KR100230498B1 - Automatic sound control apparatus of an each broadcasting program - Google Patents

Abstract

The present invention proposes an automatic sound equalization technology that enables automatic setting of a sound equalization level for each broadcast program mode in a VSI or television system having a hi-fi / voice multiple reception function.

The technical configuration of the present invention comprises a tuner stage for tuning a television broadcasting channel, an image intermediate frequency amplifier stage for amplifying a video signal of a channel tuned by the tuner stage, and an audio intermediate frequency signal extracted from an output of the image intermediate frequency amplifier stage. A first signal path consisting of a first BPF, a signal amplifier, a first FM detector, and a first equalizer of 4.5 MHz to transmit the output of the voice intermediate frequency amplifier stage and the output of the voice intermediate frequency amplifier stage to the matrix stage; A second signal path comprising two BPFs, a signal amplifying stage, a second FM detector, and a second equalizing stage, a pilot detecting stage for determining whether a pilot signal is present on the speech signal passing through the second BPF, and the matrix; A voice equalization level which controls the stage and sets the first and second light stages based on the pilot detection signal from the pilot detection stage. It will include a microcomputer that is made dropped.

Description

Automatic sound setting system for each broadcasting program

The present invention registers the sound equalization setting values for each broadcast program in advance and then determines the type of broadcast program received by the tuner and automatically selects an appropriate sound equalization value for the broadcast program. It is about an automatic setting system.

The current broadcast signals that we receive through VSI or TV are divided into hi-fi stereo / voice multiplex and mono.

The stereo hi-fi broadcast system is applied to a show program, a music program, a drama program, for example.

Voice broadcasting is applied to, for example, news programs, foreign currency programs, and cartoon films.

For example, the mono broadcasting system is applied to general education, news programs, and news programs.

As such, a television broadcast signal having various broadcast formats has an appropriate voice equalization area for each broadcast method. Therefore, when a user wants to watch a music program by selecting a hi-fi stereo broadcast reception mode or a vortex etc. using a voice multiple mode, It is necessary to adjust the voice equalization circuit of the voice signal processing stage to make the most suitable condition for watching the broadcast program.

Existing VSI or TV processes the voice intermediate frequency signal separated from the image intermediate frequency signal of the TV broadcast signal tuned by the tuner, and whether the current broadcast program is hi-fi stereo broadcast according to the recognition of the pilot signal obtained therefrom. It is designed to determine whether it is a voice multiple broadcast or a monaural broadcast, and to select the audio output as stereo / voice multiple and mono according to the determination result.

Therefore, in order to obtain a voice suitable for the characteristics of each broadcasting program, the value has to be adjusted by manual operation every time the receiving channel is switched or whenever the receiving program is changed.

It is an object of the present invention to automatically receive a sound equalization suitable for the nature of a broadcast program that is received without a separate hi-fi stereo, voice multiplex, or monaural broadcast program without additional separate sound equalization. It is to provide a system for automatically setting the sound equalization for each broadcast program to be set to.

1 is a circuit diagram of a system of the present invention.

2 (a)-2 (c) are graphs of optimal voice equalization characteristics for each broadcast type to be applied to the present invention.

3 is a flowchart illustrating the present invention.

* Explanation of symbols for main parts of the drawings

10: tuner stage 11: video intermediate frequency amplifier stage

15: voice intermediate frequency amplifier 16, 20, 25: BPF

17,21: signal amplifier 18,22: FM detector

19,23: equalization stage 24: matrix stage

26: pilot detection stage 27: microcomputer

A feature of the present invention is a tuner stage for tuning a television broadcast channel, an image intermediate frequency amplifying stage for amplifying a video signal of a channel tuned by the tuner stage, and an audio intermediate frequency signal extracted from an output of the image intermediate frequency amplifying stage for amplifying a signal. A first signal path comprising a first BPF at 4.5 MHz, a signal amplifier, a first FM detector, and a first equalization stage, and a second at 4.72 MHz to transmit the voice intermediate frequency amplifier stage and the output of the voice intermediate frequency amplifier stage to the matrix stage. A second signal path comprising a BPF, a signal amplifying stage, a second FM detector, and a second equalizing stage, a pilot detecting stage for determining whether a pilot signal is present on the speech signal passing through the second BPF, and the matrix stage And control the first and second equalization stages to a predetermined voice equalization level based on the pilot detection signal from the pilot detection stage. In the V or sialic speech processing system of the television it is composed of a microcomputer donor.

