between the inverting input terminal and the output terminal, and the second bias power supply 17 connected between the non-inverting input terminal and the ground. There is. The output terminal of the second electronic volume IC 13 is the audio signal output terminal 4
Is further connected to the other end of the second input resistor 16 via the second rectifier circuit 14 and the second amplifier 15. The output terminal of the second operational amplifier 18 is connected to the gain control terminal of the second electronic volume IC 13.

Further, FIG. 2 shows the low speed response A shown in FIG.
3 shows the input / output characteristics (dynamic range) of the GC circuit 1 and the high-speed response AGC circuit 2, where (a) is the low-speed response AGC circuit 1 and (b) is each of the characteristics in the high-speed response AGC circuit 2. The horizontal axis represents the input signal level and the vertical axis represents the output signal level.

Further, FIG. 3 shows an example of changes in signal waveforms and voltage states of the respective parts in the embodiment shown in FIG. 1, in which (a) is an audio input to the low speed response AGC circuit 1. Signal, (b) is the AGC voltage supplied to the low speed response AGC circuit 1, (c) is the low speed response AGC circuit 1
Is an audio intermediate output signal output from, the (d) is an AGC voltage supplied to the high speed response AGC circuit 2, and (e) is an audio output signal output from the high speed response AGC circuit 2. The axis shows the signal or voltage level.

Here, the operation of this embodiment will be described with reference to FIGS.

When the audio signal supplied to the audio signal input terminal 3 is input to the low speed response AGC circuit 1,
In the first electronic volume IC 5, the signal level is adjusted according to the magnitude of the AGC voltage applied to its gain control terminal. The audio signal whose signal level has been adjusted is taken out from the low speed response AGC circuit 1 as an audio intermediate output signal and supplied to the next high speed response AGC circuit 2. At this time, a part of the audio intermediate output signal is also supplied to the first AGC feedback loop, and first, the starting point of AGC (a little left side of -A in FIG. 2) is adjusted by the voltage regulator 6, and then, Is rectified by the rectifier circuit 7 and converted into a pulsating voltage. The pulsating current voltage is amplified by the first amplifier 8 and then supplied to the inverting input terminal of the first operational amplifier 11 to be inverted and amplified, and then the first capacitor 12
And the like, and is converted into an AGC voltage and applied to the gain control terminal of the first electronic volume IC5.

In this case, in the first AGC feedback loop, the output voltage of the first bias power supply 10 connected to the non-inverting input terminal of the first operational amplifier 11 determines the level of the audio intermediate output signal. And a voltage substantially equal to the intermediate voltage (reference voltage) of the AGC voltage supplied to the signal first electronic volume IC 5, for example, 2.5.
Configured to generate V. Further, the attack time t _a1 of the AGC voltage is determined by the output impedance value r _O of the first operational amplifier 11 and the capacitance value C ₁₂ of the first capacitor _12.
It is decided by and.

Now, as shown in FIG. 3A, the amplitude of the audio signal input to the low-speed response AGC circuit 1 rapidly increases at time t _{0 and} rapidly decreases at time t ₁ . If so, the first operational amplifier 11 sequentially decreases in the attack time t _a1 period from the time t ₀ , as shown in FIG. 3B, in response to the audio signal whose amplitude sharply increases and decreases. And time t ₁
The AGC voltage that gradually increases is generated during the _decay time t _d1 . As a result of such an AGC voltage being supplied to the first electronic volume IC 5, the low speed response AGC circuit 1
As shown in FIG. 3 (c), the output of the signal is temporarily increased in amplitude at time t ₀ , and then the amplitude is stabilized for a relatively long time, and then at time t ₁ , After the amplitude is temporarily decreased, an audio intermediate output signal in which the amplitude is constant is obtained in the same manner as before, taking a relatively long time.

At this time, the low speed response AGC circuit 1 operates as shown in FIG.
As shown in (a), the flat portion of the output signal level with respect to the level change of the input signal has input / output characteristics extending from the reference input signal level point O to the level range of ± Adbm. In order to prevent overshooting of the AGC voltage inside the
_O and capacitance C ₁₂ are selected.

Next, the audio intermediate output signal output from the low speed response AGC circuit 1 is supplied to the high speed response AGC circuit 2 and the magnitude of the AGC voltage applied to the gain control terminal of the second electronic volume IC 13 is increased. The signal level is adjusted again according to this, and is taken out from the high-speed response AGC circuit 2 as an audio output signal and supplied to the audio signal output terminal 4. At this time, a part of the audio output signal is supplied to the second AGC feedback loop, and is first rectified by the second rectifier circuit 14 and converted into a pulsating current voltage. This pulsating current voltage is amplified by the second amplifier 15, is then supplied to the inverting input terminal of the second operational amplifier 18, is inverted and amplified, and is then smoothed by the second capacitor 20 and the like to become the AGC voltage. It is converted and applied to the gain control terminal of the second electronic volume IC 13.

