KR100295324B1 - Automatic normal audio converting method - Google Patents

Abstract

PURPOSE: An automatic normal audio converting method is provided to automatically detect a buzz section of a hi-fi audio signal through a detected drop-out pulse and to properly convert a hi-fi audio reproduction mode into a normal audio reproduction mode. CONSTITUTION: Drop-out pulses generated from a weakened portion of a hi-fi RF signal are detected. When the width of the detected drop-out pulse is wider than the width of a reference pulse, an audio reproduction mode is automatically converted to a normal audio reproduction mode. When the number of counts of the detected drop-out pulses is larger than the number of reference counts even if the width of the detected drop-out pulse is narrower than the width of a reference pulse, the mode is automatically converted to the normal audio reproduction mode.

Description

Automatic Normal Audio Switching Method

The present invention relates to normal audio switching of hi-fi audio, and in particular, automatically detects a buzz section of hi-fi audio and simultaneously switches it to a normal audio playback mode so that a user can smoothly It is about automatic normal audio switching method that can hear smooth sound.

As shown in FIGS. 1 and 2, when switching the conventional hi-fi audio, the high frequency (RF) of the hi-fi audio amplified by the amplifier 1 is input to the band pass filter (BPF) 2. In the band pass filter 2, the input high-fidelity high frequency is filtered and then output to the playback processor 3 and the envelope detect 4.

At this time, the envelope detector 4 detects the envelope from the filtered high-frequency high-frequency and outputs the envelope to the microcomputer 5, so that the microcomputer 5 detects and inputs the high-frequency high-frequency. After comparing the envelope with a predetermined threshold voltage, a control signal for determining whether to switch the hi-fi audio reproduction mode to the normal audio reproduction mode is output to the output selector 6 using the envelope.

That is, the microcomputer 5 outputs a control signal to the output selector 6 for continuing the hi-fi audio reproduction mode when the detected high-fidelity high-frequency envelope is larger than a predetermined reference voltage. The output selector 6 outputs the sound of the hi-fi audio reproduction mode.

On the other hand, when the detected hi-fi high frequency envelope is smaller than a predetermined reference voltage, the microcomputer 5 outputs a control signal for switching the hi-fi audio reproduction mode to the normal audio reproduction mode. The output selector 6 switches the hi-fi audio playback mode to the normal audio playback mode and outputs the sound accordingly.

However, in the method of switching the high-fi audio according to the prior art, since the switching of the normal audio reproduction mode is dependent only on the envelope detector 4, even if an audio buzz occurs, the detected envelope value of the audio is determined in advance. If the voltage is higher than the normal audio reproduction mode, the sound of the hi-fi audio reproduction mode in the noisy state is output, so that the user cannot hear the soft sound of the audio.

Accordingly, the present invention has been made to solve such a problem, the object of which is that the drop-out (detection) section for detecting the weakened portion after considering that the high-fiber buzz occurs in the high frequency By detecting the dropout pulse, the buzz section of hi-fi audio is automatically detected, and the hi-fi audio playback mode is properly switched to the normal audio playback mode so that even in a bad recording condition, To hear the audio.

1 is a block diagram showing a conventional hi-fi audio switching device.

2 is a flowchart showing a method of switching a conventional hi-fi audio.

Figure 3 is a flow chart showing the automatic normal audio switching method of the present invention.

4 is an embodiment of a system block diagram for implementing the present invention automatic normal audio switching method.

5A to 5E are output waveform diagrams of respective parts for comparing the width of the dropout pulse and the width of the reference voltage pulse during one period of the head switch signal H. SW30 in the present invention.

6A to 6C are output waveform diagrams of respective parts for comparing the number of counters of the dropout pulse and the number of reference voltage pulses during the period of the head switch signal H. SW30 in the present invention.

The automatic normal audio switching method of the present invention for achieving the above object is mentioned in the attached flowchart of FIG. 3, and the progress thereof is as follows.

First, a pulse detection step of checking the rising edge of the hi-fi high frequency and then detecting a dropout pulse occurring at the weakened portion of the high frequency,

If the width of the dropout pulse detected by the pulse detection step is larger than the pulse width th1 of the reference voltage, the hi-fi audio play mode is automatically changed to the normal audio play mode regardless of the number of counters of the dropout pulse. A first mode switching step of switching;

If the number of counters of the dropout pulse detected by the detecting step is larger than the number of pulses of the reference voltage countered to switch to the normal audio playback mode for a predetermined time, the rising edge is counted and then the hi-fi audio playback mode is normal audio. And a second mode switching step of automatically switching to the regeneration mode.

