JP4811182B2 - Audio device gain switching method and device - Google Patents

Description

  The present invention relates to a gain switching method and apparatus for an audio apparatus.

  In the audio device, a built-in microphone and a mixing microphone jack with an interlocking switch are connected to a common amplifier circuit having an amplifier and a volume adjusting volume, and the interlocking switch is activated by inserting and removing the mixing microphone into the jack. The acoustic signal from the built-in microphone or mixing microphone is selectively input to the amplifier, and only when the mixing microphone is inserted, the acoustic signal from the amplifier is output via the volume to switch the gain of the amplifier circuit. There is something like that (see, for example, Patent Document 1).

  By the way, in the audio apparatus, a signal that becomes noise is generated at the time of gain switching, but no means for preventing the output of this signal is provided, and an improvement in this respect has been desired.

Japanese Utility Model Publication No. 7-34532

  An object of the present invention is to provide a gain switching method for an audio apparatus and its switching apparatus that can prevent the output of a signal that becomes noise generated at the time of gain switching.

In order to achieve the above object, the gain switching method of the audio device according to the present invention is characterized in that the first and second input terminals to which an acoustic signal is input are connected to a common amplifier circuit, and the second input terminal The external output terminal can be freely connected and disconnected, and the second input terminal is provided with an interlocking switch for cutting off the input of the acoustic signal from the first input terminal to the amplifier circuit when the external output terminal is connected. In the audio apparatus, when the external output terminal is connected to the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off, and then the gain of the amplifier circuit is controlled by the gain switching circuit connected to the input side of the amplifier circuit. After the switching, the cutoff of the acoustic signal input from the second input terminal to the amplifier circuit is released, and thereafter the cutoff of the output of the acoustic signal from the amplifier circuit is released. When the external output terminal is separated from the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off, and then the gain of the amplifier circuit is switched by the gain switching circuit connected to the input side of the amplifier circuit. After that, the input of the acoustic signal from the second input terminal to the amplifier circuit is cut off, and the switching of the output of the acoustic signal from the amplifier circuit to the first input terminal is canceled in the above order from switching to the amplifier circuit input side. is there.
Further, the gain switching device of the audio device according to the present invention is characterized in that the first and second input terminals to which the acoustic signal is input are connected to a common amplifier circuit, and the external output terminal is connected to the second input terminal. In an audio device that is separable and includes a changeover switch that blocks input of an acoustic signal from the first input terminal to the amplifier circuit when an external output terminal is connected to the second input terminal. A gain switching circuit that switches the gain of the amplifier circuit is connected to the input side of the circuit by connecting / disconnecting the external output terminal to the second input terminal, and the output of the acoustic signal from the amplifier circuit is shut off at the subsequent stage of the amplifier circuit A first acoustic mute circuit is provided, and a second acoustic mute circuit for blocking the input of an acoustic signal from the second input terminal to the amplifier circuit is disposed in a previous stage of the amplifier circuit, and a control means is provided. System Means, A. When the external output terminal is connected to the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off by the first acoustic mute circuit, and then the gain switching circuit is activated. After this operation, the second acoustic mute circuit is activated. Thus, the cutoff of the input of the acoustic signal from the second input terminal to the amplifier circuit is released, and thereafter the cutoff of the output of the acoustic signal from the amplifier circuit by the first acoustic mute circuit is released. B. When the external output terminal is separated from the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off by the first acoustic mute circuit, and then the gain switching circuit is activated. After this operation, the second acoustic mute circuit is activated. According to the above, the input of the acoustic signal from the second input terminal to the amplifier circuit is cut off and the output of the acoustic signal from the amplifier circuit by the first acoustic mute circuit is switched from the first input terminal to the amplifier circuit input side. It is in the point which cancels in the order.
Note that the gain switching circuit may increase the gain of the amplifier circuit when the external output terminal is connected to the second input terminal as compared with the separation.
There may also be provided first and second acoustic mute driving circuits which are controlled by the control means to operate the first and second acoustic mute circuits.
Further, the amplifier circuit may include an operational amplifier that is a non-inverting amplifier, and the gain switching circuit may be able to intermittently connect the inverting input terminal of the operational amplifier to the ground.

  According to the present invention, it is possible to satisfactorily prevent the output of a signal that becomes noise generated at the time of gain switching, and since the gain switching circuit is connected to the input side of the amplifier circuit, the signal is input to the first and second input terminals. Even if the difference in the output impedance of the acoustic source is large, there is no risk of problems.

  Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings. As shown in FIG. 1, the audio apparatus includes first and second input terminals 1 and 2 and R / L channel amplifier circuits 3 and 4. And a gain switching circuit 5, first and second acoustic mute circuits 6 and 7, first and second acoustic mute driving circuits 8 and 9, a selector / volume 10, a microcontroller 11 and the like.

  The first input terminal 1 is connected to an acoustic signal input line so that it can be connected and separated, and has R / L channel input terminals 1R and 1L.

  The second input terminal 2 constitutes a mixing microphone jack (connected portion), and a plug (not shown) of a mixing microphone (not shown) exemplified as an external output terminal can be freely inserted and removed (intermittently connected / disconnected). R / L channel input terminals 2R, 2L, a ground terminal T1, a detection terminal T2 connected to the microcontroller 11 and detecting plug connection, interlock switches SWL, SWR, etc. Have The input terminals 2R and 2L and the ground terminal T1 are connected to and separated from the output terminals and the ground terminal of the plug of the mixing microphone so that an acoustic signal is input to the input terminals 2R and 2L. The ground terminal T1 is also connected to the first input terminal 1. The detection terminal T2 detects a connection of a mixing microphone plug and outputs a low-level detection signal, and is connected to the microcontroller 11. A positive voltage + VDD is applied to this connection point via a resistor R24, and this connection point is also connected to the gain switching circuit 5 via a resistor R25. A connection point between the resistor R25 and the gain switching circuit 5 is grounded through an electrolytic capacitor C11. Each interlock switch SWR, SWL is always turned on, and is turned off when the plug of the mixing microphone is connected. The contact T3 connected to each input terminal 1R, 1L of the first input terminal 1 T5, contacts T4 and T6 which can be intermittently connected to these contacts T3 and T5, and interlocking portions 13 and 14 which come into contact with the plug and separate the contacts T3 and T5 from the contacts T4 and T6 when the plug is connected. .

  The R / L channel amplifier circuits 3 and 4 amplify an acoustic signal from the mixing microphone, and have operational amplifiers Q13 and Q21, negative feedback resistors R26 and R44, and capacitors C11 and C20. The operational amplifiers Q13 and Q21 are non-inverting amplifiers, and input terminals 1R and 1L of the first input terminal 1 are connected to these non-inverting input terminals via resistors R31 and R43 and capacitors C15 and C19. . The connection point between the resistors R31 and R43 and the capacitors C15 and C19 is grounded via the resistors R33 and R38, and the connection point between the capacitors C15 and C16 and the operational amplifiers Q13 and Q21 is grounded via the resistors R32 and R40. Input terminals 2R and 2L of the second input terminal 2 are connected to the non-inverting input terminals of the operational amplifiers Q13 and Q21 via electrolytic capacitors C13 and C17, a second acoustic mute circuit 7, and electrolytic capacitors C12 and C15. . A connection point between the second input terminal 2 and the electrolytic capacitors C13 and C17 is grounded via resistors R29 and R37. A connection point between the second acoustic mute circuit 7 and the electrolytic capacitors C12 and C16 is grounded via resistors R33 and R38. The gain switching circuit 5 is connected to the inverting input terminals of the operational amplifiers Q13 and Q21 via resistors R30 and R45, and between the inverting input terminal and the output terminal of the operational amplifiers Q13 and Q21, resistors R26 and R44 and a capacitor C11. , C20 are interposed in parallel. The output terminals of the operational amplifiers Q13 and Q21 are connected to the selector / volume 10 via electric field capacitors C14 and C18 and resistors R27, R28, R41 and R42. A positive voltage + VDD and a negative voltage −VDD are applied to the operational amplifiers Q13 and Q21.

  The gain switching circuit 5 switches the gains of the amplification circuits 3 and 4, and when the acoustic signal is input from the first input terminal 1 to the amplification circuits 3 and 4, the gain is set to 1 and is amplified from the second input terminal 2. When an acoustic signal is input to the circuits 3 and 4, the gain is set to a predetermined value larger than 1, and a PNP transistor Q11 with a built-in resistor and two NPN transistors Q14 and Q19 with a built-in resistor are provided. Have. The emitter of the PNP transistor Q11 is connected to the positive voltage + VDD via the resistor R23, the base is connected to the resistor R25, and the collector is connected to the bases of the NPN transistors Q14 and Q19. The emitters of both NPN transistors Q14 and Q19 are grounded, and the collectors are connected to the inverting input terminals of the operational amplifiers Q13 and Q21. The resistor R25 and the electrolytic capacitor C11 constitute a delay circuit that delays the operation of the gain switching circuit 5 for a predetermined time determined by their time constant.

