KR930002682Y1 - Picture image recording circuit - Google Patents

Abstract

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Description

High definition video recording circuit

1 is a conventional video recording circuit diagram.

2 is an input / output signal frequency characteristic diagram of the circuit shown in FIG.

3 is a circuit diagram of an embodiment according to the present invention.

4 is an output characteristic diagram of the frequency characteristic control circuit in the circuit shown in FIG.

* Explanation of symbols for main parts of the drawings

110: FM modulation means 110: low pass modulation means

120: frequency characteristic control circuit 40: mixer

130: frequency characteristic control circuit

The present invention relates to an image recording apparatus for recording image information on a recording medium, and more particularly, to an image recording circuit for improving image quality of a video signal and recording the same on a recording medium.

In general, an image recording apparatus includes a mechanism unit for driving a recording medium, a servo circuit unit for controlling the mechanism unit, and an image recording circuit for modulating the image signal on the recording medium.

The video recording circuit will be described on the assumption that the circuit shown in FIG. 1 is a video recording apparatus for the National Television System Commitee (NTSC) broadcasting system. An automatic gain control circuit (AGC) for inputting a video signal through the input terminal IP maintains a constant gain difference of the video signal input through the input IP and outputs the same. The low pass filter 11 detects and outputs only the luminance signal distributed under 3MHZ of the output of the AGC 10. The clamp circuit 12 clamps and outputs the luminance signal input from the first low pass filter 11 to a predetermined level, and a detail enhancer 13 connected in series to the output terminal of the clamping circuit 12. ) And the sub-emphasis circuit 14 emphasizes and outputs a low level high frequency component of the clamped luminance signal that is the output of the clamping circuit 12.

The main emphasis circuit 15 emphasizes the output signal of the sub-emphasis circuit 14 irrespective of magnitude, and the black and white clip circuit 16 provides the maximum back level and the reference among the outputs of the main emulation circuit 15. 100% of the lateral level of the 140 IRE video signal; The output of the main emulation circuit 15 is limited so as to be 45%. The first modulator 17 modulates the output of the black and white clip circuit 16 into a carrier signal having a deviation of 1 MHZ and a frequency of 3.4 MHZ and applies the FM modulated luminance signal to the high frequency filter 30. The high pass filter 30 removes a low pass portion of the output of the first modulator 17 and supplies it to the mixer 40. The automatic color control (ACC) circuit 20 maintains and outputs a constant amplitude of the video signal input through the input terminal IP, and the band filter 21 outputs the ACC circuit 20. In order to detect the color signal distributed in the band of 0.5MHZ centered on the controlled 3.58MHZ, the frequency component other than 3.58 ± 0.5MHZ of the output of the ACC circuit 20 is removed and the second modulator ( 22).

The second modulator 22 low-converts the output of the bandpass filter 21 to be an AM signal of 629 MHz band, and the color detector 23 checks whether there is a color signal during the output of the ACC circuit 20 and accordingly results. Generate a color detection signal with a constant logic. An automatic color killer circuit (hereinafter referred to as an ACK) circuit 24 outputs the output of the second modulator 22 according to the logic state of the color detection signal applied to the color detector 23. 25), or the second low pass filter 25 removes a frequency component of 1.2 MHZ or more from the output of the ACK circuit 24 and supplies it to the mixer 40. Then, the mixer 40 mixes the output of the second low pass filter 25 and the output of the high pass filter 30 and supplies it to the head HD through the recording amplifier 50, and the head HD receives the recording amplifier. The modulated video signal supplied from the mixer 40 through 50 is recorded on the recording medium.

In the case of a color image signal including a luminance signal having a bandwidth of 0 to 3 MHz and a color signal of a frequency band having a deviation of 0.5 MHz based on 3.58 MHz, the luminance signal has a maximum back level of 140 IRE. FM is modulated to have a deviation of up to 1MHZ based on a carrier frequency of 3.4MHZ, and the color signal is low-modulated to an AM signal in a band of 629KHZ ± 0.5MHZ. In this case, as shown in FIG. 2B, near the 1 MHZ, the FM-modulated luminance signal and the low-band-converted color signal overlap each other, causing mutual interference between the two signals. Luminance and color bits, i.e., a moire beat phenomenon. Therefore, the high frequency filter removes the frequency component around 1 MHZ that interferes with the color signal with the high frequency filter and the high frequency color signal component with the second low filter with respect to the color signal. However, in the case of FIG. 1, the characteristic of the high frequency filter is that when the cutoff frequency is moved toward the high frequency, the outline of the screen collapses, the horizontal resolution falls, and the above-mentioned bit phenomenon occurs when the frequency is moved toward the low frequency.

