KR930002607B1 - Tv channel modulation circuit - Google Patents

Abstract

A television channel modulation circuit improves the frequency stability of the RF channel by using the PLL circuit. The circuit comprises means (1,2) for processing and modulating the input image signal, means (3,4) for processing and modulating the input voice signal, a mixer (5) for mixing the image carrier frequency and the voice signal from the FM modulator (4), a combiner (6) for combining the modulated image signal and the voice carrier frequency from the mixer, a RF mixer (7) for mixing the output of the combiner and the local oscillation frequency (RFLOF), and the first/second frequency modulation control means (20,22).

Description

TV channel modulation circuit

1 is a conventional television channel modulation circuit.

2 is a television channel modulation circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Image signal processor 2: Image signal modulator

3: audio signal processing unit 4: FM modulator

5: Mixer 6: Combiner

7: RF Mixer 8: First Local Oscillator

9: first divider 10: first phase detector

11: second local oscillator 12: reference oscillator

13: 2nd divider 14: 2nd phase detector

15: RFLO 16: the third divider

17 variable frequency divider 18 third phase detector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to channel modulation circuits for television broadcasting equipment, and in particular, a local oscillator for converting an intermediate frequency modulation and a radio frequency (hereinafter referred to as RF) TV channel frequency into a phase locked loop ( Phase Locked Loop (hereinafter referred to as PLL) and a circuit which can be controlled simultaneously by a single reference oscillator.

In general, a television channel modulation system is configured such that a local oscillator for converting a processed audio or video signal into an intermediate frequency and a local oscillator for converting the frequency converted signal into a signal of a pre-assigned RF channel band are operated separately. . In addition, an oscillation circuit that independently oscillates the carrier frequency of an audio signal modulated from an image carrier by an intercarrier method has been used. The intercarrier method amplifies an audio signal into the same circuit as the video signal and uses 4. 5 MHz as a second audio intermediate frequency, which is a beat signal of the difference between the audio carrier and the video carrier generated as a result of the image detection. Is an audio signal reception method of a television.

1 is a conventional television channel modulation circuit diagram, which is a video signal processor 21, an image modulator 22, a local oscillator 23, a multiplier 24, an audio signal processor 25, and an FM modulator. 26, mixer 27, band filter 28, combiner 29, RF Local Oscillator (hereinafter referred to as " RFLO ") 30, mixer 31, and band It consists of the filter 32.

When the image signal Vi is input to the image signal processor 21 of FIG. 1 configured as described above, the image signal processor 21 amplifies the input image signal to a predetermined level and compensates the image signal modulator 22. Will output The video signal modulator 22 modulates the video signal input by the local oscillation signal output from the multiplier 24 and outputs it to the combiner 29. At this time, the multiplier 29 multiplies a predetermined frequency oscillated from a local oscillator (hereinafter, referred to as "LO") 23 by an integral multiple to convert the video signal to an intermediate frequency and supplies it to the image modulator 22. do.

On the other hand, the voice signal Ai is outputted from the voice signal processor 25 which amplifies the input voice signal Ai with a predetermined level and compensates for it. The voice signal output from the voice signal processor 25 is input to the FM modulator 26, and then modulated by the FM signal to the mixer 27. At this time, the mixer 27 mixes the FM modulated voice signal and the local oscillation frequency output from the multiplier 24 and inputs the intermediate frequency converted voice signal to the band filter 29.

Accordingly, it can be seen that the FM modulator 26 that inputs and modulates the audio signal Ai causes the carrier frequency to be oscillated independently from the image carrier in an intercarrier manner.

The video signal modulated by the operation of the video signal modulator 22 is applied to a combiner 29, and the audio signal intermediate frequency from the mixer 27 is passed through a band filter 28. When applied to the combiner 29, the combiner 29 synthesizes the inputted modulated video signal and the intermediate frequency audio signal into a signal that does not interfere with each other and outputs it to the mixer 31.

The mixer 31 for inputting a signal in which the modulated video signal and the audio signal are combined as described above inputs the output of the RFLO 30 for oscillating a frequency for converting the modulated signal into a signal of a band of an RF channel. Therefore, the mixer 31 mixes the two inputted frequencies and outputs them to the band filter 32 so that the band filter 32 is different from the band of the synthesized frequency (sum or difference) of the modulated two frequencies. The frequency will be attenuated. That is, only the signal of the sum or difference of the modulated two signals is output from the band filter 32 as RF.

