KR200143100Y1 - Satellite broadcast receiving system - Google Patents

Abstract

An object of the present invention relates to a satellite broadcasting receiving system that can receive a variety of languages (mono) in stereo with a background sound in a limited band in a multi-language broadcasting,

The object of the present invention as described above is that the first and second phase synchronizer loops for generating an oscillation frequency corresponding to the received signal by the control signal output from the microcomputer, and from the input mono signal and the first phase synchronizer loop. A first frequency mixing unit for mixing the output oscillation frequency, a second frequency mixing unit for mixing and outputting the oscillation frequency output from the input stereo signal and the second phase synchronizer loop unit, and the first and second frequency mixing This is achieved by configuring a first and second signal processing unit for filtering only the bands required for the frequency output from the unit and then performing FM demodulation and a signal mixing unit for mixing and outputting the signals output from the first and second signal processing units. It is done.

Description

Satellite broadcasting reception system

1 shows a satellite broadcast transmission format.

2 is a block diagram of a conventional satellite broadcasting reception system.

3 is a block diagram of a satellite broadcasting reception system of the present invention.

* Explanation of symbols for main parts of the drawings

3, 4: 1st, 2nd phase synchronization loop part 5, 6: 1st, 2nd frequency mixing part

7, 8: first and second signal processing unit 9: signal mixing unit

The present invention relates to a satellite broadcast reception system, and more particularly, to a satellite broadcast reception system that enables a variety of languages (mono) to be received in stereo with a background sound in a limited band in a broadcast providing a multilingual service.

FIG. 1 is a broadcast transmission format of satellite broadcasting in Europe. As shown here, one main sound (mono) and up to four sub sounds (stereo) can be transmitted. Up to nine sounds can be transmitted simultaneously.

When transmitting in such a broadcast transmission format, a conventional satellite broadcast receiving system amplifies a high frequency signal received by a satellite broadcasting antenna BA, mixes it with a local oscillation frequency, and then detects an intermediate frequency signal. 100, an image processing unit 101 for amplifying and demodulating the image intermediate frequency signal output from the tuner 100, and a control signal output to the microcomputer 102 to generate an oscillation frequency corresponding to the reception frequency. A phase mixing loop 103, a frequency mixing section 104 for mixing and outputting an audio intermediate frequency signal output from the tuner 100 and an oscillation frequency output from the phase synchronization loop 103, and the frequency mixing Output from the first and second filter units 105 and 106 and the first and second filter units 105 and 106 for filtering and outputting only the required bands of the frequencies output from the unit 104, respectively. Each signal to the original signal First and second demodulators 107 and 108 for outputting and outputting the first and second demodulators 107 and 108, and third and third filters for low-pass filtering the signals output from the first and second demodulators 107 and 108, respectively. It consists of four filter parts 109 and 110.

When explaining the operation and effects of the present invention configured in detail as described above, the composite video signal is received through the satellite broadcasting antenna (BA), the tuner 100 amplifies the received composite video signal to a predetermined level and mixed with the local oscillation frequency The intermediate frequency signal is detected at the mixed frequency, and the image intermediate frequency signal is applied to the image processing unit 101 and the audio intermediate frequency signal is applied to the frequency mixing unit 104.

The image processor 101 amplifies the image intermediate frequency signal output from the tuner 100 to a predetermined level and demodulates the amplified image intermediate frequency signal into an original signal and displays the same in the CRT.

On the other hand, the microcomputer 102 recognizes the voice intermediate frequency signal output from the tuner 100 and applies the control signal according to the phase synchronization loop 103, and the phase synchronization loop 104 is a microcomputer 102 The oscillation frequency is applied to the frequency mixing section 104 by the control signal output from the controller.

Accordingly, the frequency mixing unit 104 mixes and outputs the audio intermediate frequency signal output from the tuner 100 and the oscillation frequency output from the phase synchronization loop unit 103. After band filtering through the second filter unit 105 and 106, it is applied to the first and second demodulation unit 107 and 108, respectively.

The first and second demodulators 107 and 108 demodulate the signals filtered by the first and second filter units 105 and 106 into original signals, respectively. Low-pass filtering is performed through the fourth filter unit 109 and 110, and the satellite broadcasting is received by being transmitted to the speaker.

However, such a conventional satellite broadcasting reception system has a problem in that it is impossible to receive only four languages when transmitting stereo broadcasts to different countries with one satellite in the current broadcasting system.

Accordingly, an object of the present invention is to provide a satellite broadcasting reception system capable of receiving various languages (mono) in stereo with a background sound in a limited band in providing a multilingual service.

The object of the present invention as described above is to generate an oscillation frequency corresponding to the received signal by the control signal output from the microcomputer, the first phase and the second phase synchronizer loop part, and the input mono signal and the first phase synchronizer loop part. A first frequency mixing unit for mixing the output oscillation frequency, a second frequency mixing unit for mixing and outputting the oscillation frequency output from the input stereo signal and the second phase synchronizer loop unit, and the first and second frequency mixing This is achieved by configuring a first and second signal processing unit for filtering only the bands required for the frequency output from the unit and then demodulating and outputting the FM, and a signal mixing unit for mixing and outputting the signals output from the first and second signal processing units. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a satellite broadcast receiving system of the present invention. As shown in the drawing, a tuner for amplifying a composite video signal received by a satellite broadcasting antenna (BA) and mixing it with a local oscillation frequency and detecting an intermediate frequency at the mixed frequency ( 1), an image processing unit 2 for amplifying, demodulating and outputting an image intermediate frequency signal output from the tuner 1, and a control unit for generating an oscillation frequency corresponding to a reception signal by a control signal output from a microcomputer. First and second phase synchronizer loops 3 and 4 and a first frequency mixer 5 for mixing and outputting frequencies output from the tuner 1 and the first phase synchronizer loop 3. A second frequency mixing unit 6 for mixing and outputting frequencies output from the tuner 2 and the second phase synchronization loop unit 4, and the first and second frequency mixing units 5, 6 Demodulate the original signal after filtering only the required bands The first and second signal processing units 7 and 8 respectively outputting the same, and the signal mixing unit 9 respectively mixing and outputting signals output from the first and second signal processing units 7 and 8 respectively. ), A voice processor 10 for processing and outputting each of the audio signals R and L output from the signal mixing unit 9, and an audio signal output from the voice processor 10. An audio amplifier section 11 amplifies to a level and outputs the speaker SP1 and SP2.