In this case, the second operational amplifier 18 operates differently from the operation of the first operational amplifier 11 already described, and the operation executed by the second operational amplifier 18 will be described below. An input / output characteristic of the operational amplifier 18, that is, an example of the relationship between the pulsating current voltage supplied to the inverting input terminal and the output voltage output from the output terminal will be described with reference to FIG. However, for convenience of explanation, the power supply voltage of the second operational amplifier 18 is 12V on the positive side, −0V on the negative side, its amplification gain is 1000 times, the output voltage of the second bias power supply 17 is 4.5V, and the diode 19 is It is ideal and its forward voltage drop is 0V.

Now, when the pulsating current voltage supplied to the other end of the second input resistor 16 connected in series with the inverting input terminal of the second operational amplifier 18 is less than 4.5 V, for example, 4.0.
Assuming V.V., the inverting input terminal and the non-inverting input terminal of the second operational amplifier 18 are 4.0V and 4.V, respectively.
When a voltage of 5V is applied, the second operational amplifier 18 amplifies the difference voltage 0.5V between these voltages by an amplification gain of 1000 times the theoretical value, and theoretically outputs 500V to the output terminal of the second operational amplifier 18.
An output voltage of V will be generated. However, the output voltage of the second operational amplifier 18 is 4.
Since it does not exceed 5V, the second operational amplifier 18 is saturated and an output voltage of 4.5V is generated at its output terminal. Since this output voltage is supplied to the inverting input terminal via the diode 19, 4.5V is applied to each of the inverting input terminal and the non-inverting input terminal of the second operational amplifier 18 and the output terminal. It will be in a state of being. This voltage state always occurs when the pulsating current voltage supplied to the inverting input terminal of the second operational amplifier 18 is 4.5 V or less, and at that time, the maximum AGC voltage of 4.5 V is the second AG voltage.
It is supplied from the C feedback loop to the second electronic volume IC 13.

On the other hand, if the pulsating voltage supplied to the other end of the second input resistor 16 connected in series with the inverting input terminal of the second operational amplifier 18 exceeds 4.5V, for example, 5.0V.
Assuming that the voltage rises to 5.0V, the inverting input terminal and the non-inverting input terminal of the second operational amplifier 18 are 5.0V each.
And a voltage of 4.5V is applied to the second operational amplifier 18, and the differential voltage of those voltages, -0.5V, is amplified by an amplification gain of 1000 times the theoretical voltage of -500V at the output terminal of the second operational amplifier 18. Output voltage will be generated. Here again, the output voltage of the second operational amplifier 18 does not exceed the power supply voltage 0V on the negative side thereof, so that the second operational amplifier 18 is in the saturated state as in the previous case, and the output terminal thereof has 0V. Output voltage is generated. When this output voltage is applied to the diode 19, the diode 19 is in a reverse bias state, so that the voltage states of the inverting input terminal and the non-inverting input terminal of the second operational amplifier 18 and the output terminal are 5. It becomes 0V, 4.5V, and 0V.
At that time, the minimum AGC voltage of 0 V is supplied to the second electronic volume IC 13 from the second AGC feedback loop.

As described above, the input / output characteristics of the second operational amplifier 18 are as shown in FIG. 4 if the pulsating current voltage is in the range of 0V to 4.5V.
Has a constant value of 4.5V, but when the pulsating current voltage exceeds 4.5V, the output voltage of the second operational amplifier 18 gradually decreases from 4.5V as it exceeds 4.5V. The output voltage of the second operational amplifier 18 is as follows.
The AGC voltage is supplied to the second electronic volume IC 13.

Then, as shown in FIG. 3C, it takes a relatively long time after the amplitude of the audio intermediate output signal input to the fast response AGC circuit 2 temporarily increases at time t ₀ . The amplitude is made constant and at time t
_{In 1} , if the amplitude is temporarily reduced and then the amplitude is made constant for a relatively long time, the second operational amplifier 18 responds to such an audio intermediate output signal. As shown in FIG. 3D, the amplitude is the attack time t _a2 from time t ₀ (where t _a1 >> t _a2 ).
The output voltage is gradually decreased during the period, and is gradually increased during the decay time t _d2 (where t _d1 >> t _d2 ) from the time t ₂ , and the output voltage that is stabilized during the remaining period is generated. Then, this output voltage is supplied to the second electronic volume IC 5 as an AGC voltage. As a result, the output of the fast response AGC circuit 2 temporarily increases in amplitude at time t ₀ and then becomes constant within a relatively short time, as shown in FIG. Then, at time t ₁ ,
After the amplitude is temporarily reduced, an audio output signal whose amplitude is made constant is obtained in the same manner as before, taking a relatively long time.

At this time, the input / output characteristic of the fast response AGC circuit 2 is that the input signal level is as shown in FIG.
From the input signal level point (-A) to the input signal level point B slightly exceeding the reference signal level point O, the output signal level increases sequentially with the increase of the input signal level,
Beyond the signal level point B, the output signal level becomes constant regardless of the increase of the input signal level.

This constant output signal level is set to be higher by 3 db than the output signal level of the flat portion of the low speed response AGC circuit 1 shown in FIG. 2 (a). . The reason is that it is preferable in terms of audibility, and for example, when the level difference between the two output signals is set to 0, when the amplitude of the input audio signal changes abruptly, the listening sound becomes less tight, This is because the strength and weakness of the sound will be lost, and when the level difference between the two output signals is set to be considerably larger than 3 db, the original AGC function will be lost or a popping sound will be produced.