However, in the conventional circuit as described above, the FM modulator 26 for FM modulating and outputting the audio signal is modulated in an intercarrier manner from the video carrier so that the carrier frequencies of the voice signal Ai and the video signal Vi are independently generated. Therefore, the characteristics of the audio and video signals are independent, and the local oscillator 23 and the RFLO 30 oscillate independently to affect the overall output characteristics. In order not to be affected, there is a need to individually adjust the frequency characteristics of each oscillator, and there is a problem that frequency stability is relatively low.

Accordingly, an object of the present invention is to improve frequency stability by synchronously oscillating with a local oscillation frequency for intermediate frequency modulation and frequency conversion into an allocated RF band using one high precision reference signal using a PLL to improve frequency stability and to easily adjust channel bands. It is to provide a television channel modulation circuit.

Therefore, another object of the present invention is a television channel modulation that can simultaneously control the local oscillation frequency and the frequency of the intercarrier voice signal modulation circuit for intermediate frequency modulation and frequency conversion to the allocated RF band with a single reference oscillator. In providing a circuit.

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

2 is a diagram of a television channel modulation circuit according to the present invention, which comprises a video signal processor 1 for amplifying an input video signal Vi1 to a predetermined level and compensating and outputting the same, and outputting from the video signal processor 1; A video signal modulator 2 for modulating and outputting a commercial signal to be output by a video carrier frequency Vfrq, and an audio signal processor 3 for amplifying the input audio signal Ai1 to a predetermined level and then compensating and outputting the same. And an FM modulator 4 for modulating and outputting an audio signal output from the audio signal processor 3 by an FM modulating frequency Cfreq, and the audio signal output from the FM modulator 4 to the image carrier frequency. A mixer 5 for outputting an audio carrier frequency Afreq which is a difference frequency of the two frequencies by mixing with Vfreq, and a modulated video signal output from the image modulator 2 and the mixer 5 Voice carrier output RF combiner 6 which combines and outputs frequency Afreq, and outputs the difference signal of two input signals by mixing the output of the combiner 6 and the RF channel conversion local oscillation frequency RFLOF. (7), the reference oscillator 12 which oscillates and outputs a predetermined frequency (0.25 MHz) at a reference frequency, and the voice carrier frequency Afreq, which is output from the mixer 5, are divided by the predetermined frequency. First frequency modulation control means for comparing the phase of the divided signal and the phase of the reference frequency Rfreq output from the reference oscillator 12 to generate a frequency corresponding to the phase comparison difference and to output the frequency as the FM modulation frequency Creq. (20) and generate an RF channel conversion local oscillation frequency (RFLOF) synchronized with the reference frequency (Rfreq) output from the reference oscillator (12) to provide to the combiner (6), and generate the generated RF channel conversion. Local oscillation frequency (RFLOF) And it consists of the picture carrier frequency (Vfreq) in synchronization with the reference frequency (Rfreq) in a second frequency modulation control unit 22 to be input to the video signal modulator (2).

In the configuration of FIG. 2, the first frequency modulation control means 20 divides the voice carrier frequency Afreq outputted from the mixer 5 into a predetermined frequency divider 9, and the frequency divider 9 A first phase comparator 10 and a first phase comparator 10 for outputting a phase comparison difference signal by comparing a phase output from the reference oscillator 12 and a phase of the reference frequency Rfreq outputted from the reference oscillator 12; And a second voltage controlled oscillator (hereinafter referred to as " VCO ") 11 which oscillates a frequency corresponding to the phase difference signal output from the signal and outputs the frequency at the FM modulation frequency Cfreq.

The second frequency modulation control unit 22 divides the generated image carrier frequency Vfreq into a second divider 13 for outputting a first comparison signal and the reference oscillator 12. A second phase detector 14 for inputting a reference frequency Rfreq outputted from the first comparison signal and outputting a phase difference signal corresponding to a phase difference between the two signals, and an output from the second phase detector l4 The RFLO 15 oscillating the RF channel conversion local oscillation frequency (RFLOF) corresponding to the phase difference signal to be outputted to the RF mixer 7 and the output of the RFLO 15 are divided and outputted. A phase comparison difference signal is obtained by comparing the phases of the third divider 16 and the variable divider 17 and the divided signal output from the variable divider 17 with the phases of the first comparison signal. The third phase detector 18 and the third phase detector 18 to output the negative That oscillates and outputs a video carrier frequency (Vfreq) corresponding to the signal output consists of the 1VCO (8).

First, before describing the operation of FIG. 2 according to the present invention, when the above-described video carrier intermediate frequency (Vfreq) is 45.75 MHz, and the voice carrier intermediate frequency (Afreq) is 41.25 MHz, and the frequency of the RFLO is 101 MHz. Next, a process of forming an RF channel having an image carrier of 55.25 MHz and an audio carrier of 59.75 MHz using the output of the RF mixer 7 in a difference frequency method will be described.