  The first acoustic mute circuit 6 blocks input of acoustic signals from the amplifier circuits 3 and 4 to the selector / volume 10 and includes four NPN transistors Q15 to Q18 with built-in resistors. The emitters of the transistors Q15 to Q18 are grounded, the base is connected to the first acoustic mute driving circuit 8, and the negative voltage -VDD is applied to the base via the resistor R35. The collectors of the transistors Q15 and Q17 are connected to the connection point of the resistor R27 or resistor R41 and the selector / volume 10. The collectors of the transistors Q16 and Q18 are connected to the connection point of the resistors R27 and R28 or the connection point of the resistors R41 and R42.

  The first acoustic mute driving circuit 8 operates the first acoustic mute circuit 6 and is connected to the microcontroller 11.

  The second acoustic mute circuit 7 blocks the input of acoustic signals from the second input terminal 2 to the amplifier circuits 3 and 4, and has two N-channel MOS field effect transistors Q12 and Q20 of a built-in diode type. The sources of the transistors Q12 and Q20 are connected to the electrolytic capacitors C13 and C17, the drains are connected to the electrolytic capacitors C12 and C16, the gates are connected to the second acoustic mute driving circuit 9, and the negative voltage -VDD is applied to the resistor R36. Is applied through.

  The second acoustic mute driving circuit 9 operates the second acoustic mute circuit 7 and is connected to the microcontroller 11.

  The selector / volume 10 selects an input acoustic signal and adjusts its volume.

  The microcontroller 11 (microcomputer, system controller, control means, control device) receives the detection signal from the detection terminal T2, and controls the first and second acoustic mute driving circuits 8, 9 and the selector / volume 10. A central processing circuit (CPU) (not shown) for performing information processing, a read only memory (ROM) (not shown) in which a control program is stored, and a random access memory (RAM) for storing variables necessary for processing ) (Not shown). The microcontroller outputs first and second mute control signals to the first and second acoustic mute driving circuits 8 and 9, and the first and second acoustic mute driving circuits 8 and 9 output the first and second acoustic mute driving circuits 8. The first and second mute signals are output to the circuits 6 and 7, and the circuits 6 and 7 are operated.

  Next, a specific description will be given based on the waveform diagrams shown in FIGS. 2 and 3, the high level of gain control indicates a case where the gain is 1, and the low level indicates a predetermined value of 1 or more.

  When the acoustic signal input line (or the built-in microphone of the audio apparatus) is connected only to the first input terminal 1 and the mixing microphone is not connected to the second input terminal 2, as shown in FIG. The detection signal from the detection terminal T2 is at a high level, the transistors Q11, Q14, Q19 of the gain switching circuit 5 are all off, and the inverting input terminals of the operational amplifiers Q13, Q21 are not grounded. Therefore, the amplification circuits 3 and 4 do not perform amplification and the gain is 1.

  Further, by the control of the first acoustic mute driving circuit 8 by the microcontroller 11, the first mute signal output from the first acoustic mute driving circuit 8 is low level, and the transistors Q15 to Q18 of the first acoustic mute circuit 6 are in the off state. Thus, an acoustic signal can be output from the amplifier circuits 3 and 4 to the selector / volume 10. The second acoustic mute driving circuit 9 controls the second acoustic mute driving circuit 9 to output a second mute signal of a high level from the second acoustic mute driving circuit 9 to the second acoustic mute circuit 7. The transistors Q12 and Q20 are turned on, and an acoustic signal from the first input terminal can be input to the operational amplifiers Q13 and Q21.

  In this state, when an acoustic signal is input to the first input terminal 1, the acoustic signal is output to the selector / volume 10 via the amplifier circuits 3 and 4, but the acoustic signal is amplified by the amplifier circuits 3 and 4. Instead, the acoustic signal input to the first input terminal 1 is output to the selector / volume 10 as it is.

  Next, when the plug of the mixing microphone is connected to the second input terminal 2, the contacts T3 to T6 of the interlocking switches SWR and SWL are separated by the contact between the plug and the interlocking portions 13 and 14 of the interlocking switches SWR and SWL. The input of the acoustic signal from the first input terminal 1 to the amplifier circuits 3 and 4 is blocked.