As described above, according to this embodiment, the low-speed response AGC circuit 1 and the high-speed response AGC circuit 2 which are connected in cascade are provided, and the low-speed response AGC circuit 1 in the preceding stage is adapted to abrupt amplitude change of the input audio signal. The high-speed response AGC circuit 2 in the subsequent stage enhances the followability of the portion that cannot be followed, and the dynamic range of the high-speed response AGC circuit 2 may be half or less of the dynamic range of the low-speed response AGC circuit 1. AGC which can follow the amplitude change of the input audio signal at high speed without causing overshoot in
A circuit can be realized.

[0038]

As described above, according to the present invention,
Cascaded low-speed response AGC circuit 1 and high-speed response AGC
The AGC circuit using the circuit 2 is used to
Since the GC is performed and the dynamic range of the AGC circuit is greatly expanded as compared with the known AGC circuit of this type, even if an audio signal whose amplitude sharply increases is input, There is an effect that it is possible to obtain an audio output signal whose amplitude is substantially constant within a relatively short time without generating a silent state due to overshoot of the AGC voltage or a clicking sound accompanying a delay in AGC followability.

Further, according to the present invention, when an audio signal whose amplitude sharply increases or decreases is input, an audio signal of slightly large or slightly small amplitude is initially output, and then an audio signal of a predetermined amplitude is output. Since the signal is output, a portion where the amplitude of the input audio signal changes abruptly, despite having the AGC function,
There is an effect that the reproduced sound can be clearly identified when it is heard.

[Brief description of drawings]

FIG. 1 is a circuit configuration diagram showing an embodiment of an AGC circuit of an audio device according to the present invention.

FIG. 2 is a characteristic diagram showing input / output signal transmission characteristics of the low speed response AGC circuit and the high speed response AGC circuit shown in FIG.

FIG. 3 is a waveform diagram showing an example of changes in signal waveforms and voltage states of various parts in the embodiment shown in FIG.

4 is a characteristic diagram showing an example of a relationship between a pulsating current voltage value supplied to an inverting input terminal of the second operational amplifier shown in FIG. 1 and an output voltage output from an output terminal.

FIG. 5 is a circuit configuration diagram showing an example of an AGC circuit of a known audio device.

6 is a characteristic diagram showing an example of a relationship between an AGC voltage supplied to each electronic volume IC and an audio signal attenuation amount in the known AGC circuit shown in FIG.

FIG. 7 is a characteristic diagram showing an example of changes in signal waveforms and voltage states of respective parts in the known AGC circuit.

[Explanation of symbols]

1 Slow AGC control response characteristic first AGC circuit (slow response AGC circuit) 2 Fast AGC control response characteristic second AGC circuit (fast response AGC circuit) 3 Audio signal input terminal 4 Audio signal output terminal 5 First Electronic volume IC (first audio signal level control means) 6 voltage regulator 7 first rectifier circuit 8 first amplifier 9 first input resistor 10 first bias power supply 11 first operational amplifier 12 first capacitor 13 second electronic volume IC (second audio signal level control means) 14 second rectifier circuit 15 first amplifier 16 second input resistor 17 second bias power supply 18 second operational amplifier 19 diode 20 second Capacitors

Claims (4)

[Claims] 1. A slow AGC comprising first audio signal level control means coupled to a first AGC feedback loop.
The first AGC circuit having the control response characteristic and the second AGC circuit having the second audio signal level control means to which the second AGC feedback loop is coupled are provided, and the second AGC circuit having the fast AGC control response characteristic is provided. AGC circuit and the second AGC
The circuit is an AGC circuit for audio equipment, wherein the circuit is cascade-connected to an audio signal path. 2. The first AGC feedback loop includes a first operational amplifier having first and second input terminals and an output terminal, and a first input resistor connected in series to the first input terminal. A first bias power supply connected between the first input terminal and the output terminal and a second capacitor connected between the second input terminal and the ground;
The GC feedback loop includes a second operational amplifier having first and second input terminals and an output terminal, a second input resistor connected in series with the first input terminal, the first input terminal and the output. 2. A second capacitor and a diode connected in parallel with the terminal, and a second bias power supply connected between the second input terminal and ground. AGC circuit of audio equipment. 3. The output voltage of the first bias power supply is
The output voltage of the second bias power supply is set so as to be a value approximately in the middle of the AGC voltage applied to the first audio signal level control means, and the output voltage of the second bias power supply is set to the audio signal gain of the second audio signal level control means. Is set to be approximately equal to the AGC voltage that maximizes the value of the first capacitor, and the product of the capacitance value of the first capacitor and the resistance value of the first input resistor is equal to the capacitance value of the second capacitor and the second capacitor. 3. The AGC circuit for audio equipment according to claim 2, wherein the AGC circuit is set to be larger than the product of the input resistance and the resistance value. 4. The first audio signal level control means and the second audio signal level control means are constituted by a variable gain amplifier or a variable attenuator. An AGC circuit of the audio device according to claim 1.