When a power supply voltage is supplied to a circuit as shown in FIG. 2 now, the reference oscillator 12 oscillates and outputs a reference frequency Rfreq of 0.25 MHz. At this time, the first phase detector 14 detects a phase difference by comparing the phase of the first frequency compared with the first comparison signal output from the second divider 13 and the reference frequency Rfreq and detects a phase difference signal corresponding to the detected phase difference. Output to RFLO (15). Assuming that there is no initial output of the first VCO 8, the output of the reference oscillator 12 is output from the second phase detector 14 as it is. The RFLO 15, which inputs the phase difference signal output from the second phase detector 14, receives the RFLOF signal of 101 MHz by the voltage of the input phase difference signal from the RF mixer 7 and the third divider 16. )

In this case, when the total frequency division ratio of the third frequency divider 16 and the variable frequency divider 17 is set to 404, the third phase detector 18 may output an output frequency of the variable frequency divider 17 and a second frequency divider ( The phase difference signal corresponding to the phase difference is output to the first VCO 8 by comparing the frequency phase with the output frequency of 13). Accordingly, the first VCO 8 oscillates an image carrier intermediate frequency Vfreq of 45.75 MHz in response to the voltage of the phase difference signal output from the third phase detector 18 and outputs the generated image carrier modulator 2 to the image signal modulator 2. As described above, when the first VCO 8 oscillates the image carrier intermediate frequency Vfreq of 45.75 MHz, when the second divider 13 oscillates the image carrier intermediate frequency Vfreq, the second divider 13 Divides the image carrier intermediate frequency Vfreq by the frequency division ratio 183 divided by the reference frequency Rfreq, and outputs the frequency to the second and third phase comparators 14 and 18 at 0.25 MHz.

By the above operation, the second phase detector 14 receives the first comparison signal (frequency of about 0.25 MHz) output from the second divider 13 and the reference frequency output from the reference oscillator 12. The phase difference of Rfreq) (0.25 MHz) is detected and output. Therefore, the RFLO 15 outputs the RFLOF corresponding to the change of the phase difference signal output from the second phase detector 14.

When the image signal Vil is input to the image processor 1 in the above state, the image signal processor 1 compensates the input image signal Vil and outputs it to the image signal modulator 2. When the image signal Vil processed as described above is input to the image signal modulator 2, the image modulator 2 is oscillated and output from the first VCO 8 by the operation as described above. Vfreq) Amplitude modulates the Youngsan time signal Vi1 into a band of 45.75MHz by 45.75MHz and outputs it to the combiner 6. At this time, the image carrier intermediate frequency Vfreq 45.75 MHz output from the first VCO 8 is controlled by the phase difference detection signal output from the third phase detector 18.

Meanwhile, the voice signal Ail is input to the voice signal processor 3 and amplified to a predetermined level and then compensated. The processed voice signal Ail is input from the first VCO 11 to the FM modulator 4 which inputs an FM modulation frequency Cfreq of 4.5 MHz, which is output by an operation described later. At this time, the FM modulator 4 modulates the input voice signal Ail to the mixer 59 by FM modulating the FM modulation frequency Cfreq 4.5MHz output from the second VCO 11 to the center frequency. 5) is a voice carrier of 41.25MHz, which is the difference frequency of the two frequencies by mixing the FM signal input and modulated with the image carrier intermediate frequency (Vfreq) 45.75MHz as described above output from the first VCO (8) The intermediate frequency Afreq is output to the combiner 6 and the first divider 9.

In this case, the first divider 9 divides the voice carrier intermediate frequency 41.25 MHz from the voice carrier intermediate frequency Afreq by the reference frequency Rfreq in order to compare phase with the reference frequency 0.25 MHz. A frequency division of 165 is performed to output 0.25 MHz to the first phase detector 10. The first phase detector 10 converts the phase difference signal obtained by comparing the phase of the output frequency of the first divider 9 with the phase of the reference frequency Rfreq of the reference oscillator 12 as a driving signal of the second VCO 11. Output The first VCO 11 outputting the phase difference signal output from the first phase detector 10 outputs an FM modulation frequency Cfreq of 4.5 MHz to the FM modulator 4 in response to the input of the phase difference signal.

