JPH01296863A - Television receiver - Google Patents

Abstract

PURPOSE:To evade fluctuation in the perpendicular direction of a picture at the time of a strobe display by fixing the odd and even numbers of a video signal stored in a memory means at one of the odd number or the even number. CONSTITUTION:One field of the input video signal in a jump scanning system is stored into a memory 15. The writing and reading of the memory 15 is controlled by a microcomputer 4 and a controller 16, and one field of the input video signal is written to the memory 15 over a first period equivalent to the one field period at every cycle of 2nV (however, n=1, 2, 3,..., V is a perpendicular cycle), thereafter, the writing is stopped, and the video signal for one field stored into the memory 15 is repeatedly read over the second period longer than the first period.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a television receiver that is capable of strobe display (frame-by-frame display) of video signals.

[Summary of the invention]

The present invention relates to a television receiver, in which one field of an interlaced scanning type human input video signal is converted to 2nV (however,
n=1.2,3. . . . , ■ is a vertical period), the first period equal to one field period is written into the storage means, and then the writing is stopped, and the second period longer than the first period is written. Vertical fluctuations in the image during strobe display are avoided by controlling the storage means such that one field worth of video signal stored in the storage means is repeatedly read out over a period of . It is.

[Conventional technology]

Conventionally, television receivers have been proposed that are capable of strobe display (frame-by-frame display) of video signals. Such conventional television receivers are equipped with a memory (video RAM) that can store field signals (frame signals are also possible) of video signals, and in strobe display mode, one field of the input video signal is stored for one field period. Then, the writing is stopped, and the video signal is read out repeatedly over a predetermined field period, for example, 8 field periods, and the video signal for 1 fields that has been repeatedly integrated is read out by CR''. l' for display, then stop its writing, and write one field of the human-powered video signal into the storage means over one field period in the same way as described above.
By repeating this, a strobe display is performed on the CRT screen in which the image changes every nine field periods of the human video signal.

This strobe display can be performed on the entire screen of the CRT based on the video signal of a certain channel, or when the CR'I" screen is divided into two, and on the - side split screen, the strobe display is performed on the entire screen of the CRT based on the video signal of a certain channel. Based on the above (normal display is performed, the other divided inner surface performs strobe display based on the video signal of the other channel, and the divided screen that displays the normal display and strobe display is alternated at predetermined intervals). be.

[Problem to be solved by the invention]

By the way, in a television receiver capable of such a strobe display, as described above, the storage means stores one field of the input video signal over one field period every 9 (-1+8) fields, that is, every odd field period. At the same time, the writing is stopped and the video signal for one field stored in the storage means is repeatedly read out over a period of 8 fields, which is longer than the writing period, so that the manual video signal is skipped. In the case of a scanning video signal, the odd/even field of the first video signal of the video signal written into the storage means every nine fields, that is, the number of fields, is the number of fields, the number of fields, the number of even numbers,
Since the input video signal changes alternately with odd numbers, etc., if the input video signal is an image signal with little movement, there is a drawback that the image appears to fluctuate in the vertical direction.

In view of this point, the present invention improves the image quality during strobe display. l! The present invention attempts to propose a television receiver in which vertical fluctuations are avoided.

[Means to solve the problem]

The television receiver according to the present invention has a storage means (for storing one field of an interlaced scanning type human input video signal).
15) and 2nV (however, n-1゜2.3...
, ■ is a vertical period), one field of the human video signal is written into the storage means (15) over a first period equal to one field period, and then the writing is stopped and the first the storage means (15) so as to repeatedly read out the video signal for one field stored in the storage means (15) over a second period that is longer than the first period;
and control means (4, 16) for controlling.

[Effect]

According to the present invention, since the odd-even of the field of the video signal stored in the storage means (15) is fixed to either an odd number or an even number, when the input video signal is a video signal of an image with little movement, However, vertical fluctuations in the image during strobe display are avoided.

〔Example〕

FIG. 1 shows an embodiment of a television receiver according to the present invention, which will be described below. In FIG. 1, a received signal from an antenna (1) is supplied to a chainer circuit (2), where a television signal of a desired channel is selected, and at the same time, the frequency conversion circuit converts the selected television signal. is converted into a video intermediate frequency signal.

This television receiver uses a PLL synthesizer type channel selection circuit, and when selecting a channel, AFT
control is in place. This will be explained below.

The PLL circuit (3) shown in FIG. 1 is a prefrequency divider.

The frequency divider 9 is composed of a phase comparator, a reference signal excavator, and a low-pass filter (all of which are not shown), and the local oscillation signal from the local oscillator (not shown) of the tuner circuit (2) is , PLL circuit (31 prescaler and frequency divider are fed to its phase comparator. On the other hand,
The reference signal from the reference signal oscillator of the PLL circuit (3) is
is fed to its phase comparator. In this phase comparator, the output of the frequency divider and the reference signal from the reference signal oscillator are compared in phase, and the comparison output is supplied to the tuner circuit (2) via a low-pass filter. The oscillation frequency of the local oscillator is then controlled based on this comparison.