The first signal processing means includes a first filter unit 7a for filtering and outputting a required band at a frequency output from the first frequency mixer 5, and a signal output from the first filter unit 7a. Is configured as a first FM demodulator 7 for FM demodulation to the original signal and the second signal processor 8 filters different bands at frequencies output from the second frequency mixer 6. FM demodulating each of the signals output from the second and third filter units 8a and 8a 'and the second and third filter units 8a and 8a' into the original signals, respectively. And second and third FM demodulators 8b and 8b ', wherein the signal mixer 9 mixes and outputs signals output from the first and second FM demodulators 7b and 8b. And a second mixing section 9b for mixing and outputting signals output from the first and third FM demodulation sections 7b and 8b '.

When the composite video signal is received by the satellite broadcasting antenna BA, the tuner 1 amplifies the received composite video signal by a predetermined amount and mixes it with a local oscillation frequency. Video and audio intermediate frequency signals at the specified frequency.

The detected image intermediate frequency signal is processed by the image processor 2 and displayed on the CRT. In the audio intermediate frequency signal, the mono signal is applied to the first frequency mixer 5 and the stereo signal is the second frequency mixer 6. Is applied.

Accordingly, the microcomputer (not shown) applies control signals corresponding to the stereo and mono signals to the first and second phase synchronizer loops 3 and 4, respectively, and the first and second phase synchronizer loops described above. Units 3 and 4 apply oscillation frequencies corresponding to stereo signals and mono signals to the first and second frequency mixing units 5 and 6, respectively, by the control signals output from the microcomputer. .

The mono signal and the oscillation frequency applied to the first frequency mixing unit 5 are mixed through the first frequency mixing unit 5 and applied to the first filter unit 7a of the first signal processing unit 7. The stereo signal and the oscillation frequency applied to the frequency mixing unit 6 are applied to the second and third filter units 8a and 8a 'of the second signal processing unit 8 through the second frequency mixing unit 6. do.

The first filter unit 7a of the first signal processing unit 7 filters the required band (10.7 MHz) at the frequency output from the first frequency mixer 5, and the filtered frequency is the first FM demodulator 7b. Is demodulated through the < RTI ID = 0.0 > 1, < / RTI > and applied to the first and second mixing sections 9a, 9b of the signal mixing section 9.

In addition, the second filter unit 8a filters the required band (10.7 MHz) of the frequency output from the second frequency mixing unit 6, and the filtered frequency is demodulated by the first FM demodulator 7b so that the signal mixing unit is demodulated. It is applied to the 1st, 2nd mixing parts 9a and 9b of (9).

In addition, the second filter unit 8a filters out the required band (10.7 MHz) of the frequency output from the second frequency mixing unit 6, and the filtered signal is converted into the original signal through the second FM demodulator 8b. After demodulation, the level of the resistor R1 and the variable resistor VR1 are sequentially adjusted and then applied to the first mixing unit 9a, and the third filter unit 8a 'is removed from the second frequency mixing unit 6. Only the required band (10.52 MHz) is filtered at the output frequency, and the filtered signal is demodulated to the original signal through the third FM demodulator 8b 'and then passed to the second mixing unit 9b of the signal mixing unit 9. Is approved.

Accordingly, the first mixer 9a of the signal mixer 9 mixes the signals output from the first and second FM demodulators 7b and 8b and is applied to the voice processor 10 and the second mixer. Reference numeral 9b mixes the signals output from the first and third FM demodulators 7b and 8b 'and applies them to the audio processor 10. FIG.

The voice processor 10 processes each of the signals R and L output from the signal mixer 9 and the processed signals are amplified to a predetermined level through the audio amplifier 11 and then each. It is transmitted to the speakers SP1 and SP2 so that satellite broadcasting is received.

As described in detail above, the present invention is convenient for the user since the limited sound service can be expanded and received in stereo when satellite broadcasting is performed in one country, that is, when a program is provided in multiple languages. There is an effect that can provide.

Claims (1)

A first phase-locked loop means for generating an oscillation frequency corresponding to the received mono signal, a second phase-locked loop means for generating an oscillation frequency corresponding to the received stereo signal, and a frequency output from the first frequency mixing means A first signal processing means comprising a first filter means for filtering and outputting a required band, a first FM demodulation means for FM demodulating and outputting a signal output from the first filter means into an original signal, and a second frequency Second and third filter means for filtering different bands at a frequency output from the mixing means, and second signals for FM demodulating each signal output from the second and third filter means as original signals and outputting the respective signals; Second signal processing means including third FM demodulating means, first mixing means for mixing and outputting signals output from said first and second FM demodulating means, and said first and third FMs; And a signal mixing means comprising a second mixing means for mixing and outputting a signal output from the demodulation means.