On the other hand, the combiner 6 which inputs the voice signal of the 41.25MHz voice carrier intermediate frequency (Afreq) of the video signal amplitude-modulated to the band of 45.75MHz as described above combines the two signals to the RF mixer 7 Will output In this case, the RF mixer 7 mixes an RF channel converted local oscillation frequency (RFLOF) 101 MHz output from the RFLO 15 to a difference frequency between the two input signals and the RF channel converted local oscillation frequency (RFLOF) 101 MHz. Output at RF channel frequency. In this case, when the image carrier intermediate frequency (Vfreq) coupled and output from the combiner (6) is 45.75 MHz and the voice carrier intermediate frequency (Afreq) is 41.25 MHz, when the frequency of the RFLO is 101 MHz, the difference is mixed and outputted. The RF mixer 7 outputs an RF channel frequency of 55.25 MHz for an image carrier and 59.75 MHz for an audio carrier.

Therefore, the frequency provided to the image signal modulator 2 and the local oscillation signals of the FM modulator 4 and the RF mixer 7 can both be provided as signals that are phase-locked in phase with a reference frequency of 0.25 MHz. By adjusting the period 16 and the variable divider 17, the signal of the RF channel band can be easily adjusted by changing the image carrier intermediate frequency Vfreq.

As described above, the present invention can easily adjust the RF modulation channel of the TV channel by adjusting the signal of the television RF channel as a single reference signal using a PLL, and has the advantage of improving the frequency stability and precision of the RF channel. have.

Claims (3)

The video signal processor 1 of the video that amplifies the input video signal Vi1 to a predetermined level and then compensates and outputs the video signal Vi1 and the video signal output from the video signal processor 1 to the video carrier frequency Vfyeq. The video signal modulator 2 to be modulated and output, the audio signal Ai1 to be amplified to a predetermined level, and then compensated and output from the audio signal processor 3 FM modulator 4 which modulates and outputs an audio signal by FM modulation frequency Cfreq, and an audio signal output from the FM modulator 4 by mixing with the image carrier frequency Vfreq. A mixer 5 for outputting an audio carrier frequency Afreq, which is a difference frequency of?, A modulated video signal output from the image modulator 2, and an audio carrier frequency Afreq output from the mixer 5; Combiner 6 for combining and outputting A television channel modulation circuit comprising an RF mixer (7) for mixing the output of the combiner (6) and the RF channel conversion local oscillation frequency (RFLOF) to output a difference signal of two input signals at a channel frequency. The reference oscillator 12 oscillates and outputs the reference frequency Rfreq of the predetermined frequency and the voice carrier frequency Afreq outputted from the mixer 5, and divides the predetermined divided signal and the reference oscillator 12. The first frequency modulation control means 20 and the reference oscillator 12 for comparing the phase of the reference frequency (Rfreq) output from to generate a frequency corresponding to the phase comparison difference and outputs the frequency to the FM modulation frequency (Cfreq) Generate an RF channel conversion local oscillation frequency (RFLOF) synchronized with the reference frequency Rfreq outputted from the N-channel, and provide it to the combiner 6, and divide the generated RF channel conversion local oscillation frequency (RFLOF) by a predetermined frequency. standard The video carrier frequency (Vfreq) in synchronization with the frequency (Rfreq) television channel modulation circuit for input to the video signal modulator (2). The second frequency modulation control unit 22 divides the generated image carrier frequency Vfreq into a second divider 13 for outputting a first comparison signal, and the reference oscillator. A second phase detector 14 for inputting a reference frequency Rfreq outputted from 12) and the first comparison signal to output a phase difference signal corresponding to a phase difference between the two signals, and the second phase detector 14; Outputs the RFLO 15 oscillating the RF channel conversion local oscillation frequency (RFLOF) corresponding to the phase difference signal output from the RF mixer 15 and outputs the RFLO 15 to the RF mixer 7, Comparing the phases by comparing the phases of the third divider 16 and the variable divider 17 and the divided signal output from the variable divider 17 with the phases of the first comparison signal. A third phase detector 18 for outputting a difference signal, and the third phase detector 18 The television channel, characterized in that the modulation consists of 1VCO (8) circuit for oscillating a video carrier frequency (Vfrq) corresponding to the signal outputted from the output. The frequency divider (9) according to claim 2, wherein the first frequency modulation control means (20) divides the voice carrier frequency (Afreq) output from the mixer (5) by a predetermined frequency and outputs the frequency divider (9). A first phase comparator 10 and a first phase comparator 10 for comparing a phase output from the reference oscillator 12 and a phase output from the reference oscillator 12 to output a phase comparison difference signal; And a second VCO (11) for oscillating a frequency corresponding to the phase difference signal output from the second signal and outputting the frequency at the FM modulation frequency (Cfreq).

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