KR900007986Y1 - Pop Noise Canceling Circuit of Audio Signal - Google Patents

Abstract

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Description

Pop Noise Canceling Circuit of Audio Signal

1 is a circuit diagram of the present invention.

2 is a system reset signal and power control signal waveform diagram.

* Explanation of symbols for main parts of the drawings

10: Digital Audio Processing Unit (APU) 20: Low Pass Filter

30: amplifier 40: switching unit

1-3: Input terminal R ₁ -R ₆ : Resistance

C ₁ -C ₄ : Capacitor Q ₁ , Q ₂ : Transistor

SP ₁ , SP ₂ : Left and right channel speakers B ^* : Power

ST: Standby Power

The present invention is a remote control (REMOCON) type television, a pop generated by a transient phenomenon when the power is "on-off" in the audio signal output terminal for outputting the digital audio signal of the digital audio processing unit (APU) The present invention relates to a pop noise canceling circuit of an audio signal that is designed to remove noise.

The digital audio signal output of the remote control TV converts the pulse width modulated digital audio signal generated by the APU into an analog audio signal in a low pass filter and then amplifies it in an amplifier and outputs it to the sputter. In the audio signal output, the cause of pop noise when the power is "on-off" is firstly a change in the power voltage applied to the pull up resistor connected to the APU output terminal, which is amplified as it is, and output to the speaker. Secondly, the pop-up noise was generated at the output because the current at the terminal that the APU used as the volume reference for the output changed rapidly during power on and off.

Conventionally, in order to eliminate the pop noise as described above, a power delay unit using multiple transistors is connected to an amplifier that amplifies an audio signal, and when the power is "on", the power supply input to the amplifier is delayed and the power is "off". In this case, the power remaining in the amplifier is quickly discharged to remove the pop noise generated when the power is “on-off”. However, as the audio output is increased, a pull up resistor must be connected to the output side of the APU. "The removal of pop noise due to rapid discharge has a disadvantage in that pop noise is not effectively removed due to the limitation of discharge time constant, and power is consumed unnecessarily due to the voltage drop generated in the power delay part that delays the amplifier input power. There was a disadvantage.

As described above, in the digital audio signal processing of a remote control TV, the power-on pull-up part of the APU output side and the volume reference stage of the APU, which are the main causes of pop noise, are removed, and the " on-off " "It eliminates pop noise that occurs when the APU output stage is pulled up to the standby power supply, and the APU volume reference stage is controlled using a system reset signal to eliminate pop noise.

Thus, in the digital audio signal processing of the remote control TV, the present invention for the purpose of removing the pop noise generated when the power "on-off" will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of the present invention, after the digital audio signal of the APU 10 is converted into an analog audio signal by the low pass filter 20, the left and right channel spurs SP ₁ (SP ₂ ) through the amplifier 30. In the digital audio signal output circuit configured to be output to the power supply, the standby power supply (ST) is applied to the pull-up resistor (R ₁ ) (R ₂ ) of the low pass filter (20) and switched to a system reset signal. The driving of transistors Q ₁ and Q ₂ of the unit 40 is controlled to control the supply of power B ^* applied to the volume reference terminals V and R of the APU 10.

That is, the digital audio signal applied from the input terminals 1 and 2 is signal processed and output through the APU 10, and the digital audio signal output from the APU 10 is a pull-up resistor R ₁ (R ₂ ). After converting into an analog audio signal in the low pass filter 20 consisting of and a condenser (C ₁ ) (C ₂ ) and through the DC removal capacitor (C ₃ ) (C ₄ ) and the amplifier 30 (SP ₁ ) ( In the digital audio signal output circuit configured to be output to SP ₂ ), the standby power supply ST is applied to the pull-up resistor R ₁ and R ₂ of the low pass filter 20, and the input terminal 3 is connected to the output terminal 3. It is configured to control the driving of the transistors Q ₁ and Q ₂ of the switching unit 40 to which the standby power source ST is applied as a system reset signal applied to the APU (APU) by the operation of the switching unit 40. It is configured to control the power supply (B ^* ) applied to the volume reference stage (VR) of 10).

