KR0134530Y1 - Automatic discrimination circuit of multi-sound broadcasting - Google Patents

Abstract

The present invention relates to an audio discrimination automatic discrimination circuit, and automatically determines whether an audio signal to be applied is an audio multiplex method or a stereo system. Thus, a playback signal can be obtained even when the applied signal is weak. Filtering means for separating and detecting only the audio signal from the filter, rectifying means for rectifying the audio signal detected by the filtering means and converting the digital signal into a digital pulse signal, integrating means for integrating the digital pulse signal outputted from the rectifying means; Amplifying means for comparatively amplifying the integral signal applied from said integrating means and the digital pulse signal applied from said rectifying means, pulse generating means for generating a pulse signal identical to that output from said rectifying means from a high frequency head switching pulse, and According to the control signal applied from the pulse generating means Was provided with a switching means for switching the pulse signals amplified by the amplifying means group.

Description

Voice multicasting automatic discrimination circuit

1 is a schematic block diagram showing an automatic voice multiplex discrimination circuit according to the present invention.

FIG. 2 is an output waveform diagram of each part shown in FIG.

* Explanation of symbols for main parts of the drawings

1 filter unit 2 first amplifier unit

3: rectifying part 4: integrating part

5: second amplifier 6: pulse generator

7: switching unit

The present invention relates to an automatic speech multiplexing circuit, and more particularly, to automatically determine whether a recorded audio signal is an audio multiplex signal or a general stereo signal even if an audio signal is weak. It relates to a discrimination circuit.

In recent years, each broadcasting station is using voice multiplexing to provide more advanced television broadcasting to viewers. This voice multiplexing method translates a foreign language into a native language in a foreign film, records it again in a way called dubbing by a voice actor, and then simultaneously transmits the foreign language and the native language so that the viewer can selectively listen to the foreign language and the native language. It would be.

Therefore, the voice multicast signal has different characteristics from the general stereo broadcast signal. That is, the audio multicast signal includes a pilot signal that is distinguished from a stereo broadcast signal in the audio signal and is a voice multicast signal.

At this time, the pilot signal indicating the voice multiplexing system has a predetermined level, which is generally defined as 4 decibels (dB).

Therefore, a video receiving and reproducing apparatus such as a television and a video cassette recorder owned by a general household is provided with an integrated circuit for voice multi-broadcast recognition (HA118276F IC of Hitachi Co., Ltd.) and recognizes the received or reproduced broadcast signal by the voice multi-broadcast. By applying to the integrated circuit to detect the presence or absence of a pilot signal, it is determined whether the received and reproduced broadcast signal system is a voice multiplex method or a general stereo system.

However, the conventional voice multicasting automatic discrimination circuit as described above discriminates voice multicasting through an integrated circuit for recognizing voice multicasting. In this case, the voice multicasting pilot integrated signal is 4 decibels (dB). Can be read only when Therefore, when the pilot signal of the received and reproduced broadcast signal is less than 4 decibels (dB), or when the deck signal is severely changed due to a poor driving state of the deck, an error may occur in the process of determining the voice multicasting. There was a problem.

In such a case, the integrated circuit for recognizing voice multi-broadcast is recognized as a general stereo broadcast even if voice multi-broadcasting is applied, so that a foreign language and a native language are mixed and output.

Therefore, the present invention is to solve the above-described problems, an object of the present invention is to use a playback device to stably determine even when the pilot signal of the video signal recorded on the tape is weak or the level fluctuation is severe. It is to provide a voice multiplex automatic discrimination circuit.

Features of the present invention for achieving the object as described above, filtering means for separating and detecting only the audio signal from the reproduction signal; Rectifying means for rectifying the audio signal detected by the filtering means and converting the audio signal into a digital pulse signal; Integrating means for integrating the digital pulse signal outputted from the rectifying means; Amplifying means for comparatively amplifying the integrated signal applied from said integrating means and the digital pulse signal applied from said rectifying means; Pulse generating means for generating a pulse signal identical to that output from said rectifying means from a high frequency head switching pulse; And switching means for switching a pulse signal amplified by the amplifying means in accordance with a control signal applied from the pulse generating means.