Referring to the accompanying drawings, the technical configuration of the present invention will be described.

1 shows a circuit diagram of a system of the present invention.

The circuit shown here is the core circuit of the audio intermediate frequency signal processing stage installed in the television, and this circuit has the same circuit configuration as the audio intermediate frequency signal processing stage inside VSI.

The television broadcast signal received through the antenna is connected to the tuner stage 10 after the desired channel is tuned and converted into an intermediate frequency signal to be transmitted to the image intermediate frequency amplifier stage 11.

The image intermediate frequency signal output from the image intermediate frequency amplifier stage 11 is configured to be output as an image signal through the image detector 12 and the image signal processing stage 13.

In addition, the video intermediate frequency signal output from the video intermediate frequency amplifier stage 11 is applied to the audio intermediate frequency amplifier stage 15 so that the audio intermediate frequency signal is picked up and amplified and output.

The voice intermediate frequency signal output from the voice intermediate frequency amplifier stage 15 includes a first BPF 16, a signal amplifier stage 17, a first FM detector 18, and a first equalization stage 19. The first intermediate path of the matrix terminal 24 is connected to the first input of the matrix stage 24, and the audio intermediate frequency signal output from the speech intermediate frequency amplifier stage 15 is provided by the second BPF 20, the signal amplifier stage 21, A second signal path consisting of the second FM detector 22 and the second equalizer 23 is connected to be provided to the second input of the matrix stage 24.

The frequency characteristic of the first BPF 16 is designed to be 4.5 MHz, and the frequency characteristic of the second BPF 20 is designed to be 4.724 MHz.

Meanwhile, the voice signal filtered and output from the second BPF 20 is connected to the pilot detection terminal 26 via the third BPF 25 having a frequency characteristic of 55.1 MHz.

The presence / absence determination signal of the pilot signal output from the pilot detection stage 26 controls the matrix stage 24 and the microcomputer automatically sets the voice equalization levels of the first and second equalization stages 19 and 23. It is configured to connect to provide (27).

The operation process of the present invention configured as described above will be described with reference to FIGS. 2 (a)-2 (c) and 3.

When a television RF broadcast signal is input to a tuner stage 10 of a VSI or a television through an antenna, the tuner stage 10 extracts an image intermediate frequency (PIF) signal from a broadcast signal of a tuned channel and transmits it to the image intermediate frequency amplifier stage. Will print.

The image signal is output as an image signal through the image detector 12 and the image signal processor 13.

The PIF output of the image intermediate frequency amplifier stage 11 is input to the audio intermediate frequency amplifier stage 15.

This speech intermediate frequency amplifier stage 15 picks up the SIF signal from the speech intermediate frequency (PIF) signal and amplifies and outputs it.

The voice intermediate frequency signal output from the voice intermediate frequency amplifier stage 15 includes a first signal path including a first BPF 16, a signal amplifier stage 17, a first FM detector 18, and a first equalization stage 19. It is transmitted to the first input terminal of the matrix stage 24 via.

In addition, the speech intermediate frequency signal output from the speech intermediate frequency amplifier stage 15 includes a second BPF 20, a signal amplifier stage 21, a second FM detector 22, and a first equalization stage 23. It is transmitted to the first input terminal of the matrix terminal 24 via two signal paths.

The matrix stage 24 receives a voice signal input through the first and second signal paths through a respective R / L channel under the control of the microcomputer 27, and has a voice in hi-fi stereo mode, voice multiple mode, or monaural mode. The output will be in mode.

The microcomputer 27 uses a pilot signal as a source for switching the voice signal matrix stage 24.

In other words, if the pilot signal frequency is 150 Hz, it is determined to be stereo broadcasting, and if it is 276 Hz, it is determined to be voice multiple broadcasting to control the matrix stage.

