JPH0771266B2 - MUSE receiver - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television receiver, and more particularly to a MUSE receiver for receiving a MUSE signal and reproducing it.

[Conventional technology]

There is no conventional example corresponding to the present invention. However, as a conventional example to be referred to, for example, "MUSE-525 converter / Ninomiya et al., 1988 IEICE Spring National Convention", "MU
The standard method adapter for SE reception / Ninomiya et al., Technical Report of the Television Society of Japan, TEBS99-5 ”.

FIG. 3 is a schematic block diagram showing a signal processing circuit of a conventional MUSE-525 converter as an example.

The MUSE signal 1101 input to the input terminal 1 is the sampling frequency
Sampled by A / D converter 3 at 16.2MHz. The sampled MUSE signal 1102 is converted from a signal with 1125 scanning lines into a signal with 1050 scanning lines by the scanning line number and aspect ratio conversion circuit 4. Number of scanning lines and aspect ratio conversion circuit 4
The output 1103 of the luminance signal processing circuit 5 and the color signal processing circuit 6 are
Given to. The output 1104 of the luminance signal processing circuit 5 is a luminance signal according to the NTSC system and is given to the inverse matrix circuit 8a via the D / A converter 7a. The outputs 1105 and 1106 of the color signal processing circuit 6 are R according to the NTSC system, respectively.
-Y signal and BY signal, respectively D / A converter 7
It is given to the inverse matrix circuit 8a via b and 7c. The R, G, B signals 1110, 1111, 1112 are output from the inverse matrix circuit 8a and output from the signal terminals 2a, 2b, 2c, respectively.

Next, the operation will be described.

The MUSE signal proposed as a high-definition broadcasting system cannot be reproduced by the current receiver. Therefore, in order to reproduce the MUSE signal on the current receiver, the signal must be converted to NTSC signal. At that time, both conversion of the aspect ratio and conversion of the number of scanning lines are required. The MUSE signal has 1125 scanning lines with an aspect ratio of about 16: 9, while NT
The SC signal has 525 scanning lines with an aspect ratio of 4: 3. In this conventional example, the following conversion method is adopted.

1050 of the 1125 scanning lines are used.

The above-mentioned interlaced signal with 1050 scanning lines is converted into an interlaced signal with 525 scanning lines.

Display only the part with the aspect ratio of 4: 3 (the left and right parts are not displayed).

Figure 4 shows the outline of the conversion.

Hereinafter, description will be given with reference to FIG.

The MUSE signal sampled at the sampling frequency of 16.2 MHz is scanned by the scanning line number and aspect ratio conversion circuit 4 by the scanning line number 1125.
A book is converted into a signal 1103 with 1050 scanning lines. The scanning line and the aspect ratio conversion circuit are generally composed of a memory whose input and output operate asynchronously. Also,
The output read at this time is only the part corresponding to the aspect ratio 4: 3, and the left and right data are discarded.

The signal converted into the aspect ratio 4: 3 with 1050 scanning lines is given to both the luminance signal processing circuit 5 and the color signal processing circuit 6. Since the MUSE signal is a color difference signal (RY signal, BY signal) multiplexed as a line-sequential TCI (Time Compressed Insertion) signal, such a configuration is adopted (reference document "MUSE").
Method development / Ninomiya et al., NHK Technical Research Sho 62 ”).

The sampling pattern in the field of the luminance signal in the signal supplied to the luminance signal processing circuit 5 is as shown in FIG. The sampling pattern here is obviously equivalent to the MUSE signal. Incidentally, Y (i +
1, l) indicates the sample value in the seat (i + 1, l),
For the sake of explanation, it seems that the seat at the point one line below is different from (i + 1, l + 4) by unit 4.

The luminance signal processing circuit 5 performs the following processing.

Since the MUSE signal is sub-sampled, interpolation processing is performed within the field.

In order to convert the number of scanning lines from 1050 to 525, band limitation is performed at 525/2 [cph] in the vertical direction.

Converts 1050 scanning lines to 525 scanning lines.

The above three processes are actually performed in the following procedure.

Zero is inserted as a sample value at point x in FIG. 6 (a).

Apply a low pass filter in the vertical direction.

In this conventional example, a vertical filter having the following transfer function is used.

F (Z) = 1/4 {1 + 4Z- ^L + 3Z- ^2L } ... Filter A (Z- ^L : delay operator representing one line delay) or F (Z) = 1/4 {3 + 4Z- ^L + Z- ^2L } ... Filter B FIG. 6 (b) is a signal obtained as a result of applying the filter A every other line to FIG. 6 (a). For example, Y _V (i−1, l−1) in FIG. 6 (b) is obtained as follows.

