JPH04192778A - Television signal converting method - Google Patents

Abstract

PURPOSE:To prevent the bending and doming of a deflecting system in a video image adjacent to a blanking area by detecting the luminance level of the video image and adjusting the luminance level of the blanking area corresponding to its luminance level. CONSTITUTION:When a large difference is present on a luminance level between a blanking area (b) and the video image adjacent to the blanking area, high voltage is greatly changed, thereby generating the bending or doming of the deflecting system in the cathode ray tube of a television receiver. A leakage integration circuit 19 detects an average luminance level by performing integration smoothening of an input MUSE signal. The circuit then outputs a background level signal having the level corresponding to the luminance That is, the luminance of the blanking area (b) s adjusted to a value corresponding to the luminance of a video image part aN. Thus, the generation of the large difference in luminance level between the blanking area (b) and the image video part aN can be prevented an the irregularity of the image can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to a television signal conversion method for converting a television signal into a second television signal with seven different aspects. In particular, MUS with an aspect ratio of 16:9
The present invention relates to a television conversion method in a MUSE/NTSC converter that converts an E signal to an NTSC signal with an aspect ratio of 4:3.

(b) Hi-Vision, which is the next generation of high-definition television, is being broadcast on conventional satellite broadcasting. This high-definition signal is band-compressed by a band-compression technique called the MUSE, Ji method. This band-compressed signal (MUSE signal) is then broadcast. The aspect ratio of this high vision is 16:9.

In order to view this MUSE signal on a normal NTSC television receiver, use the MUSE/NT as shown in Figure 6.
SC converter (), (10) is not sold (
For example, Mitsubishi Electric UC-5000). This λ1USE/
The NTSC converter (1,00) converts the λ4USE signal into an NTSC signal. Furthermore, this MUSE/'NTS
The operation of the C converter is explained, for example, in pages 31 to 45 of the magazine "Television Technology October 1989 Issue" published by Denshi Gijutsu Publishing Co., Ltd.

By the way, the aspect ratio of high-definition is as shown in Figure 7(a).
As shown, the ratio is 6:9. The aspect ratio of NTSC television is I:3. For this reason, when displaying original high-definition images on an NTSC television, a mote is used to cut off the sides of the high-definition screen as shown in Figure 7(b), and a mote as shown in Figure 7(c).
There is a blanking area (1) below the video part (a, 1).
+) ) (b) There is a mode (wide mode) in which a (visible blanking area) is provided.

In this latter wide mode, the blanking area (b) in FIG. 7(C) can be colored in a desired color by the user's operation.

By the way, the operation of this MUSE/NTSC converter will be briefly explained with reference to FIG.

This converter mainly consists of the following circuits.

-3 - In other words, an analog/digital converter (12) that converts the analog MUSE video signal to be converted into a digital signal. A vertical low-pass filter (13) for thinning out or creating new scan lines (interpolation) in order to convert between different numbers of scan lines.

A time axis conversion circuit (14) for converting the time axis and aspect ratio between the two systems. A signal switching circuit (15) for setting the vertical and horizontal flyback periods after NTSC conversion to a pedicle level and setting the blanking area (b) to an arbitrary background level. A digital/'analog converter (16) converts the digital signal converted into an NTSC signal into an analog video signal.

In the above circuit, the analog NIUSE signal is input to the input terminal (11), and then the analog NIUSE signal is input to the input terminal (11).
A, "I)) is converted into digital data with a sampling frequency of 16.2\It(z, quantization focus number of 8) by the converter (2). In the wide mode conversion method, the high-definition scanning line NTS per 3 pieces
Since we only need to create one scanning line of C, vertical row, 1
- In the pass r filter (13), the vertical frequency band is limited to one-third.

In the time axis conversion circuit (]4), the vertical low-pass filter (
13) For every three high-definition scanning lines that pass through
Only one SC scanning line is extracted and converted to the NTSC time axis. This time axis conversion circuit 04) is composed of a memory. Since the sample phase of the MUSE signal is offset between lines, when signals are added between lines, data is created by interpolation and the sampling frequency is set to 324\111z. In other words, the memory constituting the time axis conversion circuit (14) has only one out of every three high-definition scanning lines, and the data rate is 32,4M.
Write in l-Lz, Figure 7 (video part of cl (a3)
Data rate of 15.12 kl only in
Read out in Hz.

Next, the signal switching circuit (5) selects the output of the time axis conversion circuit (14) in the video portion (aN, ), and selects the output of the time axis conversion circuit (14) in the horizontal and vertical retrace periods, and selects the output of the pedicle switch set by the terminal (18a) in the horizontal and vertical retrace periods. A level is selected, and the background level set by the terminal (18b) is set in the blanking area (b).

Finally, the digital 'analog CD/'A) converter (1
G) is converted into an analog video signal and displayed on an NTSC television monitor.

Assuming that the background level or the black level is the above-mentioned background level or black level, the level of each horizontal scanning line in the vertical direction of the video signal converted from the high-definition MUSE system to the NTSC system is checked as described in 1-. The result will be as shown in Figure 5(a). Here, the black circles indicate the light number field, and the white circles indicate the video signals of the even field. By the way, as shown in FIG. 5(a), there is a large difference in brightness level at the boundary between the blanking area (b) and the video portion (aN,).