The pilot signal is detected by the pilot detection stage 26, and the voice filtering signal of the second BPF 20 passing through the third BPF 25 having a frequency characteristic of 55.1 KHz is included in the pilot detection stage 26. To be authorized.

On the other hand, when the pilot detection stage 26 detects the pilot signal from the voice intermediate frequency signal passing through the third BPF 25 and transmits it to the microcomputer 27, the microcomputer 27 determines whether the pilot signal is present or not. In addition to the judgment, when the pilot signal is input, it is determined whether the frequency of the pilot signal is 150 Hz or 276 Hz. Therefore, as described above, the voice matrix stage is controlled to be switched to the stereo mode / multiple mode / monaural mode. Will be.

The voice mode determination output from the microcomputer 27 is provided to the first and second equalization stages 19 and 23 on the first and second signal paths.

In this case, the first and second equalization stages 19 and 23 have at least three voice equalization levels under the control of the microcomputer.

2 (a)-2 (c) shows a graph of voice equalization frequency characteristics of a preferred example according to the type of broadcast program.

As referred to herein, FIG. 2 (a) is a graph of voice equalization characteristics at the time of stereo broadcast reception suitable for a show program or a drama program, and the feature is that low and high ranges are particularly emphasized.

Also, FIG. 2 (b) is a graph of voice equalization frequency characteristics at the time of monaural broadcasting reception suitable for culture and news program, and its characteristic is to maintain flatness over the entire band.

Fig. 2 (c) is a graph of voice equalization frequency characteristics at the time of voice multiple broadcast reception suitable for foreign currency or news program, and its characteristic is that the midrange is particularly emphasized.

3 illustrates a process in which the microcomputer selectively controls the first and second equalization stages according to the present invention.

In the first step, it is determined whether a pilot signal is present from the voice intermediate frequency signal by turning on the tuner stage.

If the pilot signal is not detected in this step, it is determined as the voice monaural mode and the first and second equalization stages 19 and 23 are set to the equalization level of the frequency characteristic as shown in FIG. 2 (a).

However, when the pilot signal is detected in the above step, the next step of determining the magnitude of the pilot signal frequency is performed.

In this case, when 150Hz is detected, it is determined as the stereo broadcast reception mode and the first and second equalization stages 19 and 23 are set to the equalization level of the frequency characteristics as shown in the second (a), otherwise the pilot has a 276Hz pilot. The first and second equalization stages are set to the equalization level of the frequency characteristic as shown in FIG.

As described above, in the present invention, when a television broadcast program is received using a tuner or a built-in tuner in a television, the user may perform a voice equalization level by each mode of the broadcast program, that is, in stereo mode / multiple voice mode / mono mode. It is a unique feature that maximizes the function of VSI or TV by automatically detecting the broadcast mode status in the receiving system and automatically setting the optimal voice lighting accordingly, deviating from the conventional method that had to be operated manually. The effect of will appear.

Claims (1)

A television broadcast reception system having a stereo / audio multiplex function, comprising: a tuner stage (10) for tuning a television broadcast channel, a video intermediate frequency amplifier stage (11) for amplifying a video signal of a channel tuned by the tuner stage; In order to transmit the audio intermediate frequency amplifier stage 15 for extracting and amplifying the audio intermediate frequency signal from the output of the image intermediate frequency amplifier stage, and to transmit the output of the audio intermediate frequency amplifier stage to the speech matrix stage 24, a first BPF 16 of 4.5 MHz is provided. ), A first signal path comprising a first FM detector 18 and a first light stage 19, and a second BPF 20 and a second FM detector 22 and a second light stage 23 at 4.724 MHz. A pilot detection stage 26 for determining whether a pilot signal is present on a second signal path and a voice intermediate frequency signal passing through the second BPF 20, and controlling the matrix stage to detect the pilot Files from tier In accordance with the presence or absence of a pilot signal from the pilot detection stage and the frequency size of the detected pilot to make the first and second equalization stages 19 and 23 at a predetermined voice equalization level, And a microcomputer 27 for discriminating stereo mode / multiple voice mode / monaural mode.