_{Y V (i-1, l} -1) = 1/4 {Y (i-1, l + 4) +4 · Y
(I + 1, l) +3 · Y (i-1, l-4)} Incidentally, Y (x, y), Y V (x, y) is the sample value at the coordinates (x, y).

Here, due to the characteristics of the filter A, the signal shown in FIG. 6 (b) does not represent the original signal on the scanning line.

Apply a low pass filter horizontally.

In this conventional example, a horizontal filter having the following transfer function is used.

F (Z) = 1/2 {1 + Z ^-1 } ... Filter C (delay operator representing Z ^-1 : 1 sample delay) FIG. 6 (c) applies filter C to FIG. 6 (b). This is the signal obtained as a result. For example, Y _VH (i, l-1) in FIG. 6 (c) is obtained as follows.

Y _VH (i, l−1) = 1/2 {Y _V (i + 1, l, l−1) + Y _V (i−
1, l-1)} Note that Y _VH (x, y) is a sample value at coordinates (x, y). Here, due to the characteristics of the filter C, the sample points indicated by the coordinates in FIG. 6 (c) are horizontally displaced from the sample points indicated by the coordinates in FIG. 6 (b).

Filter A and filter B, which are vertical filters shown in the procedure, are used separately for each field. That is, the filter A is used in the odd field and the filter B is used in the even field. By this operation, an interlaced signal is obtained as shown in FIG.

The above three processes are executed by the above four procedures.

The sampling pattern in the field of the color difference signal (RY signal, BY signal) in the signal given to the color signal processing circuit 6 is as shown in FIG. 5 (b).
Here, the sampling pattern is obviously equivalent to the MUSE signal, and the color difference signals are multiplexed as line-sequential TCI signals. The color signal processing circuit 6 performs the following processing.

Since the MUSE signal is sub-sampled, interpolation processing is performed within the field.

Bandwidth is limited at 525/4 [cph] in the vertical direction.

An interlaced color difference line sequential signal with 1050 scanning lines is converted into an interlaced RY signal with 525 scanning lines and an interlaced BY signal with 525 scanning lines.

Perform time axis extension.

The above four processes are actually performed in the following procedure.

Zero is inserted as a sample value at point x in FIG.

Apply a low pass filter in the vertical direction.

In this example, a vertical filter having the following transfer function is used.

F (Z) = 1/4 {1 + 4 ・ Z ^-2L +3 ・ Z ^-4L } ... Filter D or F (Z) = 1/4 {3 + 4 ・ Z ^-2L + Z ^-4L } ... Filter E Color difference signal is a line Since they are sequentially multiplexed, such a configuration is adopted. FIG. 8 (b) is a signal obtained as a result of applying the filter D to each line, that is, the RY signal and the BY signal alternately with respect to FIG. 8 (a). For example, the RY signal C _V (j-1, l-6) and BY in FIG.
The signal _CV (j-1, l-2) is obtained as follows.

C _V (j-1, l-6) = 1/4 {C (j-1, l + 4) + 4 · C
(J−1, l-4) + 3 · C (j−1, l + 12)} C _V (j−1, l−2) = 1/4 {C (j−1, l + 8) + 4 · C
(J−1, l) + 3 · C (j−1, l + 8)} Here, due to the characteristics of the filter D, the signal shown in FIG. 8 (b) does not represent the original signal on the scanning line.

Apply a low pass filter horizontally.

In this conventional example, a horizontal filter having the following transfer function is used.

F (Z) = 1/2 {1 + Z ^-1 } ... Filter F FIG. 8 (c) is a signal obtained as a result of applying the filter F to FIG. 8 (b). For example, C _VH (j, l-6) and C _VH (j, l-2) in FIG. 8 (c) are calculated as follows.

_CVH (j, l-6) = 1/2 { _CV (j + 1, l-6) + _CV (j-1,
l−6)} C _VH (j, l−2) = 1/2 {C _V (j + 1, l−2) + C _V (j−1,
l-2)} Here, due to the characteristics of the filter F, the sample points indicated by the coordinates in FIG. 8 (c) are horizontally displaced from the sample points indicated by the coordinates in FIG. 8 (b).

Filter D and filter E, which are vertical filters shown in the procedure, are used separately for each field. That is, the filter D is used in the odd field and the filter E is used in the even field. By this operation, a signal as shown in FIG. 9 is obtained.