When tuning for the first time, A F'l'' control is performed. That is, the frequency divider of the PLL circuit (3) is divided so that the local oscillation frequency is close to the frequency corresponding to the regular carrier frequency. This frequency division ratio is determined by the micro combinator (
4) is set. Then, the local oscillation frequency is moved upward and downward in steps, that is, AFT control is performed. When a television signal is pulled in by ATF control, offset channel data based on the frequency division ratio at that time is stored. During the next channel selection, the desired channel is selected using the offset channel data stored during the first channel selection.

By the way, the above-mentioned microcomputer (4) is given various commands such as a channel switching command and a source switching command from the key switch (5) and the remote control transmitter (6). When a channel switching command is given to the micro combinator (4), the frequency division ratio of the frequency divider of the PLL circuit (3) is reset to correspond to the desired channel.

Further, when a source switching command is given to the microcomputer (4), the first switch circuit (7) is switched according to the commanded input source.

The video intermediate frequency signal output from the tuner circuit (2) is supplied to an intermediate frequency signal processing circuit (8). In this intermediate frequency signal processing circuit (8), the video intermediate frequency signal is amplified and video detected, and a composite color video signal is output. This composite color video signal is supplied to the first switch circuit (7).

(9) is the input terminal for external video signals, and this human input terminal (9)
) is supplied with an external composite color video signal from a video device such as a VTR or a video disc playback device. The external composite color video signal from this input terminal (9) is supplied to the first switch circuit (7).

In the first switch circuit (7), the remote control transmitter (6)
Alternatively, the color video signal is switched by a control signal output from the microcomputer (4) based on a source switching command from the key switch (5).

That is, the first switch circuit (7) selects either the composite color video signal from the intermediate frequency signal processing circuit (8) or the external composite color video signal from the input terminal (9). .

The composite color video signal output from the first switch circuit (7) is supplied to a Y/C separation circuit (10).

The Y/C separation circuit (lO) converts the selected composite color video signal into a luminance signal Y and red and blue difference signals RY and B.
-Y, and the bright absorption signal Y and the color difference signal RY,
B-Y is supplied to an A/D conversion circuit (11) and a second switch circuit (12), respectively, and a vertical synchronization signal separated from the luminance signal is supplied to a microcomputer (4).

The Y/C separation circuit (1) is passed through the second switch circuit (12).
0) Luminance signal Y5 Color difference signal R-Y, B-
Y is supplied to the color video signal processing circuit (13),
It is demodulated into three primary color signals R, G, and H, and these three primary color signals R,
G and B are supplied to color CI ('l' (14)) to display a color image.

On the other hand, in the A/L) conversion circuit (11), the luminance signal Y2 and the color difference signal 1 (-Y
, B-Y respectively A/l). One field (or one frame is also possible) of the digital luminance signal and both digital color difference signals from this A/D conversion circuit (11) is stored in a field memory (
Video RAM) (Frame memory is also possible) (15
) are sequentially written to addresses. towards this memory (
15) is a remote control transmitter (6) or a key switch (
It is used when displaying frame images (stroboscopic display) based on instructions from 5).

and a remote control transmitter (6) or key switch (5)
Therefore, when a channel switching command or a source switching command for switching channels of a television signal is input to the microcomputer (4), a control signal from the microcomputer (4) is supplied to the controller (16).

This controller (16) is a micro combinator (
Based on the control signal from 4), writing and continuous output of the digital video signal (digital luminance signal and both digital color difference signals) in the memory (15) and switching of the second switch circuit (12) are controlled.

Then, the controller (16) controls the memo IJ (1) of the digital video signal based on the control signal input thereto.
5) after writing for one field period, it is stopped (frozen). As a result, the last odd or even field is stored in the memory (15).The microcomputer (4) sets the odd or even field to either one. ] One field worth of digital video signals will be stored. The controller (16) reads out this digital video signal, performs D/A conversion using the D/A conversion circuit (17), and converts it into luminance signals Y1, color difference signals R-Y, 13-
Y is obtained and supplied to the second switch circuit (12). The controller (16) also includes a second switch circuit (12).
A switch switching signal is supplied to the D/A conversion circuit (17
), the luminance signal Y1, color difference signals R-Y, B-Y, etc. are supplied to the color video signal processing circuit (13).

The luminance signal Y1 and the color difference signals R-Y and B-Y are returned to the video signal processing circuit (13) as three primary color signals R, G, and B, and are supplied to the color CR'r (14) for strobe display. will be held.

