KR0144732B1 - Apparatus for processing a color video signal - Google Patents

Abstract

No summary

Description

Color image signal processing device

1 is a circuit diagram showing an embodiment of the present invention.

2 is a circuit diagram showing another embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

1: camera signal processing system 2: playback signal processing system

3: Video signal recorder 6: A / D conversion circuit

7,37: switch 9: line memory

15: Encoder 16, 31: D / A conversion circuit

20: rotating head 21: magnetic tape

29: voltage controlled oscillator 32: burst gate circuit

33: low pass filter

[Industrial use]

The present invention relates to a color image signal processing apparatus suitable for use in a reproducible camera-integrated VTR.

[Overview of invention]

The present invention relates to a color image signal processing apparatus suitable for a VTR of a camera type that is capable of reproducing. In a camera signal processing system, a signal from an image pickup unit is supplied to a line memory, and a luminance signal and a luminance signal are based on a delay signal obtained from the line memory. Forming a carrier color signal, outputting the luminance signal as it is, and outputting the carrier color signal through an encoder; In the reproduction signal processing system, the reproduction luminance signal and the reproduction carrier color signal obtained by scanning the recording medium by the magnetic head and including the crosstalk component from the adjacent track are separated, and the reproduction luminance signal is demodulated. Decode and supply at least one of a reproduction luminance signal and a reproduction carrier color signal to the line memory to remove the crosstalk component so that the reproduction luminance signal is output as it is, and the reproduction carrier color signal is output through the encoder; By sharing the line memory, encoder, and the like of the camera signal processing system with the reproduction signal processing system, it is possible to simplify the circuit configuration, reduce the size, reduce the cost, reduce the power consumption, and easily cope with characteristics such as shift reproduction.

[Prior art]

In a conventional reproducible camera-integrated VTR, camera signal processing at the time of recording and reproduction signal processing at the time of reproduction are performed in completely independent blocks. Therefore, in the camera signal processing system which performs the camera signal processing at the time of recording, a delay line of 1H or more horizontal period (1H) or more is used for the vertical processing of the carrier color signal and for aperture control of the luminance signal. .

On the other hand, in a reproduction signal processing system that performs reproduction signal processing during reproduction, delay lines of one horizontal period or more are used for crosstalk component removal of luminance signals, dropout compensation, and crosstalk removal of carrier color signals.

In addition, devices requiring a delay line as a line memory in a camera signal processing system are generally limited to those having a complementary colors checkered filter and an aperture control circuit.

[Problem to Solve Invention]

Therefore, in the case of the conventional reproducible camera-integrated VTR as described above, since the delay line is longer than one horizontal period in the camera signal processing system and the reproduction signal processing system, respectively, the number of delay lines is large, and thus the circuit configuration is complicated. In addition, the mounting space is increased, the cost is high, and the power consumption is high.

In addition, signal processing is complicated in the conventional color-undersystem carrier color signal processing, and a large number of memories are required to change A / D in the form of subcarriers (3.85 MHz or 4.43 MHz). In addition, there are drawbacks such as difficulty in coping with characteristics such as shift reproduction.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and a comb filter composed of a line memory of a camera signal processing system by demodulating a reproduction luminance signal, decoding a reproduction carrier color signal, and converting at least one of the two signals into a line memory of a camera signal processing system. It is to provide a color image signal processing apparatus that can eliminate the above-mentioned drawback by passing.

[Means for solving the problem]

The apparatus for processing color image signals according to the present invention supplies a camera signal from the imaging section 4 to a line memory, and forms a luminance signal and a carrier color signal based on the delay signal obtained in the line memory 9. A camera signal processing system 1 for outputting the luminance signal as it is and outputting the carrier color signal through the encoder 15; The reproduction luminance signal is demodulated and the reproduction carrier color signal is separated by reproducing the reproduction luminance signal and the reproduction carrier color signal including the crosstalk component from adjacent tracks obtained by scanning the recording medium 21 by the magnetic head 20. Decodes and supplies at least one of the reproduction luminance signal and the reproduction carrier color signal to the line memory 9 to remove the crosstalk component, outputs the reproduction luminance signal as it is, and reproduces the carrier color signal. In addition to the reproduction signal processing system 2 outputted through the encoder, the encoder 15 of the camera signal processing system 1 is configured to modulate the low-frequency conversion carrier signal with the carrier color signal during recording.

