KR910008400B1 - Auxiliary signal de-modulation circuit of ac-tv - Google Patents

Abstract

The circuit for displaying the video with high resolution and being compatible to the conventional TV with NTSC format by demodulating the sub signal and separating it to the high frequency component of the side panel signal and that of the luminance signal includes a 1st divider (110) for generating the sub signal carrier of 3.108 MHz, a phase corrector (120) for correcting the phase of the sub signal carrier, a phase detector (140) for detecting the phase difference between an oscillatator (100) and a 2nd divider (130), and a 2nd modulator (170) for demodulating the high frequency of the Y signal that is phase-locked to the output of a phase shifter (150).

Description

Auxiliary Signal Demodulation Circuit of AC-TV

1 is an auxiliary signal demodulation circuit diagram of the present invention.

(A) to (e) of FIG. 2 are signal waveforms for explanation in the present invention.

* Explanation of symbols for main parts of the drawings

100: oscillator 110: first divider

120: phase corrector 130: second divider

140: phase detector 150: ideal phase

160: first demodulator 170: second demodulator

180, 190: Low pass filter VR: Variable resistor

The present invention relates to an auxiliary signal demodulation circuit that can be used for AC = TV (Advanced Compatible-TV), and in particular, by demodulating the auxiliary signal in the transmission signal of the AC-TV, it has a higher resolution even with a conventional broadcasting method. The present invention relates to an auxiliary signal demodulation circuit of an AC-TV capable of viewing a high quality screen. In general, existing TVs are designed to meet the NTSS (National Television System Committee) method, so it is difficult to develop technology in terms of image quality. In this regard, the high-definition TV (HD-TV) system currently being developed has high resolution but is expensive. And since it is incompatible with NTSC broadcasting method, it is not commercialized yet. Therefore, AC-TV, a system having high compatibility with NTST broadcasting system, has been developed. The AC-TV is a unique transmission signal composed of a main signal suitable for the existing NTSC broadcasting system and an auxiliary signal for improving image quality. Here, the main signal is the same as the existing NTSC signal standard, but the auxiliary signal is intended to have a more precise resolution than the NTSC signal, and has a considerable high frequency component in terms of color and luminance signals. Therefore, this auxiliary signal itself does not exist in the TV currently used, but this auxiliary signal must be additionally transmitted when AC-TV signal is transmitted. In addition, the existing NTSC system has an aspect ratio of 4: 3 vertical resolution and horizontal resolution, and a luminance band of 4.2 MH _Z , whereas an AC-TV system has an aspect ratio of 5: 3 and a luminance of 6.2 MH _Z. Since it has a band, it is impossible to transmit all of the 6.2 MH _Z luminance band as a transmission channel of the conventional NTSC system. Therefore, the side panel portion generated when transmitting at the high band and 5: 3 aspect ratio of the luminance band is Multiplexed to the existing 4.2M _z band is to be transmitted.

배 분주하여 3.108MH_Z신호를 출력시키는 제1분주기(110)를 통해 상기 위상감지기(140)의 출력에 따라 분주신호의 위상을 교정하는 위상교정기(120)에 연결되고 상기 위상 교정기(120)는 상기 위상교정기(120)의 출력을

배 분주하여 3.58MH_Z신호로 환원시키는 제2분주기(130)를 통해 상기 발진기(100)의 출력과 제2분주기(130)의 출력을 비교해 위상차를 감지하는 위상감지기(140)에 연결함과 아울러 상기 위상교정기(120)의 출력위상을 90°이상시키는 이상기(150) 및 변조되어 수신되는 측면 구획신호를 복조하는 제1복조기(160)에 연결하고 상기 이상기(150)는 변조된 휘도신호의 고역성분을 복조하는 제2복조기 (170)에 연결하며 보조신호입력단자(IN)는 상기 제1복조기(160)를 통해 1.1MH_Z대역의 측면 구획신호를 필터링(filtering)시키는 저역통과필터(190)에 연결함과 아울러 상기 제2복조기(170)를 통해 1.1MH_Z대역의 휘도신호 고역성분을 필터링시키는 저역통과필터(180)에 연결하여 구성한 것이다.In view of the above, the present invention demodulates an auxiliary signal transmitted by modulating at least a right angle among AC-TV transmission signals and extracts a high frequency component of a side partition signal and a luminance signal. The present invention will now be described in detail with reference to the accompanying drawings, which are intended to enable the user to watch a screen having a precise resolution. As shown in FIG. 1, the oscillator 100 generating a signal of 3.58MH _Z is connected to the phase detector 140 to prevent phase shift and simultaneously outputs the output of the oscillator 100.