The color difference signal thus obtained is still in a line-sequential state. FIG. 10 is a diagram in which this is separated into an RY signal and a BY signal. However, as can be seen from the figure, the positions of the RY signal and the BY signal are vertically displaced. Therefore, the procedure shown in FIG. 11 is taken. First, zero is inserted as a sample value at point x in the figure. After that, a vertical filter having the following characteristics is applied.

F (Z) = 1/4 {1 + 2Z- ^L + 2Z- ^2L + 2Z- ^3L + Z- ^4L } ...
Filter G At this time, the output is adopted every other line so that the vertical positions of the RY signal and the BY signal are aligned. By doing so, a pseudo interlace R- of 525 scanning lines is formed.
The Y signal and the BY signal can be obtained.

A memory is used to extend the time axis in the horizontal direction.

The above four processes are executed by the above six procedures. The luminance signal 1104 which is the output of the luminance signal processing circuit 5 and the RY signal 1105 and the BY signal 1106 which are the outputs of the color signal processing circuits 6 obtained in this way are D / A converted, respectively, and the inverse. It is converted into an RGB signal by the matrix circuit and output.

It should be noted that although the vertical displacement between the luminance signal and the chrominance signal was not described, it can be easily solved by using a memory for one of the luminance signal processing circuit or the chrominance signal processing circuit and delaying it in units of lines. can do.

[Problems to be Solved by the Invention]

The conventional MUSE-525 converter is configured as described above, and as its name implies, it converts an image transmitted as a MUSE signal so that it can be reproduced by the current NTSC receiver. However, since the aspect ratio of the MUSE signal is different from that of the NTSC signal, the MUSE-525 converter has no choice but to convert the aspect ratio. Therefore, as shown in the conventional example, there is a problem that the left and right sides of the screen are truncated.

The present invention has been made to solve the above-mentioned problems of the conventional ones, and an object thereof is to obtain a receiver capable of reproducing all images having an aspect ratio of 16: 9 transmitted as a MUSE signal.

[Means for Solving the Problems]

A MUSE receiver according to the present invention is a MUSE receiver that converts a MUSE signal into an RGB signal and reproduces the signal, and the sampled above
Memory means for extracting 1050 scanning line interlaced signals from 1125 scanning lines of the MUSE signal, and luminance signal conversion for converting the luminance signal of the 1050 scanning lines interlaced signal to 525 scanning lines interlaced signal Means and the number of scanning lines 1050
The number of scanning lines for the color signal scanned line-sequentially in this interlace
Color signal conversion means for converting into a 5-line interlaced signal is provided, and the MUSE signal is reproduced as an interlaced signal with an aspect ratio of 16: 9 and 525 scanning lines.

[Action]

According to the present invention, with the configuration as described above, an image having an aspect ratio of 16: 9 transmitted as a MUSE signal can be reproduced by 525 lines interlaced scanning in a natural form, and a simple circuit configuration is provided. Can receive the MUSE signal.

〔Example〕

 An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows a MUSE receiver according to an embodiment of the present invention, in which reference numeral 1 is an input terminal for supplying a baseband analog MUSE signal. The input terminal 1 is connected to the input of the A / D converter 3. The output of the A / D converter 3 is added to the input of the scanning line number conversion circuit 9, and then the output of the scanning line number conversion circuit 9 is simultaneously supplied to the luminance signal processing circuit 10 and the color signal processing circuit 11. The output of the luminance signal processing circuit 10 is the D / A converter 7d.
And is supplied to the first input of the inverse matrix circuit 8b.
The color signal processing circuit 11 outputs two different color difference signals, which are the second and third inputs of the inverse matrix circuit 8b via the D / A converters 7e and 7f, respectively. The output of the inverse matrix circuit is given to the 16: 9 display 12 as R, G, B signals.

Next, the operation will be described.

The MUSE signal supplied to the input terminal 1 is converted into a digital signal by the A / D converter 3 at a sampling frequency of 16.2 MHz. The sampling pattern for the original image of the digital signal obtained at this time is as shown in FIG.
The scanning line structure of this signal is 1125 interlaces. The scanning line number conversion circuit 9 extracts 1050 scanning lines from these and outputs them as interlaced signals. That is, the output of the scanning line number conversion circuit 9 has an aspect ratio of about 16: 9,1.
It is 050 lines interlaced scan, and its image data is the second
The shaded area in the figure is sub-sampled according to the pattern shown in FIG. Like the scanning line number and aspect ratio converting circuit 4 in FIG. 3, the scanning line number converting circuit 9 can be easily constituted by a read / write asynchronous image memory. The luminance signal processing circuit 10 interpolates pixels and converts the number of scanning lines with respect to the 1050 interlaced signals, and outputs a luminance signal scanned by 525 interlaced signals.

