JPH0588598B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a video signal receiver suitable for application to, for example, a television receiver in which display is performed at twice the field frequency.

BACKGROUND TECHNOLOGY AND PROBLEMS The current television system uses a scanning method called interlace. That is, 1
A single image (frame) is transmitted by two vertical scans (fields), and the aim is to increase the number of scanning lines as much as possible without causing flicker to the viewer's eyes in a limited frequency band. It was designed to do this.

However, in the CCIR system mainly used in Europe, the field frequency is 50 Hz, and flickering cannot be completely eliminated at this frequency, which causes flickering to be noticed, especially on screens with high brightness.

Therefore, conventionally, a television receiver has been proposed in which the field frequency is doubled.

That is, the video signal Sv is supplied to a conversion circuit consisting of a field memory, written in it, and read out at twice the writing speed to obtain a video signal Sv' whose field frequency is doubled. This is what is supplied to the picture tube.

In this case, if writing to and reading from the field memory is simply performed in units of one field period (1V), there is a problem in that horizontal synchronization is periodically disrupted, causing distortion at the top of the screen.

For example, the video signal Sv is 625 lines/frame, 50
Assuming a PAL video signal of fields/second,
The state of writing to memory is represented as shown in FIG. 1A. F ₁ , F ₂ , . . . indicate fields. At this time, the video signal Sv' from the conversion circuit is expressed as shown in FIG. As is clear from this figure, the video signal Sv' is
In other words, the horizontal synchronization phase shifts by 180 degrees every 1/50 second, which disturbs the synchronization at the top of the screen and causes image distortion.

Therefore, in order to prevent image distortion caused by such disturbances in horizontal synchronization, writing to the field memory that constitutes the conversion circuit and continuing reading are performed in integer multiples of the horizontal period (1H), and the A system in which the horizontal synchronization of the video signal Sv' is continuous has been considered.

For example, when the video signal Sv is written to and read from the field memory alternately in units of 313H and 212H, the state of writing to the memory is expressed as shown in FIG. 2A. The video signal Sv' from the conversion circuit is expressed as shown in FIG. As is clear from this figure, the video signal
The horizontal synchronization of Sv' is continuous. Therefore, there is no synchronization disturbance due to discontinuity of horizontal synchronization, and no image distortion occurs due to this.

By the way, when converting a color video signal as a composite signal, if the continuity of the color subcarrier of the converted video signal is maintained, the reference subcarrier for color demodulation can be easily obtained. , color demodulation processing becomes easier.

However, in the case where writing to and reading from the field memory is performed in integer multiples of the horizontal period, the continuity of horizontal synchronization is maintained, but the continuity of the color subcarrier in the converted video signal Sv' is Not guaranteed at all. Therefore, it is not easy to obtain a reference subcarrier for color demodulation, and it is difficult to perform sufficient color demodulation.

OBJECTS OF THE INVENTION The present invention has been made in view of the above problems, and is intended to facilitate color demodulation.

Summary of the Invention The present invention, for example, as shown in FIGS. 3 to 6, receives an interlaced video signal Sv,
In a video signal receiver in which the field frequency of the video signal Sv is converted to an integer multiple using the field memory 6 and then supplied to the picture tube 16, a memory control circuit 7 for controlling writing to and reading from the field memory 6 is provided. The memory control circuit 7 writes to and reads from the field memory 6 during one field period + 0.5 x horizontal period (for example, 313H) and one field period - 0.5 x horizontal period (therefore,
312H), and a predetermined number (for example, 8 pieces)
(see FIGS. 4A and 4C), and the first field F ₁ of the predetermined fields (see FIGS. 4A, 4C) is The phase of the color subtransport at the beginning of the leftmost field in B is the first field F ₁ of the following predetermined fields.
The color carrier in the video signal after conversion is made so that it is in phase with the subcarrier at the beginning of the field (in the rightmost field in Figures 4A and B) (in Figures 4 to 6, both are zero degrees). In addition to maintaining continuity, horizontal deflection scanning is performed based on the horizontal synchronizing signal P _H2 separated from the video signal after conversion.