(c) Problems to be Solved by the Invention If there is a large brightness level difference between this blanking area (1)) and the video adjacent to this blanking area, the cathode ray tube of the television receiver will , height 1 may change significantly, causing bending or doming of the deflection system.

Also, due to the increment scanning sound, if the scanning line position between the odd and even fields is one line apart and there is a large difference in brightness level at the boundary, a blanking area may occur.
) and the video portion (a, 1) flickers, creating a visual disturbance.

(d) Means for solving the problem The present invention detects the brightness level of the image and adjusts the brightness of the blanking area according to the detected brightness level.

Furthermore, in the present invention, the blanking area (b) and the video portion (
aN, ) at a predetermined level for an arbitrary number of scanning lines,
For example, a signal set to an intermediate level (approximately 12 g when the quantization bit is 8 bits, approximately 256 level) is inserted.

(e) Effect In high-definition packaging images (especially bright images),
In images adjacent to the blanking area, bending and doming of the deflection system can be prevented.

Furthermore, in the present invention, since an intermediate level signal is inserted at the boundary between the video portion (aN,) and the blanking area (b),
Level fluctuations at the boundary become more gradual, and interference caused by flickering is reduced, making it less noticeable.

(f) Implementation example A first embodiment of the present invention will be described with reference to FIG.

The same parts as in FIG. 8 are given the same reference numerals.

In FIG. 1, (19) is a leakage integration circuit, which integrates and smooths the input MUSE signal to detect the average luminance level. Then, a background level signal of a level matching this luminance is output. In other words, \TSC11! The brightness of the blanking area j in the TI direction (b) is the same as that of the image part (a, 1)
The value corresponds to the brightness of

FIG. 2 shows a second embodiment of the invention.

[Signal switching circuit according to an embodiment of the present invention shown in FIG.
]), the signal level is set at the terminal (18b), the boundary part between the blanking area and the video area = 8 -, the signal level is set at the terminal (18c), and the horizontal and vertical retrace periods are the signal level set at the terminal (18b). ], the pedicle level set in step 8a) is selected and output.

FIG. 5(b) shows the output signal level at this time.

As shown in FIG. 5(b), in the scanning line of the blanking area (b) of the prompt in FIG. 5(a), a line (!1) close to the number image portion (dl) is Boundary ((1) As a river line, the rail of this line (pl) is the intermediate point u'+:.

FIG. 3 shows a third embodiment of the illumination. In this example, two lines are used as boundary lines. (18c
l) is the intermediate level C]28,"256) input terminal, (+8C+) is the second intermediate level (6=l,
-' 25G) input terminal. And Figure 5 (C)
Two lines (F, 1) (E2) for boundary (d), as in
People output at the timing of h.

FIG. 1 shows a fourth embodiment of the present invention. (20) is All
This is an i degree level detection circuit, and detects the average level of brightness or the brightness level of the -1-side and 1-side of the art dealer. (z2)
is an averaging circuit that outputs the average of this luminance level and the background level. In this example, the h11 degree level of the line (pl) located at the boundary (cl) is an intermediate value between the video and the background.

(g) Effect of the invention According to claim 1 of the present invention, the blanking area (one)
There is no possibility that the image will be distorted due to a large brightness level difference between the image portion (aN, ) and the screen image portion (aN,).

According to claim 2.3, -1 of the present invention, a boundary part ((1) is formed between the blanking area tk(b) and the image part (a1) of the screen, and this boundary part By setting the level of (d) to an absolute (126, % 256) or relative (background level, 2+image part'2) intermediate f1a, the flicker can be reduced by -1 - visually.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a first embodiment of the present invention. FIG. 2 is a diagram showing a second embodiment of the present invention. FIG. 3 is a diagram showing a third embodiment of the present invention. Fig. 1 is a diagram showing the fourth embodiment of the invention. Fig. 5 is a diagram for explaining the operation. Fig. 6, Fig. 7, and Fig. (l) Blanking area, (d) Boundary, <y1) <p, +> Boundary line, (a1)...
Video part. Applicant -5-Yoden (Ikuko Kaika agent, patent attorney Takuji Nishino and two others) (a) (b)

Claims (4)

[Claims] (1) When converting an input first television signal of a first system to a second television signal of a second system having a different aspect ratio, the blanking area (b) is A television signal conversion method for generating a television signal, comprising: performing integral processing on the first television signal, and controlling the brightness level of the blanking area (b) according to the level of the integral output. (2) When converting an input first television signal of a first system to a second television signal of a second system having a different aspect ratio, the difference in aspect ratios causes a block to appear at least in the upper or lower part. In the television signal conversion method for generating the ranking area (b), the brightness level of the line (l_1) of the boundary (d) between the video portion (a_N,) and the blanking area (b) is set to an intermediate value. A television signal conversion method characterized by: (3) When converting an input first television signal of a first system to a second television signal of a second system having a different aspect ratio, the difference in aspect ratios causes a block to appear at least in the upper or lower part. In the television signal conversion method for generating the ranking area (b), the brightness level of a line (l_1) at the boundary between the video portion (a_N) and the blanking area (b) is changed to
a_N) and the brightness level of the blanking area (b). (4) Claim 2 or 3, wherein the intermediate value has different values depending on odd and even fields.
television signal conversion method.