[Action]

In the camera signal processing system 1 which performs camera signal processing at the time of recording, the signal from the imaging unit (ie, CCD imager) 4 is supplied to the line memory 9 via the A / D conversion circuit 6. And the upper and lower lines of the aperture control signal and the carrier color signal of the luminance signal based on the through-signal (OH), the 1 horizontal period (1H) delay signal, and the 2 horizontal period (2H) delay signal obtained here. An interpolation signal from the digital signal, and a luminance signal and a carrier color signal are formed based on these signals, and the luminance signal is output through the D / A change circuit 11, and the carrier color signal is encoded by the encoder 15 and D. Output via the / A conversion circuit 16.

On the other hand, in the reproduction signal processing system 2 which performs reproduction signal processing during reproduction, the reproduction luminance signal including the crosstalk component from the adjacent tracks obtained by scanning the recording medium 21 by the magnetic head 20 and The reproduction carrier color signal is separated, and the reproduction luminance signal is demodulated, and the reproduction carrier color signal is decoded by the A / D conversion circuit 6 to transmit at least one of the reproduction luminance signal and the reproduction carrier color signal to the line memory 9. The crosstalk component is removed by supplying to the comb filter formed by the addition circuit 30, and the reproduction luminance signal is output as it is, and the reproduction carrier color signal is output through the encoder 15 and the D / A conversion circuit 16. Accordingly, at least the line memory 9, the encoder 15, and the like of the camera signal processing system 1 can be shared with the reproduction signal processing system 2, thereby greatly simplifying and miniaturizing the circuit configuration and reducing the cost. In addition, the power consumption can be reduced, and the number of memories of the line memory can be reduced, and it is easy to cope with characteristics such as shift reproduction.

EXAMPLE

Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 and 2.

1 shows a first embodiment of the present invention, where 1 is a camera signal processing system, 2 is a playback signal processing system, and 3 is a video signal recording system. At the time of recording, the imaging signal from the CCD imager 4 is supplied to the A / D conversion circuit 6 through the contact a of the switch 5 and converted from an analog signal to a digital signal. At this time, the switch 7 is connected to the contact a so that the sampling clock is supplied from the timing generator 8.

A signal from the A / D change circuit 6 is supplied to the line memory 9 to form a through-signal (OHD), a 1H delay signal 1HD, and a 2H delay signal 2HD; In addition, it is supplied to the gamma correction circuit 10, the aperture control signal of the luminance signal is formed, accordingly the aperture control and gamma correction in the gamma correction circuit, and then supplied to the D / A conversion circuit 11 is supplied to the analog luminance signal It is output through the contact a of the switch 12.

The through signal, the 1H delay signal, and the 2H delay signal from the line memory 9 are supplied to the matrix white balance 13 and the gamma correction circuit 10, thereby interpolating the upper and lower lines of the carrier color signal. Is formed, and R, G, B, and signals are separated based on this interpolation signal, white balance is obtained, gamma corrected, and then supplied to the encoder 15 through the contact a of the switch 14. Thus, the carrier signal (3.58 MHz or 4.43 MHz) is modulated and encoded by the input signal (carrier color signal) here to obtain an NTSC signal or a PAL signal. This signal is supplied to the D / A conversion circuit 16 and output as an analog carrier color signal.

In this way, the luminance signal and the carrier signal output from the camera signal processing system 1 are supplied to each of the FM modulation circuit 17 and the frequency conversion circuit 18 of the video signal recording system 3.

The luminance signal supplied to the FM modulation circuit 17 is FM modulated in this circuit. In this case, the FM modulated carrier frequency is shifted by 1 / 2f _H (f _H is a horizontal frequency) per field (1 track) so that crosstalk components from adjacent tracks are in frequency interleaved relationship with the main signal component. The FM luminance signal from the FM modulation circuit 17 is supplied to one input of the addition circuit 19.

