KR960011415B1 - Signal level attenuator - Google Patents

Abstract

The circuit includes a sound player, a microphone amplifier, a DSP(Digital Signal Processing) chip attenuating the output from the sound player and the amplifier under attenuation control data to mix the 1st and 2nd channel sound(L)(R) with the microphone signal, variable resistors for surround and echo effects linked between a power and an earth, a level shift detected data transmitter detecting a level shift of control voltages from the variable resistors to provide corresponding attenuation data for the DSP.

Description

Signal level attenuation control circuit and method

1 is a conventional signal level attenuation control circuit diagram.

2 is a signal level attenuation control circuit diagram in accordance with the present invention.

3 is a signal level attenuation adjustment control flowchart according to the present invention.

* Explanation of symbols for main parts of the drawings

12: sound playback device 14: microphone amplifier

16,30: negative variable resistance 22,32: echo variable resistance

24: digital signal processor 26: microcomputer

28: level transition detection data transmitter

The present invention relates to a signal level attenuation control device usable in an audio device, and more particularly, to a signal level attenuation control circuit and method that can be used in an audio device for mixing and outputting audio to sound output from a sound reproducing device.

Most current audio devices can reproduce and output a signal recorded on a specific medium or a broadcast signal, and simultaneously output an audio signal output from a microphone (hereinafter referred to as a microphone) to the reproduced signal. It is supposed to be. The conventional audio device having the microphone mixing function as described above has adjustment means for appropriately adjusting the reproduced signal (hereinafter referred to as sound) and the signal level from the microphone. The adjusting means as described above is generally composed of a variable resistor named volume. Examples of such audio devices are typical home audio devices and audio devices for video orchestras (hereinafter referred to as videoke devices) that are currently widely used.

FIG. 1 is a conventional signal level attenuation control circuit diagram, which shows an example of a circuit commonly used in a videoke device. FIG. 1 shows a digital signal processor for varying the signal level output from the first and second channel output terminals L and R of the sound reproducing apparatus 12 for reproducing a sound signal source such as accompaniment. An audio multiple variable resistor 16, which is output to the attenuation input terminal 24 of the present invention, is connected to the output terminal of the sound reproducing apparatus 12. The negative multiple variable resistor 16 is composed of two variable resistors 18 and 20. An echo variable resistor 22 for varying the level output from the microphone amplifier 14 and outputting it to the attenuation input terminal of the DSP 24 is connected between the output terminal M and ground. In this case, the microphone amplifier 14 amplifies and outputs a voice signal output from the microphone. The DSP 24 processes the signals input to the respective attenuation input terminals in a predetermined state to provide a first and second channel mixing signal in which a microphone signal is mixed with each of the first and second channel sound signals of sound. Output

For example, the DSP 24 may predetermine the audio signal of the microphone input through the variable resistor 22 to the sound signals of the first and second channels output from the variable resistors 18 and 20. The first and second channel mixing signals are output by mixing with each other.

The microcomputer 26 connected to the DSP 24 controls the overall operation of the videoke and scans a key matrix (not shown) to control the mode of the user's actions and the operating conditions of the system. In this case, the mode may be selected as a videoke mode or a karaoke mode.

However, the conventional signal level attenuation control circuit configured as shown in FIG. 1 has a problem that noise is easily induced by adjusting a signal level by directly connecting a variable resistor for adjusting the signal level to a signal transmission line. In addition, there is a problem that the man-hour is increased by connecting the variable resistor to the signal line of each channel.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a signal level attenuation adjustment circuit diagram according to the present invention, which includes a sound reproducing apparatus 12 for outputting first and second channel sounds L and R, and a microphone for amplifying and outputting a signal of a microphone to a predetermined level. The signals output from the amplifier 14, the sound reproducing apparatus 12, and the microphone amplifier 14 are adjusted to a level signal by controlling attenuation adjustment data, and the adjusted first and second channel sounds ( L) DSP 24 for mixing and outputting the signal of the microphone to each of (R), and audio multiple for outputting a voice multiple level and a control voltage for controlling the signal level of the microphone, which are connected between a power supply voltage and ground, respectively. The DSP detects the level shift of the control voltage output from the variable resistor 30 and the echo variable resistor 32, and the voice multiple variable resistor 30 and the echo variable resistor 32, respectively, and outputs the attenuation adjustment data corresponding thereto. Output to 24 The bell ring is composed of a detection data transmitter 28.

In the configuration as shown in FIG. 2, the DSP 24 includes attenuators 24a and 24b for attenuating and outputting the level of the input signal to a level corresponding to the attenuation adjustment data, and a microphone signal output from the attenuator 24b. An echo processor 24c for echo processing and outputting a signal, and a signal processor for mixing a signal output from the attenuator 24a and a signal output from the echo processor 24c and outputting a mixed signal of these signals ( 24d).