  Further, the detection terminal T2 detects the connection of the plug, and outputs a low level detection signal as shown in FIG. In response to this input, by the control of the first acoustic mute driving circuit 8 by the microcontroller 11, only a predetermined time (first mute setting time) before and after the gain of the amplifier circuits 3 and 4 is switched as follows. The high-level first mute signal is output from the first acoustic mute driving circuit 8, and the transistors Q15 to Q18 of the first acoustic mute circuit 6 are turned on, and the amplifier circuits 3 and 4 to the selector / volume 10 The output of the acoustic signal is cut off.

  Further, as shown in FIG. 2, a low level detection signal is input to the base of the transistor Q11 of the gain switching circuit 5. As a result, the transistor Q11 is turned on, the transistors Q14 and Q19 are also turned on, and the inverting input terminals of the operational amplifiers Q13 and Q21 of the amplifier circuits 3 and 4 are grounded via the transistors Q14 and Q19. 3 and 4 operate as a non-inverting amplifier circuit, and the gain is switched to a predetermined value of 1 or more. This switching is delayed from the detection by a predetermined time determined by the time constant of the resistor R25 and the electrolytic capacitor C11. Thus, after the first acoustic mute circuit 6 cuts off the output of the acoustic signal from the amplifier circuits 3 and 4 to the selector / volume 10, the gains of the amplifier circuits 3 and 4 are switched.

  Further, the second mute signal output from the second acoustic mute driving circuit 9 by the control of the second acoustic mute driving circuit 9 by the microcontroller 11 within the first mute setting time after the operation of the gain switching circuit 5. Becomes high level. As a result, the transistors Q12 and Q20 of the second acoustic mute circuit 7 are turned on, and the acoustic signal input from the second input terminal 2 to the amplifier circuits 3 and 4 is released. Thereafter, under the control of the first acoustic mute driving circuit 8 by the microcontroller 11, a low level first mute signal is output from the first acoustic mute driving circuit 8, and the transistors Q15 to Q18 of the first acoustic mute circuit 6 are turned off. Then, the output of the acoustic signal from the amplifier circuits 3 and 4 to the selector / volume 10 is released.

  When an acoustic signal is input to the second input terminal 2 in the above state, the acoustic signal is amplified by the amplification circuits 3 and 4 and output to the selector / volume 10.

  Next, when the plug of the mixing microphone is separated from the second input terminal, the plug is separated from the interlocking portions 13 and 14 of the interlocking switches SWR and SWL, and the contacts T3 to T6 of the interlocking switches SWR and SWL are in contact with each other. An acoustic signal can be input from the 1 input terminal 1 to the amplifier circuits 3 and 4.

  Further, due to the separation of the plug, as shown in FIG. 3, the detection signal input from the detection terminal T2 to the microcontroller 11 becomes high level. As a result, the first acoustic mute driving circuit 8 is controlled by the microcontroller 11 so that the gains of the amplifying circuits 3 and 4 are changed for the first time only after a predetermined time (first mute setting time) before and after switching. A high level first mute signal is output from the acoustic mute driving circuit 8 and the transistors Q15 to Q18 of the first acoustic mute circuit 6 are turned on, and the acoustic signals from the amplifier circuits 3 and 4 to the selector / volume 10 are output. Is shut off.

  Also, as shown in FIG. 3, a high level detection signal is input to the base of the transistor Q11 of the gain switching circuit 5. Thereby, the transistor Q11 is turned off, the transistors Q14 and Q19 are also turned off, and the grounded state of the inverting input terminals of the operational amplifiers Q13 and Q21 of the amplifier circuits 3 and 4 is released. Therefore, the amplification circuits 3 and 4 do not perform amplification and the gain is 1. This switching is delayed by a predetermined time determined by the time constant of the resistor R25 and the electrolytic capacitor C11 after the detection signal becomes high level. Thus, after the first acoustic mute circuit 6 cuts off the output of the acoustic signal from the amplifier circuits 3 and 4 to the selector / volume 10, the gains of the amplifier circuits 3 and 4 are switched.

  Further, the second mute signal output from the second acoustic mute driving circuit 9 by the control of the second acoustic mute driving circuit 9 by the microcontroller 11 within the first mute setting time after the operation of the gain switching circuit 5. Becomes low level. Thereby, the transistors Q12 and Q20 of the second acoustic mute circuit 7 are turned off, and the input of the acoustic signal from the second input terminal 2 to the amplifier circuits 3 and 4 is cut off. Thereafter, under the control of the first acoustic mute driving circuit 8 by the microcontroller 11, a low level first mute signal is output from the first acoustic mute driving circuit 8, and the transistors Q15 to Q18 of the first acoustic mute circuit 6 are turned off. Then, the output of the acoustic signal from the amplifier circuits 3 and 4 to the selector / volume 10 is released.