When the black and white video signal including only the luminance signal having a band of 0 to 3MHZ is supplied to the input terminal IP, the black and white video signal is FM-modulated like the luminance signal of the color video signal. The screen cannot be displayed. Therefore, the conventional video recording circuit is manufactured by using the frequency characteristic of the color image signal and the frequency characteristic of the black and white image signal. Therefore, in the case of the color image signal, the color balance cannot be exactly balanced. The luminance component of the high frequency component has been removed, so that a delicate screen cannot be displayed. Accordingly, an object of the present invention is to provide a high-definition video recording circuit capable of accurately adjusting color balance and having a fine outline by adjusting frequency characteristics of a luminance signal according to a frequency distribution of color signal components of a video signal to be recorded in a recording and reproducing apparatus. .

In order to achieve the above object, the present invention provides an FM modulation means for FM modulation by separating a luminance signal from a video signal, a low pass modulation means for amplitude-modulating low frequency by separating and detecting a color signal from an image signal, and an output of the FM modulation means. A mixer for mixing the output of the low pass modulation means, a low pass filter for removing an output of a predetermined frequency or more out of the output of the low pass conversion means, and recording the output of the mixer on a recording medium A frequency characteristic adjusting means connected between the head, the mixer and the FM modulating means to adjust the output and the frequency band of the FM modulating means according to the type of the video signal, and near the low range of the luminance signal of the low frequency converting means. By determining the presence or absence of the distributed color signal by the frequency specific control means for controlling the frequency characteristic adjusting means In addition, it is characterized in that the color balance of the image signal is precisely balanced and the frequency characteristic of the image signal is adjusted so as not to lose the delicate contour components of the image signal.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 3 is a circuit diagram of an embodiment according to the present invention, which is an image recording circuit for recording an image signal for an NISC broadcasting method on a recording medium. The FM modulating means 100 comprises an AGC circuit 10 and a first low pass filter 11, a clamp circuit 12, and a detail enhancer 13 having the same function as indicated in FIG. The sub-emphasis 14, the main emulation 15, the black and white clip circuit 16, and the first modulator 17. The low pass converting unit 110 is composed of an ACC circuit 11, a band filter 21, a second modulator 22, a color detector 23, and an ACK circuit 24 having the same function as indicated by the same reference numeral in FIG. have. The frequency characteristic adjusting means 120 includes a first high filter 30 and a second high filter 31 connected in parallel between the mixer 40 and the FM modulating means 100, the mixer 40, and the It consists of a control switch SW connected between the first and second high pass filters.

The low pass filter 25 has the same function as the first low pass filter 25 in the first diagram, and is connected between the low pass conversion means 110 and the mixer. The frequency characteristic control means 130 integrates the band filter 60 for detecting a color signal distributed near the low frequency of the luminance signal among the outputs of the low frequency conversion means 110 and the output of the band filter 60. Compares the output of the band filter 60, the integrator 61 for integrating the output of the band filter 60, and the output of the integrator 61 with the reference voltage of the reference power supply 62, Comparator 64 for removing the control switch (SW). The head HD is connected to the output terminal of the mixer 40 through the recording amplifier 50. FIG. 4 is an output frequency characteristic diagram for the frequency characteristic adjusting means 120 and the frequency characteristic controlling means 130 in the circuit shown in FIG. 3, and FIG. 4A is a frequency characteristic diagram of the first high pass filter 30, 4b is a frequency characteristic diagram of the second high frequency filter 31, FIG. 4c is a frequency characteristic diagram of the bandpass filter 60, and FIG. 4d is an output waveform diagram of the integrator 61. FIG. Next, the operation of the circuit shown in FIG. 3 will be described in detail in conjunction with the characteristics shown in FIGS. 2 and 4.

The FM modulator 100 separates only the luminance signal among the image signals input through the input terminal IP, and then modulates the FM signal to supply the first high pass filter 30 and the second high pass filter 31. The low pass modulator 110 separates the color signal from the video signal input through the input terminal IP, and then modulates the amplitude signal to have a low frequency to supply the low pass filter 25 and the band pass filter 60. The low pass filter 25 removes a noise component of a predetermined frequency (ie, 1.2 MHZ) or more out of the low frequency converted color signals output from the low conversion unit 110 and supplies it to the mixer 40.

The new operation of the low frequency conversion means 110 and the FM modulating means 100 is the same as the description of FIG. The frequency characteristic control means 130 determines whether there is a color signal located near the low frequency of the luminance signal among the output signals of the low frequency conversion means 110, and controls the frequency characteristic control signal having a high or low logic state according to the result. It is applied to (SW), which will be described in detail as follows. The band filter 60 detects a color signal of a predetermined frequency band from the frequency of 1 MHz as shown in FIG. 4C and supplies the output signal of the low frequency conversion unit 110 to the integrator 61. The integrator 61 integrates the output of the bandpass filter 60 and supplies the integrated color signal to the non-inverting output terminal of the comparator 63 as shown in FIG. 4D. The comparator 63 compares whether the integrated color signal supplied to the non-inverting terminal is greater than the reference potential of the reference power supply 62 supplied to the inverting terminal, and is high when the color signal located in the low frequency band of the luminance signal exists. A frequency characteristic control signal having a state is applied to the control switch SW. On the contrary, when the signal characteristic is small, that is, when there is no color signal located near the low frequency of the luminance signal, a frequency characteristic control signal in a low logic state is applied to the control switch SW. do.