The phase corrector 120 is connected to a phase corrector 120 for correcting the phase of the divided signal according to the output of the phase detector 140 through a first divider 110 for distributing and outputting a 3.108MH _Z signal. Is the output of the phase corrector 120

The output of the oscillator 100 and the output of the second divider 130 are compared to the phase detector 140 that detects a phase difference through a second divider 130 that divides and reduces the signal to a 3.58MH _Z signal. In addition, the phase corrector 120 is connected to an ideal phase 150 for outputting an output phase of 90 ° or more and a first demodulator 160 for demodulating a modulated received side partition signal, and the ideal phase 150 is a modulated luminance signal. connection of the high-frequency component to the second demodulator 170 for demodulating and auxiliary signal input terminal (iN) is a low-pass filter to the first demodulator 160 filters (filtering) a side section in the signal band through 1.1MH _Z ( 190 and the low pass filter 180 for filtering the high frequency component of the luminance signal of the 1.1MH _Z band through the second demodulator 170.

Referring to the effect of the present invention configured as described in more detail as follows. When the auxiliary signal separated from the main signal is transmitted through the auxiliary signal input terminal IN, the auxiliary signal is demodulated by the first and second demodulators 160 and 170. Since the color subcarrier frequency of the call and the carrier frequency of the auxiliary signal are not equal to each other, in the present invention, the reference subcarrier of the auxiliary signal can be made by dividing the color carrier of the main signal.

배 분주시켜 3.108MH_Z주파수 신호로 만들어 주며 상기와 같이 만들어진 분주신호는 위상교정기(120)에 인가되어 위상감지기(140)로부터 인가되는 신호에 의해 위상이 교정된다. 또한 상기 위상교정기(120)의 출력신호는 제2분주기(130)로 인가되어

배 분주됨으로써 다시 3.58MH_Z신호로 주파수 변환되어 위상마지기(140)로 잉가되고 상기 위상감지기(140)에서 발진기(100)의 출력신호와 상기 제2분주기(130)의 출력신호의 위상을 비교하여 위상차를 감지함으로써 상기 위상감지기(140)의 출력신호에 의해 상기 위상 교정기(120)가 동작되도록 하여 신호의 위상변동을 막을 수 있도록 하는데 이때 상기 위상감지기(140)로 인가되는 입력신호의 주파수가 높으므로 상기 위상감지기(140) 내부의 분주기를 이용해 일정 레벨까지 주파수를 낮춘다음 위상을 감지한다. 즉, 여기서 위상교정기와 그리고 위상감지기의 동작원리를 제2도에 의하여 좀 더 상세히 설명하면 다음과 같다.That is, when generating a color carrier by generating a signal of 3.58MH _Z frequency with the oscillator 100, the color synchronization signal (Color Burst) sent from the transmitting side is put into the oscillator 100 so that the phase is completely in phase with the transmitting side. The color subcarriers of the main signal can be made, and the color subcarriers made as described above are applied to the phase detector 14 and the first divider 110, respectively. The first divider 110 is for making reference subcarriers of the auxiliary signal. Input 3.58MH _Z frequency signal

The frequency divider is divided into a 3.108 MH _Z frequency signal, and the divided signal generated as described above is applied to the phase corrector 120 to correct a phase by a signal applied from the phase detector 140. In addition, the output signal of the phase corrector 120 is applied to the second divider 130

The frequency division is again performed by frequency division to 3.58MH _Z signal, which is surplus to the phase marginer 140, and the phase detector 140 compares the phase of the output signal of the oscillator 100 and the output signal of the second divider 130. By detecting the phase difference, the phase corrector 120 is operated by the output signal of the phase detector 140 so as to prevent the phase shift of the signal. In this case, the frequency of the input signal applied to the phase detector 140 Since it is high, the frequency is lowered to a predetermined level by using a frequency divider inside the phase detector 140, and then the phase is detected. That is, the operation principle of the phase corrector and the phase detector will be described in more detail with reference to FIG. 2 as follows.