In the present invention, it is preferable to further include an amplifier for amplifying the audio signal filtered by the filtering means to a size capable of signal processing, and the filtering means is preferably constituted by a band pass filter of 1.5 MHz.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of an automatic voice multiplex discrimination circuit according to the present invention will be described in detail.

1 is a schematic block diagram showing an automatic voice multiplex discrimination circuit according to the present invention.

Referring to FIG. 1, the filter unit 1 which receives a reproduction signal and detects only an audio signal, and the first amplifier 2 which amplifies the audio signal detected by the filter unit 1 to a predetermined size capable of signal processing. ), A rectifier 3 for rectifying the audio signal amplified by the first amplifier 2 and converting the audio signal into a digital pulse signal, and a pulse signal rectified through the rectifier 3 to have a predetermined level. An integrating unit 4 for converting into a signal, and a second amplifying unit 5 for comparing and amplifying a pulse signal applied from the rectifying unit 3 and a predetermined level applied from the integrating unit 4 are constituted.

In addition, the pulse generator 6 generates a pulse signal having the same shape as the audio signal output from the above-described filter unit 1 by using the high frequency head switching pulse, and the amplification unit in the second amplifier 5 described above. The switching unit 7 is configured to switch the outputted pulse signal under the control of the pulse signal generated by the pulse generator 6 and output the same.

Referring to Figure 2 with respect to the operation of the present invention as described above in detail as follows.

In the reproduced reproduction signal, only the audio signal is filtered by the filter unit 1, and the remaining signal components are blocked. That is, since the audio signal is detected based on 1.5 MHz, when the filter unit 1 uses a 1.5 MHz band pass filter, only pure audio signals from which other signal components are removed are detected.

Here, when the reproduced signal is a voice multiple signal, the audio signal detected by the filter unit 1 includes a pilot signal indicating that it is a voice multiple system, and when the reproduced signal is a general stereo signal, it is detected by the filter unit 1. The pilot audio signal does not exist.

The audio signal detected by the filter unit 1 is amplified to a predetermined size for signal processing by the first amplifier 2, and then rectified by the rectifier 3 to be converted into a predetermined pulse signal and output.

Here, assuming that the reproduction signal is an audio multiplexing system, the pulse signal output from the rectifying unit 3 is output in the form of a pulse as shown in FIG. 2B by the pilot signal, and the pulse signal is integrated into the integrating unit ( When passing through 4), the voltage level is integrated with the DC voltage component having a value smaller than the upper limit of the pulse and output. Thereafter, the second amplifier 5 compares the pulse signal applied from the rectifier 3 with the integrated signal applied through the integrator 4 and amplifies and outputs the result. In this case, the two signals are compared. On the basis of the integral signal, outputs a high state when the pulse signal is larger than the integral signal and outputs a low state when the pulse signal is smaller than the integral signal. In other words, if the integral coefficient of the integrating unit 4 is properly adjusted, even if the level of the pulse signal applied from the rectifying unit 3 is a weak signal of about 2 dB, it can be sufficiently compared. Accordingly, the second amplifier 5 outputs a pulse signal having the same period as that of the output pulse of the rectifier 3 and whose amplitude is further amplified, as shown in FIG.

On the other hand, the high frequency head switching pulse as shown in (a) of FIG. 2 is applied to the pulse generator 6, and the pulse generator 6 uses the applied high frequency head switching pulse to (b) of FIG. Generate a pulse signal as shown in FIG. This is in accordance with the specification of the voice multiple pilot signal, and the high frequency head switching pulse changes the pulse shape from the time when the pilot signal of the audio signal is detected to a predetermined time. As shown, it is possible to generate a pulse signal that is inverted to a high state after a predetermined time delay from the time when the pulse shape of the high frequency head switching pulse changes. Here, since the pulse signal generated by the pulse generator 6 is detected from the same audio signal, it has the same period and shape as the pulse output from the rectifier 3.