The level shift detection data transmitter 28 can be configured as a one-chip type microprocessor which incorporates an analog-digital converter and converts and inputs an analog voltage level into digital data. In addition, when not using a microprocessor incorporating an analog-digital converter as described above, an analog-digital converter, a digital comparator and a plurality of logic circuits can be used to satisfy the operation according to the present invention with reference to the following description. It will be obvious.

3 is a flow chart of the signal level attenuation adjustment control according to the present invention, which is a flowchart programmed in the level transition detection data transmitter 28 shown in FIG. The control procedure of the level shift detection data transmitter 28 includes an initialization process of setting a digital data value corresponding to a voltage level, converting a voltage level input to each port into corresponding digital data, and A signal level adjustment process is performed to transmit attenuation adjustment data corresponding to the current input level when a change is made in comparison with the data.

Hereinafter, an operation process of FIG. 2 according to the present invention will be described in detail with reference to the control flowchart of FIG. 3. In the following detailed description of the invention, the initial output voltage levels of the voice variable variable resistor 30 and the echo variable resistor 32 shown in FIG. 2 are the median value Vcc / 2 corresponding to half of the power supply voltage Vcc. It should be noted that the level of accompaniment (first and second channel sound) and voice (microphone output) are adjusted according to an outlier or a lower value of the median value (Vcc / 2).

Now, when a circuit like FIG. 2 is operated, the level shift detection data transmitter 28 sets a data value for the level of the operating power supply voltage in step 40 of FIG. That is, the digital data for each level is set by analog-to-digital converting the power supply voltage Vcc into data corresponding to the number of bits to process the level of the power supply voltage Vcc during the initial operation. More specifically, if the analog to digital converter (ADC) located inside the level shift detection data transmitter 28 has a 4-bit processing capability, a power supply voltage level of 0 to 5 volts may be set in 16 steps. Set to a digital value (0000 to 1111). In step 40, the level shift detection data transmitter 28 converts the level of the power supply voltage Vcc into digital data. In step 42, the level shift detection data transmitter 28 performs analog digital conversion on the detection control voltage of the line SM. And store it in the attenuator 24 and transmit it to attenuators 24a and 24b in the DSP 24. At this time, the voltage input to the line SM (ME) is the voltage output from the voice multiple resistor 30 and the echo variable resistor 32, the initial set voltage is Vcc / 2 as described above. In step 44, the level shift detection data transmitter 28 digitally converts the voltage level input to the input line SM (ME), and converts the digitally converted data into previous data stored in an internal register. Compare the value to see if the data has changed in step 46.

As a result of the search, if the digital data of the currently input level is the same as the previously input data value, the level shift detection data transmitter 28 repeats the aforementioned process 42. If the user varies the voice variable variable resistor 30 and the echo variable resistor 32 to change the voltage level of the line SM (ME), the level transition detection data transmitter 28 selects the level currently input in step 48. Attenuation adjustment data corresponding to the value is transmitted to each attenuator 24a or 24b. Accordingly, the level shift detection data transmitter 28 outputs the attenuation control data corresponding to the voltage output from the voice multiple resistor 30 and the echo variable resistor 32 in each of the attenuators 24a and 24b. You can see that

At this time, the attenuators 24a and 24b in the DSP 24 adjust and output a signal level input at a level corresponding to the attenuation adjustment data output from the level shift detection data transmitter 28. For example, if the attenuation adjustment data is 1000, each of the attenuators 24a and 24b attenuates the input signal level to a level of ½, respectively, and outputs it.

In the above operating state, the first and second channel sounds are output from the first and second channel output terminals L and R of the sound reproducing apparatus 12 to the attenuator 24a in the DSP 24. When the microphone echo signal, which is input and output from the micro amplifier 14, is input to the attenuator 24b in the DSP 24, each of the attenuators 24a and 24b transmits the level of the input signals through the data bus. Adjust the output to a level corresponding to the input of the attenuation adjustment data input. At this time, the signal output from the attenuator 24b is input to the echo processor 24c, and the echo processor 23c echo-processes the signal of the input microphone by adjusting the level at the attenuator 23b and processing the signal processor 24d. ). The signal processor 24d mixes and outputs a signal output from the attenuator 24a, a sound signal, and a microphone echo signal output from the echo processor 24c. That is, the signal processor 24d outputs a first channel mixing signal in which the microphone echo signal and the first channel sound signal are mixed, and a second channel mixing signal in which the microphone echo signal and the second channel sound are mixed.

As described above, when the DSP 24 inputs the first and second channel sound signals and the microphone echo signal, the audio multiple variable resistor 30 adjusts the level of the accompaniment or the voice. And the echo variable resistor 32 are varied, the voltage level of the line SM ME changes. In the level shift detection data transmitter 28, the voltage level of the line SM ME is changed. The level shift detection data transmitter 28 detects the change in the line SM ME as described above and transmits attenuation adjustment data corresponding to the input level value to the attenuators 24a and 24b.