배 분주된 신호(b)와의 위상이 위상감지기(140)에 의해 비교되어진다. 따라서 위상감지기(140)에서는 두 신호(a),(b)의 위상차에 해당하는 값만큼(제2도 (c)) 출력하여 위상교정기(120)에 가해진다. 이때 상기 위상교정기(120)는 가변저항(VR)에 의해 초기치 레벨이 설정되어 있으므로 상기 위상감지기(140)로부터 출력되는 위상차에 따라 초기치 레벨보다 높거나 낮은 레벨값이 인가됨에 따라 신호 (d)와 같은 정확히 교정된 위상신호를 얻을 수 있으므로 상기 위상교정기(120)에서는 최종적으로 신호(e)와 같은 완전 일치한 위상 신호를 얻어내게 된다. 한편 상기와 같이 위상교정기(120)에서 위상교정된 보조 신호의 부반송파는 이상기(150)로 인가됨과 동시에 제1복조기(160)로 인가된다.First, as shown in FIG. 2 in which the phase of the oscillator 100 and the transmitting side are coincided with each other, the color carrier signal a is first outputted by the second divider 130.

The phase with the distributed signal b is compared by the phase sensor 140. Therefore, the phase detector 140 outputs as much as the value corresponding to the phase difference between the two signals a and b (FIG. 2C) and is applied to the phase corrector 120. At this time, since the initial value level of the phase corrector 120 is set by the variable resistor VR, a level value higher or lower than the initial value level is applied according to the phase difference output from the phase detector 140. Since the same accurately corrected phase signal can be obtained, the phase corrector 120 finally obtains a perfectly matched phase signal such as the signal e. Meanwhile, as described above, the subcarriers of the auxiliary signal phase-corrected by the phase corrector 120 are applied to the phase shifter 150 and to the first demodulator 160.

In this case, the first demodulator 160 in the output and the phase-locked to only a side section signal of the phase corrector 120 from the auxiliary signal input and outputs the demodulated signal is demodulated because the band 1.1MH _{Z Z} 1.1MH band When the filter is filtered through the low pass filter 190, only the demodulated side partition signal is output, and the output signal of the phase corrector 120 applied to the phase shifter 150 is 90 ° or more in phase and thus the second demodulator 170. Since the second demodulator 170 demodulates and outputs the high frequency component of the luminance signal phase synchronized with the output of the phase shifter 150 among the input auxiliary signals, the demodulated signal is low in the 1.1MH _Z band. Since the filter is filtered through the pass filter 180, the luminance signal of the demodulated high frequency component may be obtained.

As described above, the present invention does not require a special method and has compatibility with existing broadcasting methods, so that the present invention has an effect that is easy to use, and has a precise resolution due to an auxiliary signal. will be.

Claims (1)

The transmitting side and the phase matching is 3.58MH _Z and oscillator 100 to create the color subcarrier frequency, the frequency division by the _Z 3.58MH saekbu carrier of the first branch making cycle to the secondary signal of the carrier 3.108MH _Z (110), phase a second frequency divider (130 to frequency convert the carrier wave of the auxiliary signal _Z to 3.108MH 3.58MH _Z for the phase corrector 120 for correcting the phase of the sub-carrier signal, the phase detection according to an output of the detector 140 And 3.108MH _Z output from the phase detector 140 and the phase corrector 120 to detect the phase difference by comparing the output phases of the lighter 100 and the second divider 130 to prevent phase shift. The auxiliary demodulator 160 for demodulating an auxiliary signal carrier phase of 90 degrees or more, a first demodulator 160 for demodulating a side division signal phase-synchronized with the output of the phase corrector 120 among the input auxiliary signals, Phase shift with the output of the phase shifter 150 in the signal A second demodulator 170 for demodulating the high frequency component of the luminance signal, and a low pass filter 190 and 180 for filtering the outputs of the first and second demodulators 160 and 170 to remove noise. The auxiliary signal demodulation circuit of the AC-TV, characterized in that configured to watch a high-resolution screen with improved image quality.

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