The frequency characteristic adjusting means 120 adjusts the modulated luminance signal low-pass cutoff frequency which is the output of the FM modulating means 100 according to the logic state of the frequency characteristic control signal applied from the frequency characteristic controlling means 140 and the mixer 40. To send). This will be described in detail as follows. The control switch SW has the high logic state when the frequency characteristic control signal applied from the comparator 63 has a high logic state indicating that the frequency of the color signal included in the video signal being supplied on the input terminal IP is widely distributed. The output of the high frequency filter 20 is transmitted to the mixer 40. On the contrary, the frequency characteristic control signal applied from the comparator 63 is narrowly distributed in the frequency of the color signal included in the video signal being supplied on the input terminal IP. The output of the second high pass filter 31 is transmitted to the high mixer 40 when it has a low logic state indicating that it is. The first high frequency filter 30 filters the modulated luminance signal supplied from the FM modulating means 100 so as not to cause interference with the low-converted color signal, as shown in FIG. Only the modulated luminance signal is transmitted to one selection contact of the control switch SW. In addition, the second high frequency filter 31 has a frequency band of the FM-modulated luminance signal flowing from the FM modulating means 100 so as to extend to the vicinity of 1 MHZ, which is a frequency range of the low frequency-converted color signal. The luminance signal is transmitted to the other selection contact on the other side of the control switch SW.

The output signal of the second high pass filter 31 has a frequency characteristic that is higher than the cutoff frequency of 1 MHz as shown in FIG. As a result, the frequency characteristic adjusting means 120 receives a color image signal including a color signal distributed in the vicinity of the luminance signal (1 MHZ to 1.5 MHZ) through the input terminal IP by the output signal of the frequency characteristic controlling means 130. When removing the frequency component of less than 1.5MHZ of the output of the FM modulation means 100 to prevent the interference of the low-modulated color signal of the FM modulated luminance signal to eliminate the bit phenomenon of the screen, on the contrary, the input stage (IP) When the color image signal including the color signal distributed only below the low frequency of the luminance signal and the black and white image signal is introduced, the output of the FM modulator 100 is extended to the frequency region of the low frequency converted color signal to reproduce the detailed screen. .

The mixer 40 mixes the output of the frequency characteristic adjusting means 120 and the output of the low pass filter 25 and records the recording medium through the recording amplifier 50 and the head HD.

As described above, the present invention adjusts the low-pass cutoff frequency of the luminance signal according to the frequency distribution state of the color signal, thereby preventing interference between the low-converted color signal and the FM-modulated luminance signal in the case of a color image signal having a wide frequency band of the color signal. It is possible to accurately maintain the balance and to reproduce the delicate screen by extending the frequency region of the FM-modulated luminance signal to the low-conversion color signal region in the case of a color image signal and a monochrome image signal having a narrow frequency band of the color signal.

Claims (4)

A recording and reproducing apparatus, comprising: FM modulation means for FM modulation by separating a luminance signal from a video signal, low frequency modulation means for detecting and separating a color signal from a video signal, and amplitude modulating to a low frequency, an output of the FM modulation means, and a low frequency modulation A mixer for mixing the output of the means, a low pass filter connected between the low frequency modulation means and the mixer to remove an output above a certain frequency of the output of the low frequency conversion means, a head for recording the output of the mixer on a recording medium; A frequency characteristic adjusting means connected between the mixer and the FM modulating means for adjusting the frequency band of the output of the FM modulating means according to the type of the video signal, and distributed to the low frequency attenuation of the luminance signal during the output of the low converting means; It is composed of a frequency characteristic control means 130 for controlling the frequency characteristic adjusting means by determining the presence or absence of a color signal High-quality video recording circuit, characterized in that the color balance is precisely balanced and the frequency characteristic of the video signal is adjusted so as not to lose the delicate contour components of the video signal. According to claim 1, wherein the frequency characteristic adjusting means 120 is at least two or more high frequency filters 30, 31 having different low-pass frequency characteristics connected in parallel between the mixer 40 and the FM modulating means 100. And the high pass filter 30, 31 and the mixer 40 are selectively connected to the high pass filter 30, 31 by the output of the frequency characteristic control means 130. And a control switching means (SW) for connecting to the high definition recording circuit. 3. The high definition recording circuit according to claim 2, wherein the low pass frequencies of the high pass filters (30, 31) are arranged in a frequency band of the high pass component of the color signal overlapping with the low pass component of the luminance signal. [3] The band filter 60 of claim 2, wherein the frequency characteristic control means 130 detects a color signal distributed near the low frequency of the luminance signal during the output of the low frequency conversion means 110. A high quality recording circuit comprising an integrator 61 for leveling the output of the control unit 60 and a comparing means for controlling the switching operation of the control switching means SW according to the magnitude of the output potential of the integrator 61. .