  When an acoustic signal is input to the first input terminal 1 in the above state, the acoustic signal is not amplified by the amplifier circuits 3 and 4 and the acoustic signal input to the first input terminal 1 is output to the selector / volume 10 as it is. Is done.

  As described above, the first and second acoustic mute circuits 6 and 7 can satisfactorily prevent the acoustic signal, which is noise generated when the gains of the amplifier circuits 3 and 4 are switched, from being output to the selector / volume 10.

  In the above-described embodiment, the first and second input terminals are single, but one or both may be addressed to a plurality. In the above embodiment, the first and second acoustic mute circuits are provided, but only one of them may be provided. Further, in the above embodiment, the gain of the amplifier circuit is switched to 1 and a predetermined value, but may be switched to a plurality of predetermined values.

It is a circuit diagram showing an example of an embodiment of the invention. It is a wave form diagram which shows the signal level etc. of each place of FIG. It is a wave form diagram which shows the signal level etc. of each place of FIG.

Explanation of symbols

1, 2 First and second input terminals 3, 4 Amplifier circuit 5 Gain switching circuit 6, 7 First and second acoustic mute circuit 8, 9 First and second acoustic mute drive circuit 11 Microcontroller 11
Q13, Q21 operational amplifier

Claims (5)

The first and second input terminals to which the acoustic signal is input are connected to a common amplifier circuit,
An external output terminal can be freely connected to and disconnected from the second input terminal,
In an audio device provided with an interlocking switch that cuts off an acoustic signal input from the first input terminal to the amplifier circuit when an external output terminal is connected to the second input terminal.
When the external output terminal is connected to the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off, and then the gain of the amplifier circuit is switched by the gain switching circuit connected to the input side of the amplifier circuit. After that, the input blocking of the acoustic signal from the second input terminal to the amplifier circuit is canceled, and then the blocking of the output of the acoustic signal from the amplifier circuit is canceled,
When the external output terminal is separated from the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off, and then the gain of the amplifier circuit is switched by the gain switching circuit connected to the input side of the amplifier circuit. after block the input of the acoustic signal to the amplifier circuit from the second input terminal, Thereafter, the gain switching method of an audio device which unblock the output of the audio signal from the amplifier circuit. The first and second input terminals to which the acoustic signal is input are connected to a common amplifier circuit,
An external output terminal can be freely connected to and disconnected from the second input terminal,
In the audio apparatus provided with a changeover switch for cutting off the input of the acoustic signal from the first input terminal to the amplifier circuit when the external output terminal is connected to the second input terminal,
On the input side of the amplifier circuit,
A gain switching circuit that switches the gain of the amplifier circuit is connected by connecting / disconnecting the external output terminal to the second input terminal,
A first acoustic mute circuit that shuts off the output of the acoustic signal from the amplifier circuit is disposed after the amplifier circuit,
A second acoustic mute circuit for blocking the input of the acoustic signal from the second input terminal to the amplifier circuit is disposed in the front stage of the amplifier circuit,
Control means are provided,
The control means
A. When the external output terminal is connected to the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off by the first acoustic mute circuit, and then the gain switching circuit is activated. The circuit cancels the blocking of the input of the acoustic signal from the second input terminal to the amplifier circuit, and then cancels the blocking of the output of the acoustic signal from the amplifier circuit by the first acoustic mute circuit,
B. When the external output terminal is separated from the second input terminal, the output of the acoustic signal from the amplifier circuit is cut off by the first acoustic mute circuit, and then the gain switching circuit is activated. in accordance to block the input of the acoustic signal to the amplifier circuit from the second input terminal, Thereafter, the first acoustic muting circuit, to cancel the interruption of the output of the audio signal from the amplifier circuit, the gain switching of the audio device apparatus.   3. The gain switching device for an audio device according to claim 2, wherein the gain switching circuit makes the gain of the amplifier circuit when the external output terminal is connected to the second input terminal larger than that at the time of separation.   4. The gain switching device for an audio apparatus according to claim 2, further comprising first and second acoustic mute driving circuits controlled by the control means to operate the first and second acoustic mute circuits. The amplifier circuit has an operational amplifier to be a non-inverting amplifier,
The gain switching device for an audio device according to any one of claims 2 to 4, wherein the gain switching circuit enables the inverting input terminal of the operational amplifier to be intermittently connected to the ground.

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