At this time, the APU 10 determines the amplification degree by the power supply B * applied to the volume reference stage VR, and the system reset signal is several hundred msec after powering on as shown in FIG. A signal that is applied from the microcomputer to a low level before hundreds of mesc at high level and power on.

Before describing the effects of the present invention configured as described above, the system reset signal and the power control signal generation shown in the wave diagram of FIG. 2 will be described.

The system reset signal as shown in FIG. 2 (a) and the power control signal as in power B as shown in FIG. 2 (b) are signals generated by the microcomputer. Recognizing this, a power control signal as shown in FIG. 2 (b) is applied to a relay that controls the main power supply of the system to a high level so that power is supplied to the system by operating the relay, and the power switch is "off". Recognizes this and outputs the power control signal at a low level after several hundred msec, and outputs the power control signal as shown in (b) of FIG. Will be.

And a system reset signal as in FIG. 2 (a) outputs a high level several hundred msec after turning on the power switch and several hundred msec when the power control signal falls to low level when the power switch is turned “off”. Previously, the output will be low level, so the system will perform normal operation while the system reset signal is output to the high bell.

That is, the microcomputer outputs the power control signal at the high level at the same time as the "on" of the power switch, and then outputs the system reset signal to the high level after several hundred msec, and the system reset signal at the same time as the "off" of the power switch. After several hundred msec, the power control signal is output at low level.

Therefore, the system is powered on when the power control signal is output at high level as shown in (b) of FIG. 2 but is normally operated when the system reset signal is output at high level as shown in (a) of FIG. Will be

It looks at the effect of the present invention.

The digital audio signal applied to the input terminals 1 and 2 is processed by the APU 10 according to the determination of the amplification degree, and is then applied to the low pass filter 20 to be converted into an analog audio signal.

That is, the digital audio signal of the APU 10 is an analog audio signal by the charge-discharge time constant of the pull-up resistor R ₁ (R ₂ ) and the capacitor C ₁ (C ₂ ) to which the standby power source ST is applied. After the conversion to the DC removal capacitor (C ₃ ) (C ₄ ) through the amplifier 30 is amplified and output to the left and right channel speakers (SP ₁ ) (SP ₂ ).

At this time, conventionally, the pull-up resistor (R ₁ ) (R ₂ ) by applying the power (B ^* ) applied when the power control signal as shown in (b) of FIG. Pop-up noise is generated by the transients generated during the output to the speaker SP ₁ (SP ₂ ) through the amplifier 30 as it is, but in the present invention, the power cord may be plugged into the pull-up resistor R ₁ (R ₂ ). At this time, even when the power switch is not turned "on", the standby power supply ST supplied to the microcomputer is applied to perform a stable operation regardless of the power "on-off", thereby preventing pop noise.

At this time, the current of the standby power source ST flowing through the pull-up resistor R ₁ (R ₂ ) is extremely weak, so that the overall standby power consumption is hardly affected.

Therefore, by applying the standby power supply ST to the pull-up resistors R ₁ and R ₂ of the low pass filter 20, the pop noise generated by the change of the power supply voltage applied to the conventional pull-up resistor can be removed. You can listen to this unmixed audio.

On the other hand, in the APU 10, the amplification degree is determined according to the voltage level applied to the volume reference terminal (V. R), and the output volume is adjusted. When the volume reference terminal (V. R) voltage is high, the amplification degree becomes large and the output becomes large. If the voltage applied to the volume reference terminal (V. R) is low, the amplification degree is low, the output is small.

Conventionally, when the power B ^* is applied to the volume reference stage VR as it is, pop noise is generated on the output side due to a transient phenomenon when the power is “on-off”. However, in the present invention, as shown in FIG. The same system reset signal was used to eliminate pop noise.

At this time, if the current applied to the volume reference terminal V.R of the APU 10 is cut off, the output of the digital audio signal is cut off from the APU 10.