With the present invention configured as described above, the continuity of color subcarriers in the converted video signal is maintained, so color demodulation can be easily performed. In addition, since horizontal deflection scanning is performed based on the horizontal synchronization signal separated from the converted video signal, image distortion due to disturbance of horizontal synchronization caused by processing to maintain continuity of color subcarriers is easily avoided. can be avoided.

Embodiment Hereinafter, an embodiment of the present invention will be described with reference to FIG.

In the figure, 1 is an antenna, 2 is a tuner,
3 is an intermediate frequency amplifier, and 4 is a video detection circuit. From the video detection circuit 4, for example, 625 lines/
A PAL color video signal Sv of frames and 50 fields/second can be obtained.

This video signal Sv is converted into a digital signal. The video signal Sv converted to a digital signal is
The signal is supplied to the field double speed conversion circuit 6. This conversion circuit 6 is configured with a field memory (not shown). The read clock pulse supplied to this field memory has a frequency twice that of the write clock pulse, and the conversion circuit 6 outputs a video signal whose field frequency is doubled.
Sv ^* is obtained.

Writing to the field memory of the conversion circuit 6,
Reading is controlled by the memory control circuit 7, and writing to this field memory,
Reading is performed alternately in units of approximately 313H and 312H, and each approximately 313H and 312H.
312H is made to contain an integer number of cycles of the color subcarrier.

This memory control circuit 7 is supplied with continuous wave signals CW ₁ and CW ₄ (master clock) which are locked to the color burst signal and have frequencies one and four times that of the color burst signal, as well as a horizontal and vertical synchronizing signal P. _H and Pv are supplied.

That is, the video signal obtained from the video detection circuit 4
Sv is supplied to the PLL circuit 8. This PLL circuit 8
, a color burst signal is extracted from the video signal Sv and locked to it to obtain continuous wave signals CW ₁ and CW ₄ with frequencies one and four times that of the color burst signal. These signals CW ₁ and CW ₄ are then supplied to the memory control circuit 7. Also,
The video signal Sv obtained from the video detection circuit 4 is supplied to the synchronization separation circuit 9. Horizontal and vertical synchronizing signals P _H and Pv are obtained from this separation circuit 9,
These are supplied to the memory control circuit 7.

Writing to and reading from the field memory that constitutes the conversion circuit 6 is performed by the memory control circuit 7.
The control is performed as follows.

Writing video signal Sv to field memory,
Reading is basically as shown in Figure 4A.
This is done alternately in units of 313H and 312H.

Here, in the PAL video signal Sv,
The relationship between the color subcarrier frequency ∫sc and the field frequency ∫v is ∫sc=88672.375fv (1). This is 1 field period (1V=312.5H)
This means that there are 88672.375 cycles of color subcarrier. This means that 313H has 88814.25 cycles (not an integer cycle) and 312H has 88530.5 cycles (not an integer cycle).

Therefore, if the video signal Sv is simply written into and read out from the field memory alternately in units of 313H and 312H, the converted video signal
The continuity of the color subcarriers of Sv ^* will not be maintained.

Therefore, in this example, writing and reading of the video signal Sv to and from the field memory are performed alternately in approximately 313H and 312H units, and each approximately 313H and 312H includes an integer number of cycles of the color subcarrier. It will be done like this.

Here, in the video signal Sv of the PAL system, the relationship between the color subcarrier frequency ∫sc, the horizontal frequency _∫H , and the field frequency ∫v is 1/4 line offset and 1/4 line offset.
It has a 2 field offset. Therefore, in this example, the video signal Sv is written in the field memory so that the following number of cycles of color subcarriers are included in the following eight fields (F ₁ to _{F 8} ): 313H, 312H, 313H, ... (Figure 4B).

