JP3509204B2 - Color video signal processing device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to time-division multiplexing of two color difference signals so that one circuit can convert two color difference signals.
The present invention relates to a color video signal processing device which can be shared by the same and can further reduce power consumption. 2. Description of the Related Art Conventionally, when a color difference signal is thinned out and time division multiplexing is performed at a data rate equal to or lower than a clock rate, for example, the clock rate of the color difference signal is thinned out to 1/4, as shown in FIG. The two color difference signals thinned out in this way are time-division multiplexed. Generally, the RY signal and the BY signal are
Since there is no correlation, there is a problem that at these data change points, the data is inverted with a considerable probability for each bit, and a current flows through the gate each time the data is inverted, resulting in an increase in power consumption. [0003] Accordingly, the present invention provides
An object of the present invention is to provide a color video signal processing device capable of reducing power consumption by reducing inversion for each bit. According to the present invention, a digital color video signal is inputted, a digital color video signal is separated into a luminance signal and a carrier chrominance signal, and the luminance signal and the carrier chrominance signal are separated into separate digital signals. The digital signal processing circuit for the carrier chrominance signal supplies the carrier chrominance signal to the signal processing circuit. demodulating means for demodulating the chrominance signal, and means for thinning the first and second color difference signals, when time-division multiplexing the first and second color difference signals, a correlation R-Y signals respectively, and correlation multiplexed to continuous B-Y signals respectively with a color video signal processing apparatus characterized by comprising a means for outputting a multiplexed signal. When time-division multiplexing of a plurality of chrominance signals thinned out to reduce the data rate to a clock rate or less, RY signals of a plurality of chrominance signals are made continuous or BY signals are made continuous. By doing so, the probability of inversion for each bit is reduced. That is, the current flowing to the gate each time the bit is inverted can be reduced. An embodiment of a color video signal processing apparatus according to the present invention will be described below with reference to the drawings. FIG. 1 shows a VTR (Video Tape Record) according to the present invention.
er) shows a block diagram of an example. A color video signal is supplied from an input terminal denoted by reference numeral 1, and the supplied color video signal is supplied to the A / D conversion circuit 2. A / D conversion circuit 2
In, the supplied color video signal is digitized,
It is supplied to the Y / C separation circuit 3. The Y / C separation circuit 3 performs Y / C separation of the supplied color video signal.
The luminance signal Y is supplied to a luminance signal recording processing circuit 4, and the color difference signal C is supplied to a demodulator 8. The luminance signal recording processing circuit 4 applies a horizontal / vertical aperture and F to the supplied luminance signal Y.
Recording processing such as M modulation is performed. An output signal of the luminance signal recording processing circuit 4 is supplied to a D / A conversion circuit 5 and converted into an analog signal. The color difference signal C is demodulated to the base band in the demodulator 8 and the demodulated color difference signal C
Is supplied to the thinning circuit 9. The thinning circuit 9 thins out the supplied color difference signal C to １ ／, and the thinned color difference signal C is supplied to the color difference signal recording processing circuit 10.
In the color difference signal recording processing circuit 10, chroma emphasis,
And / or recording processing such as burst emphasis is performed. The color difference signal C is supplied to the color difference signal recording processing circuit 10.
Are supplied to the interpolation circuit 11 from the
An interpolation process is performed. Interpolated color difference signal C
Is supplied from the interpolation circuit 11 to the modulator 12, is returned to the carrier chrominance signal, and is converted to an analog signal in the D / A conversion circuit 13. The adder circuit 6 adds the color difference signal C and the luminance signal Y, each of which has been converted into an analog signal, and adjusts the recording current in the recording amplifier to convert the video signal via a magnetic head (usually a plurality of rotating heads) 14. Recorded on magnetic tape. At the time of reproduction, a video signal recorded on a magnetic tape is reproduced via a magnetic head 14, and the reproduced video signal is supplied to a reproduction amplifier 21. In the reproduction amplifier 21, the supplied video signal is gain-adjusted, the luminance signal Y is supplied to the A / D conversion circuit 22, and the color difference signal C is supplied to the A / D conversion circuit 26. In the A / D conversion circuit 22, the supplied luminance signal Y is converted into a digital signal and supplied to the luminance signal reproduction processing circuit 23. In the luminance signal reproduction processing circuit 23, reproduction processing such as horizontal / vertical aperture and FM demodulation is performed on the supplied luminance signal Y, and supplied to the D / A conversion circuit 24.
It is converted to an analog signal. In the A / D conversion circuit 26, the supplied color difference signal C is converted into a digital signal and supplied to a demodulator 27. In the demodulator 27, the supplied color difference signal C is demodulated to baseband and supplied to the thinning circuit 28. The thinning circuit 28 performs thinning processing on the supplied color difference signal C, and performs the thinning processing on the color difference signal C that has been thinned.
Is supplied to the color difference signal reproduction processing circuit 29. In the color difference signal reproduction processing circuit 29, the supplied color difference signal C is subjected to reproduction processing such as chroma de-emphasis and / or burst de-emphasis, and is supplied to the interpolation circuit 30. The interpolating circuit 30 performs an interpolating process on the color difference signal C subjected to the reproducing process, and supplies the interpolated signal to the modulator 31. In the modulator 31, the supplied color difference signal C is modulated by a color subcarrier and supplied to a D / A conversion circuit 32. The D / A conversion circuit 32 converts the color difference signal C converted into an analog signal into a luminance signal Y by an adder 25.
