JP2884648B2 - Video signal conversion method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention converts an EDTV (clear vision) video signal into an HDTV
The present invention relates to a method of converting a video signal for converting the video signal into a (high-vision) video signal.

[Prior Art] In general, in EDTV, the scanning frequency is doubled and non-interlace is performed to improve the image quality of the NTSC system. Specifically, the EDTV video signal has 525 scanning lines, non-interlace scanning, a frame frequency of 59.94 [Hz], and an aspect ratio of 4: 3. In contrast, HDTV video signals consist of 1125 scanning lines, interlaced scanning, and a field frequency of 6
0.00 [Hz], aspect ratio 16: 9.

[Problem to be Solved by the Invention] It is desired that an EDTV video signal can be received by an HDTV video device.

However, as described above, EDTV and HDTV have differences in the number of scanning lines, differences between non-interlace and interlace, differences in field frequency, differences in aspect ratio, etc. Could not be used.

SUMMARY OF THE INVENTION It is an object of the present invention to convert an EDTV video signal into an HDTV video signal by a simple method and obtain a video signal that can be displayed on the screen of an EDTV video device.

[Means for Solving the Problems] The present invention uses an EDTV video signal of 525 scanning lines, non-interlaced scanning, and a frame frequency of 59.94 Hz.
Book, interless scanning, HDT with field frequency of 60.00Hz
In the method of converting the EDTV video signal into a V signal, the EDTV video signal is alternately written into the first and second field memories one frame at a time for each frame, and the EDTV video signal read alternately from the first and second field memories is written. 525 out of 562.5 scanning lines of the odd and even fields of the HDTV video signal are written into and read from the first and second field memories by 999 of the EDTV video signal.
Each time the video signal for the frame is converted into the video signal for the 999 fields of the HDTV video signal, the video signal of the 999th frame of the EDTV video signal is replaced with the video signals of the 999th field and 100th of the HDTV video signal.
By reading twice from the first and second field memories as the video signal of the 0th field and changing the frequency of the write clock and read clock of the first and second field memories and performing horizontal time compression processing of the EDTV video signal, The present invention is characterized in that the total number M of samples of one horizontal line of the EDTV video signal is set within the number N (N> M) of samples of one horizontal line of the HDTV video signal, and the rest is used as a blanking period.

[Operation] One frame (525 scanning lines) of the EDTV video signal is alternately written to the first and second field memories for each frame, and is alternately read from the first and second field memories. The EDTV video signal becomes 525 video signals out of 562.5 scanning lines of odd and even fields of the EDTV video signal,
Each time the TV video signal becomes an HDTV video signal for 999 fields, the video signal of the 999th frame of the EDTV video signal becomes the video signal of the 999th field and the 1000th field of the HDTV video signal.

Further, by changing the write clock frequency (for example, 28.6 MHz) and the read clock frequency (for example, 44.55 MHz) of the first and second field memories and performing horizontal time compression processing of the EDTV video signal, one horizontal line of the EDTV video signal is obtained. Is set within the sample number N (eg, 1320) of one horizontal line of the HDTV video signal, and the rest is set as a blanking period.

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

In FIG. 1, an EDTV video signal (Y) (RY)
(BY) is converted into R, G, B signals by an inverse matrix circuit (1), and then converted into first and second field memories (2a) (2
b) is stored in each RGB memory. And the first and second
The outputs of the field memories (2a) and (2b) are converted to analog circuits by a D / A conversion circuit (3) and sent to a CRT (4) of an EDTV. (5) is a deflection circuit.

Next, a pulse having an EDTV frame frequency of 59.94 Hz as shown in FIG. 4 (a) input to the input terminal (6) is input to the inverting circuit (7) and is output for each pulse as shown in (b). An alternately inverted pulse is obtained, which is the first D-FF (D
Type flip-flop) circuit (8a). An HDTV vertical synchronizing signal (V) and a horizontal synchronizing signal (H) are input to the second D-FF circuit (8b), and a pulse having an HDTV field frequency of 60.00 Hz is obtained on the output side. The clock is input to the first D-FF circuit (8a). Then
As shown in (d), the Q output of the first D-FF circuit (8a) is alternately inverted up to 999 times at 60 Hz, only the 1000th time is not inverted and becomes the same as the 999th time. Gives a pulse inverted from the previous one. Further, an output which is completely inverted from the Q output is obtained.

From the above, the video signal of the EDTV is read when the data of the first field memory (2a) is read out in each of the fields 1, 3, 5... 999, and the data of the second field memory (2b) is Read out at the time of the field of 4, 6,... 998 and become an HDTV image by interlaced scanning.