F ₁ →88814 cycles F ₂ →88531 cycles F ₃ →88814 cycles F ₄ →88530 cycles F ₅ →88815 cycles F ₆ →88530 cycles F ₇ →88814 cycles F ₈ →88531 cycles In this Figure 4 A and B, The part indicated by "△" indicates the horizontal synchronization position. Figure 4B
If we look at the writing state shown in FIG. 5 in terms of the color subcarrier of the video signal Sv, it will become as shown in FIG. In the figure, the portion marked with "△" indicates the horizontal synchronization position. Furthermore, the portions marked with "O" indicate the first data and the last data to be written into the field memory.

This writing is performed in synchronization with the phase of the signal CW ₁ supplied to the memory control circuit 7. As is clear from FIG. 5, the color subcarriers of the first data and the last data written into the field memory always have a constant phase, for example, 0°.

The video signal written in the field memory as shown in FIG. 4B or FIG. 5 is sequentially read out for each of the fields F ₁ to _{F 8} at twice the writing speed. Therefore, from the conversion circuit 6, a video signal Sv ^* whose field frequency is doubled as shown in FIG. 4C is obtained.

As mentioned above, the first data and the last data of each field written to the field memory have a constant phase of the color subcarrier of the video signal Sv, for example, 0 degrees, so the color subcarrier of the video signal SV ^* will maintain continuity. The color subcarriers in this video signal Sv ^* are as shown in FIG. In the figure, the portions marked with "O" indicate the first data and the last data to be successively output. It can also be seen from FIG. 6 that the continuity of color subtransport in the video signal Sv ^* is maintained.

In this way, the continuity of the color subcarriers in the video signal Sv ^* is maintained, but the horizontal synchronization, for example, "F ₁ ,
F ₁ '', which results in disturbances between consecutive fields. That is, in FIG. 4D, the "●" mark and the "x" mark indicate the start and end sides of each field F ₁ , F ₁ , F ₂ , F _{2 .} . . of the converted video signal Sv ^* , respectively. This indicates the horizontal synchronization position of the field, but the position is shifted between successive identical fields. In FIG. 6, the "△" mark indicates the horizontal synchronization position, which is also clear from this figure.

Incidentally, as is clear from FIG. 4D, this disturbance in the horizontal synchronization position is less than one cycle of the color subcarrier in the video signal Sv ^* , and is relatively small.

Further, in FIG. 3, the video signal Sv ^* obtained from the conversion circuit 6 is converted into an analog signal by a D/A converter 10, and then supplied to a luminance/color separation circuit 11. The luminance signal Y obtained from this separation circuit 11 is supplied to a matrix circuit 13 via a signal processing circuit 12 including a picture circuit and a sharpness circuit. Further, the color signal C obtained from the separation circuit 11 is supplied to a color demodulation circuit 14, and from this color demodulation circuit 14, for example, a red difference signal R-
A blue color difference signal B-Y is obtained and supplied to the matrix circuit 13. And matrix circuit 13
As a result, red, edge and blue primary color signals R, G and B are obtained and supplied to the picture tube 16 via amplifiers 15R, 15G and 15B, respectively.

In addition, a video signal obtained from the D/A converter 10
Sv ^* is supplied to the horizontal synchronization separation circuit 17. A horizontal synchronizing signal obtained from this separation circuit 17
P _H2 (having twice the normal frequency) is supplied to the horizontal deflection circuit 19 through the AFC circuit 18. A horizontal deflection signal is supplied from the deflection circuit 19 to the deflection coil 20. In addition, the horizontal synchronization signal P _H2
The separation may be performed from the luminance signal Y.

Further, a vertical synchronization signal P _V2 (having twice the normal frequency) digitally formed by the memory control circuit 7 is supplied to the vertical deflection circuit 21.
A vertical deflection signal is supplied to the deflection coil 20 from this. Here, the vertical synchronization signal P _V2 is, for example, F ₁
Scanning lines are formed at the same position between fields, between F ₂ fields, and between F ₁ fields and F ₂ fields.
fields, F ₂ field and F ₃ field,...
The scanning lines formed in ... are shifted by 1/2 scanning line interval, and are formed at a timing that maintains the interlaced relationship of the video signal Sv.