And a color video signal is output via the output terminal 33. In one embodiment of the present invention, the color difference signals thinned out by the thinning circuits 9 and 28 to a data rate equal to or less than 1/4 of the clock rate are used for the color difference signal recording processing circuit 1.
0 and supplied to the color difference signal reproduction processing circuit 29. In general, in a color signal processing circuit, the frequency band of a color signal is narrow and the clock frequency is often several times higher than required by Nyquist's theorem, and two or more different types are used to reduce the cost and power consumption. The different signals are time-division multiplexed and one circuit block is used in common. An example in which color difference signals are time-division multiplexed to share one circuit block will be described below. FIG. 2 is a block diagram showing an example of the color difference signal processing circuit of the present invention. FIG. 3 is an example of a timing chart corresponding to the block diagram of FIG. A color difference signal a is supplied from an input terminal 41 and supplied to one end of a switch 44. The color difference signal b is supplied from the input terminal 42, and the supplied color difference signal is supplied to the delay circuit 43. These color difference signals a and b represent color difference signals obtained by subjecting the supplied video signal to different processing. For example, the color difference signal a indicates that the supplied video signal has been subjected to chroma emphasis, and the color difference signal b indicates that the supplied video signal has been subjected to burst emphasis. The color difference signal b supplied from the input terminal 42
Is delayed by one sampling period in the delay circuit 43 and supplied to the other end of the switch 44 as a delayed color difference signal db. The switch 44 is controlled by a switching signal tmg1 supplied from an input terminal 45. This switching signal t
When mg1 is at the high level, the switch 44 selects the delayed color difference signal db, and when it is at the low level, the switch 4
In 4, the color difference signal a is selected. That is, the switch 44 outputs a color difference signal a + db. The color difference signal processing circuit 46 performs signal processing on the supplied color difference signals a + db. The color difference signal a '+
b ′ is output. The AND gate 47 extracts the color difference signal a 'through the output terminal 51 by using the color difference signal a' + b 'supplied from the color difference signal processing circuit 46 and the signal tmg2 supplied from the input terminal 48. In the AND gate 49, similarly, the color difference signals a '+ b'
And the signal tmg3 supplied from the input terminal 50, the color difference signal b 'is extracted via the output terminal 52. At this time, signals tmg2 and tmg3 supplied to AND gates 47 and 49 form signals inverted from each other. That is, since there is no correlation between the RY signal and the BY signal, there is a high probability that the data greatly changes at each clock, that is, the data is inverted. However,
The (RY) signal of the color difference signal a and the (RY) of the color difference signal b
Signal, the (BY) signal of the color difference signal a and the color difference signal b
The time-division multiplexed data of the (BY) signal of
Due to the correlation, the probability that the data is inverted is reduced to about half. Here, “X” included in the color difference signals a, b, and db shown in the timing chart of FIG. 3 represents samples that have been thinned out in the previous stage thinning circuits 9 and 28, and the color difference signal a ′ , B ′ is
This indicates that the interpolation circuits 11 and 30 have performed zero interpolation. Here, as another example, FIG. 4 shows an LSI (Large Scale In) capable of time-division multiplexing color difference signals.
2 is a block diagram illustrating an example of an integrated circuit. The color difference signal c is supplied to one end of the switch 64 via the input terminal 61, and the color difference signal d is supplied to the delay circuit 63 via the input terminal 62. The color difference signal d supplied to the delay circuit 63 is supplied to the other end of the switch 64 after a predetermined time delay. The switch 64 is controlled by a signal supplied from the input terminal 65, and one of the color difference signal c and the delayed color difference signal d is selected and output. That is, the color difference signals c + d are time-division multiplexed and output from the switch 64 to the delay circuit 66. In the delay circuit 66, the color difference signal c + d is supplied to the amplifier 67 after a predetermined delay time is given to the color difference signal c + d. In the amplifier 67, signal processing such as waveform shaping is performed on the color difference signal c + d,
A color difference signal obtained by time-division multiplexing the color difference signals of the types is extracted. That is, in the LSI, the color difference signals are time-division multiplexed and output from the output terminal 68. This output terminal 6
Reference numeral 8 denotes an LSI pin. According to the color video signal processing apparatus of the present invention, two color difference signals are time-division multiplexed,
One circuit block can be shared. Further, in the color video signal processing device according to the present invention, power consumption can be reduced with the same gate scale as the conventional one.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an example of signal processing of a VTR according to the present invention. FIG. 2 is a block diagram showing an embodiment of a color video signal processing device according to the present invention. FIG. 3 is a timing chart showing an example of an operation corresponding to the color video signal processing device of the present invention. FIG. 4 is a block diagram showing an example of time division multiplexing using LSI pins according to the present invention. FIG. 5 is a schematic diagram illustrating an example of conventional time-division multiplexing of color difference signals. [Description of Signs] 43 Delay circuit 44 Switch 46 Color difference signal processing circuits 47, 49 AND gate

Claims (1)

(57) [Claim 1] A digital color video signal is inputted, the digital color video signal is separated into a luminance signal and a carrier chrominance signal, and the luminance signal and the carrier chrominance signal are separated. A digital video signal processing circuit for supplying the digital signal processing circuit with the digital signal processing circuit for the carrier chrominance signal for the two color difference signals; demodulating means for demodulating the second chrominance signal, and means for decimating said first and second color difference signals, when time-division multiplexing said first and second color difference signals, a correlation R-Y between signals, and a correlation B-
Means for multiplexing the Y signals so as to be continuous with each other and outputting a multiplexed signal.