The system reset signal as shown in FIG. 2 (A) becomes high level several hundred msec after the power control signal as shown in FIG. 2 (B) which supplies power to the system is output as high level as described above. is outputted pawooeo control signal is output to the low level after all as a signal drops to hundreds of low level before msec system reset signal power (B ^*) and then is turned hundreds msec after power supply (B *) is cut to several hundred msec before up to the high This signal is output as a level.

The system reset signal is applied to the input terminal 3 to control the driving of the transistors Q ₁ and Q ₂ of the switching unit 40 to which the standby power source ST is applied.

First, when the system reset signal is applied at a low level, the transistor Q ₂ of the switching unit 40 is “turned off” so that the standby power supply ST is connected to the transistor Q ₁ through the resistor R ₅ . When applied to the base, the transistor Q ₁ is "turned on" and when the transistor Q ₁ is "turned on", no current flows in the volume reference stage VR of the APU 10, and thus the digital audio signal output of the APU 10 is output. Will be blocked.

At this time period, the system reset signal which is applied to the low level is a pawooeo control signal is output to the low level, the period and pawooeo control signal is not applied to the power supply (B ^*) is output to the high level power source (B ^*) is applied, but It is a period of several hundred msec after power B ^* is applied and several hundred msec before power B ^* is cut off.

Therefore, no power supply (B ^*) is so that the moment of pawooeo control signal is the output of the APU (10) for hundreds msec from the time that a high level block input pawooeo "on" when pop noise is not generated and the power (B ^*) Since the output of the APU 10 is cut off several hundred msec before the power control signal, which is the moment when the power control signal becomes low level, no pop noise occurs when the power is “off”.

However, when the system reset signal is applied to the input terminal 3 at a high level, the transistor Q ₂ of the switching unit 40 is "turned on" so that the standby power supply ST is grounded through the resistor R ₅ to ground. This causes the transistor Q ₁ to be " turned off ".

When the transistor Q ₁ is " turned off ", the power supply B ^* is applied to the volume reference terminal VR of the APU 10 through the resistors R ₃ and R ₄ , so that the APU 10 starts from this time. It will output normal digital audio signal.

That is, when the system reset signal as shown in FIG. 2A is applied at a low level, the output of the APU 10 is cut off, and when the system reset signal is applied at a high level, the APU 10 outputs a normal audio signal. It is to let.

The system reset signal is a power supply (B ^*) is then injected is at a high level after several hundreds msec power (B ^*) end pawooeo since the low level before the several hundred msec is the block "on-off" when the volume reference stage (VR) By stabilizing the power supply (B ^* ) applied to the to eliminate the generation of pop noise.

As described above, the present invention eliminates pop noise generated by the transient phenomenon of the power applied to the pull-up resistor of the APU output stage during the "on-off" of the power supply by supplying the standby power to the pull-up resistor, and thereby the volume reference of the APU. The pop noise caused by the transient of the power applied to the volume reference stage that controls the voltage is eliminated by the system reset signal generated by the microcomputer, and the pop noise generated during the "on-off" of the powder is removed. There is an effect that can be improved and the conventional disadvantage that unnecessary power is consumed can be improved.

Claims (1)

The digital audio signal of the APU 10 is converted into an analog audio signal in a low pass filter 20 composed of a pull-up resistor R ₁ (R ₂ ) and a condenser C ₁ (C ₂ ), and then through the amplifier 30. In the digital audio signal output circuit output to the speaker (SP ₁ ) (SP ₂ ), the standby power supply (S) is applied to the pull-up resistor (R ₁ ) (R ₂ ) of the low pass filter (20) and the system reset. The switching unit 40 is configured to control the driving of the transistors Q ₁ and Q ₂ to which the standby power source ST is applied as a signal, and the volume reference of the APU 10 by driving the switching unit 40. A pop noise canceling circuit of an audio signal configured to control the supply of power (B ^* ) applied to the stage (VR).