The switching unit 7 receives the pulse signal amplified from the second amplifier 5 and controls the output of the pulse signal amplified by the second amplifier 5 according to the pulse signal generated by the pulse generator 6. do. That is, the switching unit 7 is configured to be turned on when the pulse generated by the pulse generator 6 is high and turned off when the pulse generated by the pulse generator 6 is low. The pulse signal amplified by the section 5 is selectively output.

At this time, since the pulse signal output from the pulse generator 6 and the pulse signal amplified by the second amplifier 5 have the same period, as a result, the detection signal which is the final output is shown in FIG. As shown, only the high pulse portion is detected.

Next, assuming that the reproduction signal is a general stereo system, the pulse signal output from the rectifying section 3 is output by the pilot signal as a DC component as shown in Fig. 2C, and the signal of this DC component is When passing through the integrating unit 4, it is output as a signal of the same DC component as the applied DC component. Thereafter, the second amplifier 5 compares the pulse signal from the rectifier 3 with the integrated signal applied through the integrator 4 and amplifies and outputs the result. The result of comparing the two signals is an integrated signal. When the pulse signal is larger than the integral signal, the signal is output in the high state. If the pulse signal is smaller than the integral signal, the signal is output in the low state. In other words, if the integral coefficient of the integrating unit 4 is properly adjusted, even if the level of the pulse signal applied from the rectifying unit 3 is a weak signal of about 2 dB, it can be sufficiently compared. Accordingly, the second amplifier 5 outputs the signal of the DC component since the two applied values are the same as shown in (e) of FIG.

On the other hand, the high frequency head switching pulse as shown in (a) of FIG. 2 is applied to the pulse generator 6, and the pulse generator 6 uses the applied high frequency head switching pulse to (b) of FIG. Generate a pulse signal as shown in FIG.

The switching unit 7 receives the DC component signal applied from the second amplifier 5 and outputs the DC component signal output from the second amplifier 5 according to the pulse signal generated by the pulse generator 6. To control the output. That is, the switching unit 7 is configured to be turned on when the pulse generated by the pulse generator 6 is high, and to be turned off when the pulse generated by the pulse generator 6 is low, thereby providing a second amplification. The pulse signal amplified by the section 5 is selectively output.

At this time, since the pulse signal output from the pulse generator 6 and the pulse signal amplified by the second amplifier 5 have the same period, as a result, the detection signal which is the final output is shown in FIG. As such, only the portion of the voltage whose value is low is detected.

Accordingly, it can be seen that the reproduction signal is the voice multiplexing method when the final detection signal output from the switching unit 7 is high and the reproduction signal is the normal stereo system when the final detection signal output from the switching unit 7 is low. . As a result, according to whether the final output of the present invention is high or low state, it is easy to know whether the reproduced signal is a voice multiplex method or a general stereo mode.

On the other hand, as mentioned above, if the integral coefficient of the integrating unit 4 is properly adjusted, even if the pulse signal applied from the rectifying unit 3 is weak, it can be sufficiently distinguished.

As described above, according to the voice multicasting automatic discrimination circuit according to the present invention, even when the pilot signal of the reproduced audio signal is weak or the level fluctuation of the pilot signal is severe, the level of the pilot signal is stabilized through the rectification process and integrated. Through the process and the comparative amplification process, it is possible to accurately determine the weak signal, there is an advantage that can prevent the misjudgment of the broadcast method.

Claims (3)

Filtering means for separating and detecting only the audio signal from the reproduction signal; Rectifying means for rectifying the audio signal detected by the filtering means and converting the audio signal into a digital pulse signal; Integrating means for integrating the digital pulse signal outputted from the rectifying means; Amplifying means for comparatively amplifying the integrated signal applied from said integrating means and the digital pulse signal applied from said rectifying means; Pulse generating means for generating a pulse signal identical to that output from said rectifying means from a high frequency head switching pulse; And switching means for switching a pulse signal amplified by the amplifying means in accordance with a control signal applied from the pulse generating means. 2. The automatic speech multiple discrimination circuit according to claim 1, further comprising an amplifier for amplifying the audio signal filtered by the filtering means to a size capable of signal processing. The voice multicasting automatic discrimination circuit according to claim 1, wherein the filtering means comprises a 1.5 MHz band pass filter.