The color signal processing circuit 11 outputs R from the above 1050 interlaced signals.
The -Y signal and the BY signal are separated, pixel interpolation, scanning line number conversion, and time axis expansion are performed, and a color difference signal interlaced with 525 lines is output. For the processing in the luminance signal processing circuit 10 and the color signal processing circuit 11, the signal to be handled is the aspect ratio
It may be the same as the luminance signal processing circuit 5 and the chrominance signal processing circuit 6 in FIG. 3 except that it is a 6: 9 signal. The difference in aspect ratio means that the number of pixels to be processed increases, and the luminance signal processing circuit 10 and the color signal processing circuit 11 need to increase the operating frequency by this increase. Luminance signals and color difference signals converted to 525 lines interlaced are D / A converters 7d to 7
It is converted to an analog signal by f and the inverse matrix circuit 8b
And become R, G, B signals 110 to 112. R, G, B signals 110 to 112
An image having an aspect ratio of 16: 9 is reproduced by being provided to the 16: 9 display unit 12.

As described above, according to this embodiment, the scanning line number conversion circuit converts the MUSE signal of 1125 lines interlaced scanning into the 1050 lines interlaced scanning signal, and the luminance signal processing circuit and the color signal processing circuit change the aspect ratio. 52 without conversion
Since it is converted to 5 interlaced signals and displayed on a 16: 9 display, images with an aspect ratio of 16: 9 transmitted as MUSE signals can be reproduced in a natural form, and the original MUSE Signal processing for still images and moving images required by the receiver can be realized by processing only moving images, and MUSE signals can be received with a simple circuit configuration. In addition, the widespread use of EDTV (Extended Definition TV) is expected to lead to mass production of wide-aspect display devices, so there is a possibility that the device can be configured at low cost.

〔The invention's effect〕

As described above, according to the present invention, it is a MUSE receiver that converts a MUSE signal into an RGB signal and reproduces it, and the number of scanning lines of the sampled MUSE signal is 1125 to 1050. Memory means for extracting signals and the number of scanning lines 10
Luminance signal conversion means for converting a 50-interlaced luminance signal into a 525-scan line interlaced signal;
1050 lines interlaced line-sequentially scanned color signals are provided with color signal conversion means for converting 525 scanning lines into an interlaced signal, and the MUSE signal has an aspect ratio of 16: 9 and scanning lines of 52.
Since it is reproduced as 5 interlaced signals, M
Images with an aspect ratio of 16: 9 transmitted as USE signals can be reproduced in a natural form. In addition, compared to the original MUSE receiver (which reproduces as 1125 scanning lines interlaced), the circuit configuration is simple, and there is an effect that an inexpensive MUSE receiver can be obtained.

[Brief description of drawings]

FIG. 1 is a schematic block diagram of a MUSE receiver according to an embodiment of the present invention, FIG. 2 is an explanatory diagram showing an image area that can be reproduced by the present invention, and FIG. 3 is a schematic block diagram of a conventional MUSE / NTSC signal converter. 4 and 5 are explanatory views showing image areas that can be reproduced by this MUSE / NTSC signal converter, FIG. 5, FIG. 6 and FIG.
Figures 7, 8, 9, 10 and 11 show the MUSE signal.
FIG. 7 is a sampling point diagram showing a signal processing method for converting a 525-line interlaced signal. In the figure, 1 is an input terminal, 2a to 2c are output terminals, and 3 is A /
D converter, 4 is a scanning line number and aspect ratio conversion circuit, 5, 1
0 is a luminance signal processing circuit, 6 and 11 are color signal processing circuits, 7a to 7f
Is a D / A converter, 8a and 8b are inverse matrix circuits, 9 is a scanning line number conversion circuit, and 12 is a 16: 9 display. The same reference numerals in the drawings indicate the same or corresponding parts.

Claims (1)

[Claims] 1. A MUS for converting a MUSE signal into an RGB signal and reproducing it.
E A memory means for extracting an interlace signal of 1050 scanning lines from the number of 1125 scanning lines of the sampled MUSE signal, and a 1050 scanning lines interlaced luminance signal scanning line number
A luminance signal converting means for converting into a 525 line interlaced signal; and a color signal converting means for converting a line-sequentially scanned color signal of the 1050 scanning lines interlaced signal into a 525 scanning line interlaced signal, A MUSE receiver, which reproduces the MUSE signal as an interlaced signal with an aspect ratio of 16: 9 and 525 scanning lines.