Further, the carrier color signal supplied to the frequency conversion circuit 18 changes the frequency of the FM luminance signal so that, for example, when the frequency of the subcarrier signal is NTSC system, it changes from 3.58 MHz to about 743 MHz (8 millisecond VTR). Frequency conversion to the low side. During this frequency conversion, crosstalk components from adjacent tracks are in a frequency interleaved relationship with the main signal components by so-called phase inversion (PI) or phase shift (PS) methods. The low-conversion carrier color signal is supplied to the other input side of the addition circuit 19, and is added to the FM luminance signal occupying the high frequency side, and this addition signal is supplied to the rotating head 20 which is the magnetic head so that the magnetic tape ( 21 is recorded as one inclined magnetic track per field.

Further, the rotating head 20 is actually two heads facing 180 degrees, these heads rotate in one frame period, and the magnetic tape 21 is wound inclined over a predetermined angular range along its rotational circumferential surface at a constant speed. , Is transported in a certain direction.

Next, at the time of reproduction, the reproduction signal is read out from the magnetic tape 21 by the rotating head 20, and this reproduction signal is supplied to the high pass filter 22 of the reproduction signal processing system 2 to obtain an FM luminance signal. The low pass filter 23 is supplied to the low pass filter 23 to obtain a low conversion carrier color signal.

The FM luminance signal from the high pass filter 22 is then FM demodulated by the FM demodulation circuit 24. This demodulated luminance signal is a signal containing crosstalk components from adjacent tracks. This luminance signal is then supplied to the comb filter (ie, the comb filter) 26 through the de-emphasis circuit 25. Here, the crosstalk component is removed and supplied to the input of one side of the addition circuit 27.

On the other hand, the converted color signal from the low pass filter 23 passes through the contact b of the switch 5 after the level is constant in the ACC circuit 28, and then in the A / D conversion circuit 6. A / D is converted. At this time, as the sampling clock of the A / D conversion circuit 6, the clock signal supplied from the voltage controlled oscillator 29 is used because the switch 7 is connected to the contact point b. This clock signal is, for example, a signal of 4fsc locked to the reproduction subcarrier frequency fsc. Therefore, in this case, decoded R-Y signals, B-Y signals, that is, baseband signals can be obtained alternately on the output side of the A / D conversion circuit 6. These baseband signals are supplied to a comb filter composed of the line memory 9 and the addition circuit 30, and crosstalk components are removed.

The output signal from which this crosstalk component has been removed is subjected to D / A conversion in the D / A conversion circuit 31, gated in the burst gate circuit 32, and obtained from the gate circuit 32 as a phase error component of the burst signal. The RY signal is supplied as the control signal of the voltage controlled oscillator 29 through the low pass filter 33, and thus the clock signal supplied to the A / D conversion circuit 31 is modulated. This constitutes a so-called APC (automatic phase control) loop. In addition, the burst signal from the burst gate circuit is detected as amplitude information by the APC detection circuit 34, and the burst is supplied to the ACC circuit 28 through the low pass filter 35 to achieve a constant level.

In addition, the output signal of the adder circuit 30 of the comb filter is supplied to the encoder 15 through the contact b of the switch 14, where the preceding subcarrier frequency (3.5 or 4.43) is modulated by modulating the subcarrier. Is restored, and the encoded signal from the encoder 15 is D / A converted by the D / A conversion circuit 16 and supplied to the other input side of the addition circuit 27.