For example, when the output voltage level of the voice multiple variable resistor 30 is lowered, the level shift detection data transmitter 28 attenuates the attenuation control data corresponding to the level change of the voice multiple variable resistor 30. The signal level of the first and second channel sounds output from the sound reproducing apparatus 12 is further attenuated. As described above, when the output level of the attenuator 24a is further lowered, the signal processor 24d mixes the signals of the first and second channel sounds having the lower level of the signal and the signals output from the echo processor 24c. Outputs a mixed signal whose accompaniment level is lower than that of. If the attenuation adjustment data corresponding to the level change of the echo variable resistor 32 is output to the attenuator 24b, the microphone echo signal level is further attenuated from the microphone amplifier 14. As described above, when the output level of the attenuator 24B is further lowered, the signal processor 24d mixes the microphone echo signal having the lower level of the signal and the signals of the first and second channel sounds, thereby inverting the microphone signal. Outputs a mixed signal with a lower level. Therefore, contrary to the foregoing, the mixed signal of which the signal level of the microphone is lowered rather than the accompaniment is output. If the output level of the voice multiple variable resistor 30 or the microphone echo variable resistor 32 is increased by the above operation, it can be seen that the output level of the sound reproducing apparatus 12 or the microphone amplifier 14 is increased.

In the embodiment of the present invention, an example of a state in which the attenuators 24a and 24b and the signal processor 24d are incorporated in the DSP 24 has been described. However, such an attenuator is a circuit for controlling the level of the input signal according to the digital input. It should be noted that one of ordinary skill in the art may use a associative amplifier to easily manufacture a circuit that varies the gain of amplification according to the digital value. In addition, it should be noted that the signal processor 24d may be easily configured using an analog mux or an adder.

As described above, the present invention can remove noise generated when directly adjusting the signal level of the signal line by adjusting the sound level of each channel and the signal level of the microphone by varying the voltage, and more precisely adjusting the level of the signal. Can be.

Claims (6)

A signal level attenuation control circuit having sound output means for outputting at least one channel sound and an amplification means for amplifying and outputting a voice signal to a predetermined level, wherein the signals output from the sound output means and the amplification means are respectively output. A signal level control output means for adjusting to a signal having a level corresponding to the attenuation adjustment data input, and for mixing and outputting the signal of the mark to each of the adjusted channel sounds, and the level of the channel sound and the audio signal level. Level adjustment means for outputting a control voltage to control, and level shift detection data transmission means for detecting a level shift of a control voltage output from the level output means and supplying corresponding attenuation adjustment data to the signal level control output means. Signal level attenuation adjustment characterized in that the configuration A. 4. The signal level control output means according to claim 1, wherein the signal level control output means includes first and second attenuation means for attenuating and outputting a level of a signal input at a level corresponding to attenuation adjustment data, and audio output from the second attenuation means. Echo processing means for echo-processing the signal and outputting the signal, and signal processing means for mixing the signal output from the first attenuating means and the signal output from the echo processing means and outputting a mixed signal of these signals. Signal level attenuation control circuit, characterized in that. The method of claim 2, wherein the level shift detection data transmitting means digitally converts a level of the voltage output from the level adjusting means, and compares the converted digital data with a value of previously stored digital data to generate a change. And supplying attenuation adjustment data corresponding to the converted digital data to the first and second attenuation means. 3. The apparatus of claim 2, wherein the level adjusting means includes a voice multiple variable resistor outputting a control voltage for adjusting the level of the first and second channel sounds by varying a power supply voltage to a voltage of a predetermined level. And a microphone echo variable resistor configured to output a control voltage for controlling the voice signal level by varying the voltage to a predetermined level. 5. The apparatus of claim 4, wherein the level shift detection data transmitting means digitally converts control voltages respectively output from the voice multiple variable resistor and the microphone echo variable resistor, and converts the converted digital data and previously stored digital data. And comparing a value of and supplying attenuation adjustment data corresponding to the converted digital data to at least one of the first and second attenuation means when a change occurs. Sound output means for outputting at least one channel sound, and the sound output means and a voice signal of a predetermined level are respectively adjusted to a signal of a level corresponding to input attenuation adjustment data, wherein the voice is applied to each of the adjusted channel sounds. Signal level control output means for mixing and outputting signals, level control means for outputting a control voltage for controlling the level of the channel sound and the audio signal level, and level transition of the control voltage output from the level output means. A signal level attenuation adjustment method comprising a level shift detection data transmission means for detecting and supplying corresponding attenuation adjustment data to the signal level control output means, the method comprising: an initialization step of setting a digital data value corresponding to a voltage level; Digital data corresponding to voltage level input to each port The signal attenuation level control method of claim 1, characterized in that the signal level adjustment process for converting the signal to the previously input data, and transmits the attenuation control data corresponding to the current input level.