This example is constructed as described above, and the picture tube 16 receives primary color signals R and G whose field frequencies are doubled.
and B are supplied, and horizontal and vertical deflection scanning is performed at twice the speed, so that a color image with twice the field frequency is displayed on the picture tube 16.

According to this example, the continuity of the color subcarrier in the video signal Sv ^* after conversion is maintained, so it is easy to obtain the reference subcarrier for color subtone, and color demodulation can be easily performed. can be done.

Also, from the converted video signal Sv ^* , the horizontal synchronization signal
Since P _H2 is separated and horizontal deflection scanning is performed based on this, the converted video signal Sv ^* has a horizontal synchronization position shift of 4 between consecutive fields, such as "F ₁ , F ₁ ". There is a section (see Figure D),
This deviation is relatively small and absorbed by the AFC circuit 18, and no image distortion occurs on the screen due to disturbance in horizontal synchronization.

On the other hand, if, for example, a horizontal synchronization signal is digitally formed and horizontal deflection scanning is performed based on it, image distortion due to disturbance in the horizontal synchronization position in the video signal Sv ^* cannot be avoided. When forming the horizontal synchronization signal digitally in this way, the 16 fields of the converted video signal Sv ^* are distinguished,
It is possible to prevent image distortion by shifting the signal for each field and aligning the horizontal synchronization position.
It's complicated.

In the above-mentioned embodiment, processing is performed by repeating 8 fields _F1 to _F8 , but the process is not limited to this, and may be performed by repeating 16 fields, for example. Furthermore, in the above embodiment, the video signal is
I explained the case of a PAL video signal, but
The present invention can be similarly applied to color video signals of other systems, such as the NTSC system.
Further, in the above embodiment, the field frequency is doubled, but the field frequency is not limited to this, and may be tripled, quadrupled, or
The present invention can be similarly applied to a device that converts a field frequency into...

Effects of the Invention As described above, according to the present invention, the continuity of color subcarriers in a converted video signal is maintained, so color demodulation can be easily performed. Also,
Since horizontal deflection scanning is performed based on the horizontal synchronization signal separated from the converted video signal, image distortion due to disturbance in horizontal synchronization caused by processing to maintain continuity of color subcarriers can be easily avoided. can do.

[Brief explanation of the drawing]

1 and 2 are diagrams for explaining a conventional television receiver, respectively, FIG. 3 is a configuration diagram showing an embodiment of the present invention, and FIGS. FIG. 3 is a diagram for explaining an example. 6 is a field double speed conversion circuit, 7 is a memory control circuit, 17 is a horizontal synchronization separation circuit, 18
is the AFC circuit.

Claims (1)

[Scope of Claims] 1. A video signal receiver configured to receive an interlaced video signal, convert the field frequency of the video signal to an integer multiple using a field memory, and then supply it to a picture tube, wherein the field memory A memory control circuit is provided to control writing to and reading from the field memory, and the memory control circuit writes to and reads from the field memory in 1 field period + 0.5 x horizontal period and 1 field period - 0.5 x horizontal period. , so that each field of a predetermined number of fields obtained by the reciprocal of the product of line offset and field offset for the color subcarrier frequency or an integer multiple of this reciprocal contains an integer number of cycles of the color carrier, and the predetermined number of fields. The color in the converted video signal is adjusted so that the phase of the color subcarrier at the beginning of the first field of the fields is in phase with the phase of the subcarrier at the beginning of the first field of the next predetermined number of fields. While maintaining carrier wave continuity,
A video signal receiver characterized in that horizontal deflection scanning is performed based on a horizontal synchronization signal separated from the converted video signal.