Then, the carrier color signal is added to the luminance signal by the addition circuit 27, and as a result, a desired color video signal is obtained at the output terminal 36. In this way, in this embodiment, since the line memory 9 of the camera signal processing system 1 can be shared as the comb filter of the reproduction signal processing system 2, the configuration is simplified, and the cost is reduced. Lower power consumption. In addition, since the encoder 15 of the camera signal processing system 1 is substantially used as the frequency conversion circuit of the carrier color signal in the reproduction signal processing system 2, the configuration can be simplified, miniaturized, and cost reduced. In addition, the reproduction carrier color signal is decoded and A / D converted to pass through a comb filter composed of line memories, so that the sampling frequency can be reduced, thereby reducing the memory capacity of the line memory. It can be reduced to about 1/4 of the memory capacity as it is. In addition, when A / D conversion and digital processing are performed, there is no imbalance such as phase and amplitude, so that no adjustment is possible.

FIG. 2 shows a second embodiment of the present invention. In this figure, parts corresponding to those of FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted.

In this embodiment, the subcarriers supplied to the encoder 15 are switched during recording and playback. That is, the switch 37 is provided in the encoder 15, and at the time of recording, the switch 37 is connected to the contact point a so that the encoder 15 receives a low-frequency conversion carrier signal of 734 KHz, for example, in the case of 8 millimeter VTR. At the time of regeneration, the switch 37 is connected to the contact point b to supply the encoder 15 with the subcarrier signal as in the case of FIG.

This eliminates the need for a frequency conversion circuit for low frequency conversion of the carrier signal, since the direct low frequency conversion carrier signal is modulated into a carrier color signal during recording. As shown in FIG. 2, the output side of the D / A conversion circuit 16 It is directly connected to the other input side of the adding circuit.

In this manner, the present embodiment also has the same effect as that of the above embodiment, and in this embodiment, the frequency conversion circuit for low frequency conversion of the carrier color signal is unnecessary.

In the above embodiment, only the reproduction carrier color signal is decoded and supplied to the line memory 9 during reproduction, but the reproduction luminance signal may be demodulated and supplied to the line memory 9, or two signals may be supplied to the line memory 9; It may be supplied to.

In the present embodiment, the 1H delayed signal of the line memory 9 is supplied to the adder 30 during reproduction, but the 2H delayed signal may be supplied.

As described above, according to the present invention, since a line memory, an encoder, and the like used in the camera signal processing system are shared by the reproduction signal processing system, the circuit configuration can be simplified, miniaturized, reduced in cost, and reduced in power consumption. In addition, since the reproduction carrier color signal is decoded and supplied to the line memory in the state of the baseband signal, the memory capacity can be reduced and the characteristics such as shift reproduction are easily coped with.

Further, by supplying the low-conversion carrier signal directly to the encoder of the camera signal processing system at the time of recording, the frequency conversion circuit for low-conversion carrier color signal can be deleted.

Claims (2)

An apparatus for processing color image signals, comprising imager means for providing an imager signal corresponding to a subject in a field of view of a video camera, a magnetic recording and reproducing apparatus integrated with the video camera, and a device for processing a video signal. Analog / digital conversion means for converting the imager signal into a digital form; Means for supplying a sampling clock having a frequency four times the color subcarrier frequency to the analog / digital conversion means; Means for processing said digital image signal, said line delay means for delaying said digital image signal, means for generating a luminance signal from said digital image signal and a delayed signal from said line delay means, Image signal processing means including means for generating a color signal from said digital image signal and said delayed signal from said line delay means, and an encoder for encoding said color signal with a carrier color signal; Digital / analog conversion means for converting the luminance signal and the carrier color signal from a digital form into an analog form; Means for recording said luminance signal and color signal in analog form on a magnetic medium, operating in a recording mode, said FM frequency modulation means for frequency modulating a carrier with said luminance signal, and the resulting FM luminance signal and this FM luminance signal Means for recording comprising means for combining said carrier color signal at a low frequency below the band of; Means for operating in a reproduction mode to reproduce the luminance signal and the color signal in analog form from the magnetic medium; Means for applying at least one of the reproduced luminance signal and color signal to said line delay means via said analog / digital conversion means; And means for obtaining a composite video signal from an output of said line delay means and from one of said reproduced luminance signal and color signal applied to said line delay means; The apparatus of claim 1, wherein a subcarrier or a low frequency conversion carrier signal is supplied to the encoder.

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