Here, the frame frequency 59.94 Hz and the field frequency 6
Since the frequency of 0.00 Hz is different, at the time of 1000 fields of HDTV, as shown in FIG. 5, data of 999 fields of EDTV are read again to form an image. When 1000 fields are displayed, the second field memory (2b) stores 1, 3, 5,... 999 as shown in the second half of FIG.
, And 1000 fields, and the first field memory (2a) is read when 2, 4, 6,... 998 even fields. Similarly, odd and even fields are read alternately in the same manner, and 999 and 1000 fields are read twice only in the odd field.

Next, when the clock of the EDTV is 28.6 MHz, the number of samples in one horizontal line is 910, whereas in the HDTV, it is 4
This is 1320 samples at 4.55 MHz. Therefore, EDT
By converting the frequency of the V clock 28.6 MHz to 44.55 MHz of HDTV, 910 samples for one horizontal line of EDTV are used as effective pixels, and the remaining 410 samples are used as a blanking period. For this purpose, as shown in FIG. 6, the clock (44.55 MHz) of the HDTV is started by the vertical synchronizing signal (V), counted by the counter (9), and 1 to 910 are output. Then, with the next V signal, the counter (9) is started again, and 1 to 910 are output. In order to distribute the blanking area (B) shown in FIG. 3 to the left and right, a shift register (10) for delaying the start signal of the counter (9) by, for example, 205 samples as shown in FIG. insert. Then, as shown in FIG. 8, blanking areas (B ₁ ) and (B ₂ ) are distributed to the left and right.

When the blanking areas (B), (B ₁ ), and (B ₂ ) are displayed in a specific color, for example, blue, the counter (9)
If an inverter (11) and a color generation circuit (12) such as blue are interposed between the first and second field memories (2a) and (2b) between the first and second field memories (2a) and (2b), ) (B ₁₎
(B ₂₎ may be appropriately color the background. Note that the inverter (11) can be omitted.

[Effects of the Invention] Since the present invention adopts the above-described conversion method, it is possible to convert a non-interlaced scanning EDTV video signal into an interlaced scanning HDTV video signal by a simple method and receive the image on an HDTV video device. In addition, the total number of samples of the video signal of the non-interlaced scanning of the EDTV can be displayed on the CRT as the video signal of the interlaced scanning of the HDTV. In addition, the extra blanking portion of the CRT is colored blue or the like, so that discomfort due to differences in the size and aspect ratio of the CRT can be reduced.

[Brief description of the drawings]

FIG. 1 is a circuit block diagram for realizing a video signal conversion method according to the present invention, FIG. 2 is an explanatory diagram of non-interlaced scanning of EDTV, FIG. 3 is an explanatory diagram of interlaced scanning of HDTV, FIG. FIG. 5 is a waveform diagram, FIG. 5 is an explanatory diagram showing the correspondence between field numbers of HDTV video signals and frame numbers of EDTV video signals at the time of conversion, FIG. 6 is a circuit block diagram for moving an image, and FIG. FIG. 8 is an explanatory diagram of an image on a CRT. (1) ... inverse matrix circuit, (2a) (2b) ... first,
Second field memory, (3) D / A conversion circuit,
(4) CRT, (5) deflection circuit, (6) input terminal, (7) inversion circuit, (8a) first D-FF
(D-type flip-flop) circuit, (8b) ... second D-
FF circuit, (9) counter, (10) shift register, (11) inverter, (12) color generation circuit.

Claims (1)

(57) [Claims] 1. An EDTV video signal having 525 scanning lines, non-interlace scanning, and a frame frequency of 59.94 Hz,
Book, interless scanning, HDT with field frequency of 60.00Hz
In the method of converting the EDTV video signal into a V signal,
The EDTV video signal alternately written into the first and second field memories by one frame at a time for each frame is read out from the first and second field memories, and the odd-numbered field and the even-numbered field of the HDTV video signal are scanned. 562.5
The first and second video signals are 525 video signals of the
Each time the video signal for 999 frames of the EDTV video signal is converted into a video signal for 999 fields of the HDTV video signal by writing and reading to and from the field memory, the video signal of the 999th frame of the EDTV video signal is converted to the HDTV video signal. The EDTV video signal is read twice from the first and second field memories as video signals of the 999th field and the 1000th field of the video signal, and the write clock and the read clock of the first and second field memories are changed in frequency. By performing the horizontal time compression processing of the EDTV video signal.
A method of converting a video signal, wherein the total number M of horizontal line samples is within the number N (N> M) of samples of one horizontal line of the HDTV video signal, and the remainder is a blanking period.