Then, the digital video signal for one odd or even field in the memory (15) is read out and displayed on the color R'r (14) as a strobe display image consisting of, for example, seven still images. For example, the switching operation of the color video signal is performed manually during a seven-field period. For example, in the case of a television signal, this switching operation changes the frequency of the new channel to the PLLu path (3).
This means locking in and pulling in a new television signal.

Furthermore, when changing the input source of the composite color video signal, switching is performed between the television signal and the external composite color video signal from the video equipment.

Therefore, images that are distorted due to the flow of synchronization, or completely dark images that have been blanked, are not displayed.
A comfortable usability can be provided to the user. Further, this operation is performed by software of the microcomputer (4) that controls the memory (15), and can be realized with less burden on the software and no increase in cost.

Then, the digital video signal in the memory (15) is
After the field period has been read out, one field of the digital video signal, odd or even, is written into the memory (15) again within one field period, and then the writing is stopped and the data is read over a seven field period. The digital video signal is read and a strobe display is performed on the color CRT (14).

In the above embodiment, the second switch circuit (12) connects the luminance signal Y1 color difference signal R-Y, B-Y from the Y/C separation circuit (10) and the D/A conversion circuit (17). Luminance signal Y99 color difference signal R-Y.

However, the present invention is not limited to this, and for example, as shown in FIG. 2, the output end of the D/A conversion circuit (17) is directly connected to the video signal processing circuit (13).
In other words, when the control signal from the microcomputer (4) is input to the controller (16), writing of the digital video signal to the memory (15) is stopped and the memo 'J ( 15) is read out and subjected to D/A conversion by a D/A converter (17). Along with this, the controller (16
) supplies a control signal to the color video signal processing circuit (13) to perform blanking. The above-mentioned D/A converter (
17) and superimposes the video signal from the color CRT (1
4) A still image may be displayed.

The operation of this embodiment, particularly the operation during strobe display, will be explained below with reference to the flowchart of FIG.

First, in step ST-1, the vertical synchronizing signal detecting means of the microcomputer (4) determines whether or not the vertical synchronizing signal separated from the luminance signal Y by the Y/C separation circuit (10) is detected. When the synchronization signal is detected, the process moves to step 5T-2, and when it is not detected, the process returns to step S'I'-1.

Step S'! '-2, the count value of the microcomputer (counter means) that counts vertical synchronization signals is incremented by 1 from 0 every time a vertical synchronization signal arrives.In this case, the count of vertical synchronization signals Start,
Decide whether to use the odd or even field vertical synchronization signal.

In step S ′l''-3, the microcomputer (
The count value detecting means for detecting the count value of the counter in 4) determines whether the count value of the counter has reached 8. When the count value of the counter has reached 8, step S
``!''-4, and if not 8, step S'
Moving on to r-6.

In step S'1'-4, the count value of the counter is reset to 0 by the counter control means of the microcomputer (4)), and the process moves to step 5T-5.

In step S 'T'-5, writing of the digital video signal (digital luminance signal and both digital color difference signals) to the memory (15) is started (freeze) (therefore,
After the instruction means of the micro combinator (4) instructs the controller (16) to terminate the readout, the process returns to step 5T-1.

Step S'! ” -6, the count value detection means for detecting the hand value of the counter of the micro combinator (4) determines whether or not the count value of the counter has reached 1, and when the count value of the counter has reached 1, is step S
Move to 'I' -7, and if not ■, step S
Return to T-1.

In step S'r-7, the end (freeze) of the digital video signal to the memory (15) (therefore, the start of reading) is stopped by the microcomputer (15).
After the instruction means of 4) instructs the controller (16),
Return to step 5T-1.

Television reception as mentioned above! According to the machine, storage means (1
5) Since the odd-even field of the video signal stored in 5) is fixed to either the odd or even field,
Vertical fluctuations in the image during strobe display are avoided.

〔Effect of the invention〕

According to the present invention described above, it is possible to obtain a television receiver that avoids fluctuations in the vertical direction of an image during strobe display.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing one embodiment of the present invention, FIG. 2 is a block diagram showing a part of another embodiment of the present invention, and FIG.
The figure is a flowchart for explaining one embodiment. (2) is a tuner circuit, (3) is a PLL circuit, (4) is a microcomputer, (13) is a color video signal processing circuit, (15) is a memory, and (16) is a controller. Timing chart figure 3

Claims (1)

[Claims] A storage means for storing one field of an input video signal of an interlaced scanning method, and a storage means for storing one field of an input video signal of an interlace scanning method, and a storage means for storing one field of an input video signal of an interlaced scanning method, , writing one field of the input video signal into the storage means over a first period equal to the one field period, and then stopping the writing and writing a second period longer than the first period; and control means for controlling the storage means so as to repeatedly read out the video signal for one field stored in the storage means.