4 shows an embodiment of a system block diagram for implementing the above-described automatic normal audio switching method, which is a drop in the weak portion of the hi-fi high frequency filtered through the bandpass filter 2 and output. A dropout detector 11 for detecting the out portion, a dropout filter 12 for filtering the dropout portion detected by the dropout detector 11, and a dropout filtered by the dropout filter 12; The pulse generating unit 13 generates a pulse of the part and outputs the same to the microcomputer 5, and the same part as in FIG. 1 is denoted by the same reference numeral and the overlapping description thereof is omitted.

Therefore, the operation of the automatic normal audio switching method of the present invention will be described with reference to FIG.

First, when the high-fi audio head outputs the head switch signal H. SW30 as shown in FIG. 5A to the amplifier 1, the amplifier 1 inputs the head switch signal H. SW30. After amplification), the high-frequency high frequency as shown in (b) of FIG. 5 is output to the band pass filter 2.

In addition, the band pass filter 2 filters the input high-fidelity high frequency and outputs the same to the playback processor 3 and the dropout detector 11, so that the dropout detector 11 A signal waveform that detects missing and attenuated portions at the input high-fi high frequency, that is, a dropout waveform as shown in (c) of FIG. 5 is detected and then output to the dropout filter 12.

In addition, the dropout filter 12 filters the input dropout waveform and then outputs a signal waveform that does not generate a pulse at a value below a predetermined position Vth as shown in FIG. Since the pulse generator 13 outputs the dropout pulse to the microcomputer 5 using the filtered dropout waveform, the pulse generator 13 outputs the dropout pulse as shown in FIG.

At this time, the microcomputer 5 outputs a control signal to the output selector 6 for determining whether to play the hi-fi audio or the normal audio according to the input dropout pulse.

That is, in the microcomputer 5, the presence or absence of a rising edge generated in a weak portion (about -20 dB of the reference) of the hi-fi high frequency through a dropout pulse inputted during one period of the head switch signal H. SW30. After checking, if the rising edge is present, the width of the dropout pulse is checked while increasing the rising edge (edge = edge + 1) to check whether the rising edge is 30 by counting the number of dropout pulses for one second. The width of the checked dropout pulse is compared with the pulse width th1 of the reference voltage.

In this case, when the width of the dropout pulse is larger than the pulse width th1 of the reference voltage by the compared value, the microcomputer 5 recognizes that the high-frequency high frequency is attenuated. Without this, a control signal for automatically switching the hi-fi audio playback mode to the normal audio playback mode is outputted to the output selector 6.

On the other hand, when the width of the dropout pulses compared by the microcomputer 5 is smaller than the pulse width th1 of the reference voltage, the microcomputer 5 performs a control operation of counting the number of dropout pulses for one second. do.

That is, in the microcomputer 5 which recognizes that there is no rising edge through the dropout pulse output from the pulse generator 13, as shown in (a) and (b) of FIG. (During the period of the head switch signal H. SW30), the number of dropout pulses is countered (dropout pulse = dropout pulse + 1).

In this case, the microcomputer 5 compares the number of dropout pulses with the number of pulses of the reference voltage based on the counter value, and then switches the number of dropout pulses to the normal audio playback mode for one second by the compared value. The output selector 6 outputs a control signal for automatically switching the hi-fi audio playback mode to the normal audio playback mode while increasing the rising edge by a certain number (edge = 30) when the number of pulses of the reference voltage countered is increased. Will be output to.

Therefore, the output selector 6 selects the hi-fi audio reproduction mode as the normal audio reproduction mode according to the input control signal, so that the user can hear a soft sound.

Here, the width th1 of the reference voltage is experimentally about 10 to 15 ms, and the number of reference voltage pulses to be switched to normal audio regeneration mode by counting the number of dropout pulses for one second is about 30 to 35 experimentally. .

As described above, the present invention configures a dropout detector for detecting the weakened portion after considering that the high-fiber buzz occurs in the high frequency weakened portion. -It automatically detects the buzz section of the pi audio and switches the hi-fi audio playback mode to the normal audio playback mode so that the sound of soft sound can be heard even in the case of a poor recording condition.

Claims (1)

A first step of detecting a dropout pulse occurring at the weak portion of the hi-fi high frequency wave, A second step of automatically switching to a normal audio playback mode when the width of the dropout pulse detected in the first step is larger than the width of the reference pulse; And a third step of automatically switching to a normal audio playback mode when the number of counters of the dropout pulses detected in the first step is greater than the number of reference counters even when the width of the dropout pulses is smaller than the width of the reference pulse in the second step. Normal audio switching method characterized in that configured by.

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